Report No: ACS7124


Middle East and North Africa
Integration of Electricity Networks in the
Arab World
Regional Market Structure and Design



December 2013




MNSEE
MIDDLE EAST AND NORTH AFRICA
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                                                 ii
                                         Table of Contents
Executive Summary (English)
  This Study’s Context and Objectives                                           1
  The Objective of Regional Integration, and Paths to Its Achievement           4
  Designing the Path to an Integrated Power Market                              5
  The Proposed Long-Term Strategy                                               6
  High-Level Executive Decisions                                               11
Executive Summary (Arabic)
                                                Volume 1:
1      Background, Purpose, and Organization of the Report                     12
  1.1    Background                                                            12
  1.2    The Context and Purpose of This Study                                 13
  1.3    Approach and Organization of the Study and this Report                14
2      Sector and Regional Overview                                            18
  2.1    Maghreb Region                                                        18
    2.1.1     Overview                                                         18
    2.1.2      Demand/Supply Balance                                           19
    2.1.3     Generation Mix                                                   20
    2.1.4     Maghreb Interconnection                                          21
    2.1.5     National Power Markets in the Maghreb                            25
  2.2    EIJLLPST Region                                                       30
    2.2.1     Overview                                                         30
    2.2.2     Demand/Supply Balance                                            30
    2.2.3      Generation Mix                                                  31
    2.2.4     EIJLLPST Interconnection                                         33
    2.2.5     EIJLLPST’s National Power Markets                                35
  2.3    GCC Region                                                            48
    2.3.1     Overview                                                         48
    2.3.2     Demand/Supply Balance                                            48
    2.3.3      Generation Mix                                                  49
    2.3.4     GCC Interconnection                                              51
    2.3.5     GCC’s National Power Markets                                     59
    2.3.6     Summary of Arab Market Status                                    67
  2.4    Neighboring Regions                                                   68
    2.4.1      Europe                                                          68
    2.4.2      Turkey                                                          70
    2.4.3      Iran                                                            71
    2.4.4     Nile Bas in Initiative (NBI)                                     72
    2.4.5     West African Power Pool (WAPP)                                   74
    2.4.6     Trade with Countries to the East                                 75
  2.5    Summary                                                               76
3      The Context for Regional Electricity Trade                              81
  3.1    Benefits and Challenges of Integrating Regional Electricity Markets   81
  3.2    Experience with Market Integration                                    82
    3.2.1 SIEPAC                                                               84
    3.2.2 SEE                                                                  86
    3.2.3     PJM                                                              89
  3.3    Evolution of the EU Electricity Market                                91
  3.4    Renewable Energy Development in the Arab Countries                    94
    3.4.1     Potential                                                        94
    3.4.2     Renewable Energy Projects and Initiatives in Arab Countries      96
    3.4.3     Gulf Countries Enabling Research                                 97
    3.4.4    Regional Integration to Enable Greater Levels of RES Penetration                         98
  3.5    Synchronization                                                                              99
  3.6    Assessment of Arab Regional Electricity Markets                                             102
  3.7    Requirements for Regional Integration and Trade                                             105
4      The “Ultimate” Regional Market Design                                                         110
  4.1    Purpose and Approach to Development of the “Ultimate” Regional Market Design                110
  4.2    Proposed Ultimate Regional Market Design for Arab Countries                                 110
    4.2.1    High-Level Description                                                                  110
    4.2.2    Salient Features of Proposed Ultimate Regional Market Design                            112
    4.2.3    Roles and Responsibilities of Market Participants                                       113
    4.2.4 Regional Institutions                                                                      117
    4.2.5 Governance Documentation                                                                   118
  4.3 Summary                                                                                        118
5      Proposed Transitional Regional Electricity Market Design                                      120
  5.1    Objective and Guiding Principles                                                            120
  5.2    Approach to Regional Electricity Market Integration                                         122
  5.3    Proposed Path to Regional Electricity Market Integration                                    123
  5.4    Transitional Regional Electricity Market Design: Stage 1                                    128
    5.4.1 Market Design                                                                              128
    5.4.2    Salient Features of Proposed Transitional Regional Electricity Market Design: Stage 1   129
    5.4.3    Regional Market Participants and Their Roles in Stage 1                                 130
    5.4.3    Regional Market Institutions                                                            134
    5.4.4    Transitional-Regional-Market Governance Documentation                                   138
6      Next Steps      142

                                    Volume 2: Attachments
Attachment 2.A—Retail Tariff Analysis
Attachment 2.B—Private Sector Investment in Arab Countries
Attachment 2.C—Electricity Sector in Europe
Attachment 2.D—Electricity Sector in Turkey
Attachment 2.E—Electricity Sector in Iran
Attachment 2.F—Nile Basin Initiative
Attachment 3.A—Summary of EU Legislation on Internal Market and Cross-Border Electricity Trade
Attachment 3.B— Prospects of Synchronizing the Power Grids of EIJLLPST Countries with ENTSO-E




                                                   iv
                      Abbreviations and Acronyms

ACER       Agency for the Cooperation of Energy Regulators (Europe)
AER        Authority for Electricity Regulation
AERF       Arab Electricity Regulators’ Forum
AMU        Arab Maghreb Union
ARC        Advisory and Regulatory Committee
ASEAN      Association of Southeast Asian Nations
AUE        Arab Union of Electricity
Bbl        Barrel
BOO        build-own-operate
BOOT       build-own-operate-transfer
CAGR       compound annual growth rate
CASAREM    Central Asia Regional Electricity Market
CEGCO      Central Electricity Generating Company
CMEP       Compliance Monitoring and Enforcement Processes
COMELEC    Comité Maghrebin de l’Electricité (Maghreb Electricity Committee)
CRIE       Comisión Regional de Interconexión Eléctrica
CSP        concentrated solar power
CT         combustion turbine
DSO        distribution system operator
EAC        East African Community
EAPP       Eastern Africa Power Pool
ECRA       Electricity and Cogeneration Regulatory Authority
ECRB       Energy Community Regulatory Board
EDCO       Electricity Distribution Company
EDL        Electricité du Liban
EEHC       Egyptian Electricity Holding Company
EIA        Energy Information Administration (United States)
EIJLLPST   Eight-country Interconnection (Egypt, Iraq, Jordan, Libya, Lebanon,
           Palestine, Syria, and Turkey)
EIJST      Five-country Interconnection (Egypt, Iraq, Jordan, Syria, and Turkey)
EITC       Electrical Interconnection of Three Continents
ENG        Emirates National Grid
ENTRO      Eastern Nile Technical Regional Office
ENTSO-E    European Network for Transmission System Operators - Electricity
EOR        Ente Operador Regional
ERC        Electricity Regulatory Commission
ESMAP      Energy Sector Management Assistance Program
ETSO       European Transmission System Operators
EU         European Union
FERC       Federal Energy Regulatory Commission
FTRs       Financial transmission rights
GCC        Gulf Cooperation Council
GCCIA      Gulf Cooperation Council Interconnection Authority
GDP        gross domestic product
GECOL      General Electricity Company of Libya
GEDCO      Gaza Electricity Distribution Company
GRC        Gulf Research Center
                                     v
GT          gas turbine
GW          Gigawatt
GWh         gigawatt-hours
HEPCO       Hebron Electric Power Company
HFO         heavy fuel oil
HVAC        high voltage alternating current
HVDC        high voltage direct current
Hz          Hertz
IAEA        International Atomic Energy Agency
ICCS-NTUA   Institute of Communications and Computer Systems of the National
            Technical University of Athens
IEC         Israel Electric Corporation
IPP         independent power producer
IRENA       International Renewable Energy Agency
ISO         independent system operator
IWPP        independent water and power producer
JDECO       Jerusalem District Electric Company
KACST       King Abdulaziz City for Science and Technology
KAHRAMAA    Qatar General Electricity and Water Corporation
KAUST       King Abdullah University of Science and Technology
kV          Kilovolt
kWh         kilowatt-hour
LAS         League of Arab States
LMPs        locational marginal prices
MENA        Middle East and North Africa
MER         Mercado Eléctrico Regional
MEW         Lebanon’s Ministry of Energy and Water
MOU         memorandum of understanding
MW          Megawatt
MWh         megawatt-hour
NBI         Nile Basin Initiative
NEDCO       Northern Electric Distribution Company
NEPCO       Jordan’s National Electric Power Company
OECD        Organisation for Economic Co-operation and Development
ONE         Office National d’Electricité
PEA         Palestinian Energy and Natural Resources Authority
PEC         Public Electricity Corporation
PEDEEE      Public Establishment for Distribution and Exploitation of Electric Energy
PEEGT       Public Establishment for Electricity Generation and Transmission
PETA        Power Exchange and Trading Agreement (GCC)
PHLG        Permanent High-Level Group
PJM         Pennsylvania-Jersey-Maryland Interconnection
PPA         power-purchase agreements
PV          Photovoltaics
PX          power exchange
REM         regional electricity market
RES         renewable energy sources
RTOs        regional transmission organizations
SEC         Saudi Electric Company
                                      vi
SEE        Southeast Europe
SELCO      Southern Electric Power Company
SET-Plan   European Strategic Energy Technology Plan
SIEPAC     Central American Electric Interconnection System
STEG       Société Tunisienne de l’Electricité et du Gaz
SWCC       Saline Water Conversion Corporation
TEK        Turkish Electricity Corporation
TSO        transmission system operator
TW         Terawatt
TWh        terawatt-hours
TX         Transmission
UAE        United Arab Emirates
UCTE       Union for the Coordination of Transmission of Electricity
UNMIK      United Nations Interim Administration Mission in Kosovo
WAPP       West African Power Pool
WEC        Water and Electricity Company




                                    vii
                                       Acknowledgement

This report was prepared jointly in 2010-2011 by the League of Arab States (LAS) and the
World Bank. The report is part III of a three-part study on the feasibility of interconnecting the
electrical systems of the Arab countries including:
      Part I: Study of Interconnections of Electrical Systems in the Arab World.
      Part II: Study of Electricity-Gas Trade among the Arab Countries.
      Part III: Study of Institutional and Regulatory Frameworks.
Parts I and II are prepared jointly by LAS and the Arab Fund for Social and Economic
Development.
The World Bank team who worked on this report was led by Husam Beides (Lead Energy
Specialist) and comprised Hossein Razavi (Consultant), Doug Bowman (Cosultant), Mohab
Hallouda (Senior Energy Specielist), Waleed Alsuraih (Senior Energy Specilist), Roger Coma
Cunill (Energy Specialist), Hayat Al Harazi (Operations Officer) and Mark Njore (Program
Assistant). The LAS team comprised the Study Steering and Technical Committees consisting of
the representatives of the Arab (national and sub-regional) power utilities as well Department of
Energy at LAS.
The report was prepared under the context of the World Bank Arab World Initiative and was
supported in part by ESMAP. The Financial and technical support by the Energy Sector
Management Assistance Program (ESMAP) is gratefully acknowledged.




                                               viii
                                                Disclaimer

Energy Sector Management Assistance Program (ESMAP) reports are published to communicate the
results of ESMAP’s work to the development community with the least possible delay. Some sources
cited in this paper may be informal documents that are not readily available.

The finding, interpretations, and conclusion expressed in this report are entirely those of the author(s) and
should not be attributed in any manner to the World Bank, or its affiliated organizations, or to members of
its board of executive directors for the countries they represent, or to ESMAP. The World Bank and
ESMAP do not guarantee the accuracy of the data included in this publication and accepts no
responsibility whatsoever for any consequence of their use. The boundaries, colors, denominations, other
information sown on any map in this volume do not imply on the part of the World Bank Group any
judgment on the legal status of any territory or the endorsement of acceptance of such boundaries.




                                                     ix
Executive Summary (English)
This Study’s Context and Objective s
The Arab countries have experienced rapid economic growth in recent years, and the high
economic growth has triggered a significant increase in energy demand, particularly for
electricity. Although part of this growing demand may be curbed through more effective energy
conservation policies, including tariff adjustments, there is a clear need to expand generating
capacity and fuel supply in all Arab countries. In recent years, gas availability has turned into a
serious issue as countries such as Syria, Jordan, Saudi Arabia, Kuwait, the United Arab Emirates
(UAE), and others have realized that their domestic gas production is insufficient to meet the
needs of their power sectors. This has triggered a search for sources of imported gas or
electricity, which in turn has led to attempts to construct cross-border infrastructure facilities.
Besides enabling energy imports, interconnected power networks impart a series of additional
benefits such as improved system reliability, reduced reserve margins, reactive power support,
and energy exchanges that take advantage of daily and seasonal demand diversity and disparities
in marginal production costs. Recognizing the benefits of regional integration, several bilateral
and subregional initiatives are under way to interconnect the electricity networks of Arab
countries in an effort to establish integrated electricity systems for electricity exchange and trade.
The primary regional interconnection schemes among Arab countries include:
        The Maghreb regional interconnection, which includes Morocco, Algeria, and Tunisia,
         and which was initiated in the 1950s and evolved into multiple high-voltage transmission
         interconnections between the three countries. Morocco was connected to Spain in the late
         1990s, and Morocco, Algeria, and Tunisia are now all synchronized with the pan-
         European high-voltage transmission network.
        The eight-country (Egypt, Iraq, Jordan, Libya, Lebanon, Palestine, Syria, and Turkey
         [EIJLLPST]) regional interconnection, which was initiated in 1988 by Egypt, Iraq,
         Jordan, Syria, and Turkey as part of an effort to upgrade their electricity systems to a
         regional standard.1 Lebanon, Libya, and the Palestinian Authority later extended the
         agreement to eight countries. 2 Turkey is expected to fully synchronize to the European
         grid early in 2012, which will further efforts to synchronize the EIJLLPST electricity
         network with the grids in Turkey and Europe.
        The regional power interconnection of the Gulf Cooperation Council (GCC) allows
         electricity exchange among its six member states —Kuwait, Saudi Arabia, Bahrain, Qatar,
         the UAE, and Oman—under an agreement signed in 2009. The interconnection is
         targeted at sharing capacity reserve and improving supply reliability, which will reduce
         the need for investment in new generation capacity.




1
  Although the EIJLLPST Interconnection Agreement was signed in the 1980s, physical interconnections between Syria and
Jordan and between Syria and Lebanon were constructed in the 1970s.
2
  According to the Minutes of the Eighteenth Annual Meeting of Medelec, the EIJLLPST interconnection will be renamed the
Electrical Interconnection of T hree Continents (EIT C) at the next ministerial meeting.



                                                           1
                           Figure ES1. Existing and planned interconnections


                       EU Electricity
                                                                                Turkey
                         Markets
                                              Italy            EIJLLPST
                                                            Interconnection

                                 Under
                              Consideration                              Lebanon          Syria
                                                                                                              Iran
        Spain
                                                                   Palestine
                                                                                 Jordan          Iraq
                                                                Libya Egypt

    Morocco                Algeria            Tunisia

         Maghreb                                                                     Kuwait             Bahrain
     Interconnection

    Mauritania                                             Under
                                                                                                         Qatar
                                                        Consideration                  KSA
             400 kV
                                                                        Sudan
             220 kV                             Ethiopia
             150 kV                                                 Yemen                                 UAE
             90 kV
             66 kV                                                  Djibouti
            Existing                                                                                     Oman
                                                                   Somalia
           Not operational/Island operation                                                  GCC
           Under-consideration,-study,-construction                Comoros             Interconnection


Note: Medium voltage interconnections between Jordan and West Bank and between Egypt and Gaza exist and operate on island
mode
Source: LAS/The World Bank

Though the Maghreb and EIJLLPST interconnections have existed for some time, electricity
trade among the Arab countries has remained at modest levels due to obstacles such as limited
generation reserve margins, the absence of a harmonized regulatory framework with clear rules
governing electricity trade, and institutional weaknesses at both the national and regional level
(that is, governing bodies lack the tools, data, and incentives necessary to promote trade). But the
desire to improve supply security through the diversification of energy supply resources,
particularly in the context of the interregional programs for the development of renewable wind
and solar resources, has improved motivation to deal with these weaknesses.
The League of Arab States (LAS) is carrying out a three-part study on the feasibility of
interconnecting the electrical systems of the Arab countries:
Part I: Study of Interconnections of Electrical Systems in the Arab World.
Part II: Study of Electricity-Gas Trade among the Arab Countries.
Part III: Study of Institutional and Regulatory Frameworks.



                                                            2
The main objective and scope of the three-part study is to establish a strategy and a master plan
for the development of electricity trade among Arab countries. The three parts of the study are
considered complimentary. Part III of the study— which is the subject of this report—is a joint
effort between the LAS and the World Bank. The World Bank has been particularly active in this
area of the world. Under the Arab World Initiative, the World Bank has completed three studies
assessing the potential of energy integration in the three Arab subregions, including the
Maghreb, EIJLLPST, and the GCC, while implementing a major regional program for scaling up
concentrated solar power (CSP) in the Middle East and North Africa (MENA) region.
This study focuses on the institutional and regulatory aspects of cross-border trade and electricity
market integration among the 22 Arab countries, and between the Arab countries and potential
neighboring markets. Consistent with the LAS terms of reference, the study covers six primary
areas:
      Analyzing the legal and regulatory framework for the power sectors of the target
       countries, with particular attention to cross-border electricity trade, including the
       development of required governance documents such as grid code, power exchange, and
       supply code (market rules).
      Identifying potential obstacles to the creation of a regional electricity market (REM) as
       well as enabling factors, and developing operational recommendations to surmount these
       obstacles.
      Identifying barriers to efficient energy trading among the concerned countries and
       developing possible ways to facilitate trade and regional integration.
      Defining the legal support required for a gradual progression toward a competitive and
       efficient REM.
      Developing and assessing the general terms under which electricity is to be traded, taking
       into consideration international constraints such as European Union (EU) market trading
       rules, limitations on imports, limitations on long-term price agreements, and
       environmental rules.
      Proposing an action plan for the negotiation of the necessary treaties or international
       agreements to promote electricity trade among Arab countries and target markets.
The study comprises two phases: Phase 1 provides an overview of current regional and national
electricity markets in the Arab World, including market structure, institutions, and regulations
and defines the principles of electricity market integration in the Arab World. Phase 1 results are
summarized in this study main report (Volume I). Phase 2 develops a draft road map for a
transition path toward market integration and associated governance documentation including
drafts Memorandum of Understanding (MoU), General Agreement, General Pan -Arab
Electricity Agreement, and the Regional Grid Code, all included in Volume II of the report.
To facilitate the consultation process the LAS formed Steering and Technical Committees
consisting of the representatives of the Arab (national and sub-regional) power utilities. The
World Bank team and the LAS teams held regular meetings to review the results and
recommendations of the study.




                                                 3
The Objective of Regional Integration, and Paths to Its Achievement
The ultimate goal of an integrated power market is to optimize the supply of electricity within a
broad, regional (rather than confined, national) framework. Often this is thought to be achievable
in a market environment where every party has equal access to all networks (domestic, regional,
and international); where market data and information (pricing, market operation, capacity
allocation, and so on) are transparent; and where electricity tariffs cover the cost of supply,
power-grid codes are harmonized, systems are synchronized, and markets liberalized.
The objective of market integration has three distinct dimensions: security of supply,
sustainability, and competition. While all three dimensions appear on the regional integration
agenda of various parts of the world, the emphasis on each dimension has varied depending on
the priorities of each region. For example, in the EU integration agenda, the emphasis has been
on competition. This emphasis indicates that market integration can be achieved through a
coordinated reform process, which in turn implies that the liberalization of individual national
markets is a prerequisite to regional integration. On the other hand, in East Asia, Latin America,
and parts of the Arab world, the emphasis has been on improving the security of supply by
building the required physical infrastructure and relying on simple rules for operation of the
interconnected systems. This approach recognizes the fact that the individual national markets
are at different stages of development and that the liberalization of these markets cannot be
expected to proceed at the same pace.
Review of global experience is most revealing in the sense there is no evidence to suggest that
any of the existing or developing regional integration schemes got the model right at the initial
stage of integration. It is nevertheless clear that learning from other people’s mistakes enables
policy makers to avoid wasting time and resources. In the past two decades regional integration
has gained a higher profile as the benefits to integrated countries receive wider recognition. But
every integration scheme has taken a long time and significant effort to materialize. The more
successful schemes are the ones that pursued an adaptive approach and adjusted their course
when needed, and that remained persistent in dealing with challenges both foreseen and
unforeseen. The success of such schemes indicates the need to prepare a clear implementation
plan, establish dependable political support early on, and establish a monitoring mechanism that
can quickly bring obstacles and challenges, as they emerge, to the attention of decision makers.
The Arab world’s electricity integration initiatives have appropriately emphasized security of
supply. But the aim of future regional electricity integration in the Arab world will incorporate
sustainability and competition dimensions as well. The sustainability dimension will be a priority
since most Arab countries are eager to ensure the long-term preservation of their energy
resources and to mitigate local and global environmental damage. The competition dimension
will also be important: most Arab countries are introducing private sector projects into the power
sector but would like to ensure that these projects are able to compete at a regional level. It is
therefore proposed that the approach to regional integration in the Arab world should:
      Recognize the inherent difficulty of moving a large number of member countries toward
       political consensus.
      Recognize the diversity of national electricity systems (markets), the varying pace of
       reform processes, and the differences between the three existing subregional
       interconnections.


                                                4
        Attempt to coordinate sector reform decisions.
        Strengthen the interconnection/integration within each subregion.
        Develop the institutional framework needed for a coordinated move toward a harmonized
         network.
Designing the Path to an Integrated Power Market
Elaboration of regional integration schemes often starts with an attempt to design a model for an
integrated market. But it quickly becomes evident that while the desirable model has a set of
clear features,3 its achievement is a long-term goal. The immediate challenge is to then draw a
picture of the path that takes the region from its current status to the desirable solution in a
calculated, systematic, and practical manner.
The path to market integration should take account of current realities. At the top of these
realities is the fact that one country is not likely to trade with another if by doing so it is placing
its own customers at risk of reduced reliability. This is always a hampering factor at the initial
stage of regional integration, when each participating country needs reassurance that the power
systems of the other countries are reliable. This is also an important reason for making a
distinction among the countries of the GCC, Maghreb, and EIJLLPST subregions. Currently, the
three subregional markets are at different stages of development and must operate independently
because they are either not interconnected or not synchronized. But this is likely to change in the
future. Ultimately, it is anticipated that the three Arab subregional markets will merge into one,
and might subsequently be interconnected with the EU and potentially with markets in Asia and
Africa.
The EU experience is often looked to for lessons on integrating electricity markets. This report
reviews the EU experience, with the idea that it is relevant to designing the regulatory and legal
systems of the Arab electricity network. It may appear, at first glance, that the EU has achieved a
high degree of electricity market integration at a rapid pace; however, in reality, the EU has been
struggling with all the practical issues that are also being faced in other regions. Several EU
subregions have moved more slowly than others in facilitating electricity trade and integration,
and the EU continues to correct the course of market integration by revising various directives
and guidelines. At the same time, it is perhaps the most valuable experience to study because of
the persistent public policy and substantial professional and technical skills that have gone into
keeping market integration on the right track. The review of the EU experience provides
significant material in analyzing two distinct aspects of regional electricity integration: (i) the
overarching agenda for integration, and (ii) a strategy to deal with the varying status of the EU
subregions. Both of these aspects will be helpful in designing the transitional path of market
integration in the Arab world.
Considering the international experience and the current status of the electricity sectors in Arab
countries, this report sets out a path toward market integration with the following four stages:

3
  T hese features are described in the body of the report. T he basic requirements for a successful regional electricity market
(REM) include: availability of the necessary physical infrastructure (that is, high -voltage transmission lines); harmonized
technical rules for the operation of the interconnected systems as well as harmonized wholesale market rules; fair and
nondiscriminatory access to the physical infrastructure, including transparent pricing mechanisms for use of such infrastructure;
and suitable mechanisms for regional regulation and market supervision, enforcement procedures, and dispute -settlement
schemes.



                                                               5
      Stage 1 : Implementing a transitional regional market design, focusing on identifying and
       expanding trade opportunities.
      Stage 2 : Expanding the transitional regional market’s functionality, focusing on
       unbundling transmission system operators (TSOs), and introducing wholesale
       competition.
      Stage 3 : Moving toward an ultimate regional market design, focusing on full wholesale
       competition supported by multiple financial markets.
      Stage 4 : Achieving a fully integrated Arab regional market, focusing on a fully
       interconnected and synchronized Arab electricity network.
The above four-stage development plan is politically feasible, in line with best practices, and
promises the long-term achievement of the integration objectives. Its stages ensure a gradual but
consistent and coherent approach to the development of electricity trade and market integration.
The Proposed Long-Term Strategy
To translate the above four-stage vision into practice, one would need to devise a clear and
consistent long-term strategy that identifies specific policy actions to be undertaken in each stage
of market development. Table ES1 summarizes the content of the proposed strategy, which is
focused on the policy decisions pertaining to institution building and the legal and regulatory
framework. The strategy recognizes that the three subregions are at different stages of market
development; however, institution building for the entire Pan-Arab network would assist transfer
of knowledge, skills, and information among the three subregions and also from neighboring
countries. It is also noted that the institution building during each stage is devised to meet the
requirements of that stage and to prepare for moving to the next stage.




                                                 6
                          Table ES1. Summary of proposed long-term strategy

      Stage of      Expansion of infrastructure and electricity          Institution building, legal framework , and policy
    development                       trade                                                  decisions


Stage 1:            Subregional T SOs/market facilitators identify       Establish a secretariat.
                    trade opportunities based on international fuel
Transitional        prices.                                              Establish a regional advisory and regulatory committee.
market focused
on identifying      Additional trade volume expected among GCC,          Establish regional Arab T SOs committee.
and expanding       EIJLLPST , and Maghreb countries.
trade                                                                    Establish a subregional T SO/market facilitator for each
opportunities       T rade takes place according to direct utility-to-   subregion.4
                    utility bilateral contracts between contiguous
                    and noncontiguous countries.                         Develop and sign:
                                                                            A memorandum of understanding and general
                    Some countries provide transit/wheeling service.         agreement on Pan-Arab regional electricity market
                                                                             integration.
                    Reinforce infrastructure by:                            A general regional electricity market agreement.
                      Expanding generation to meet national                A regional grid code.
                        requirements and exports.
                      Utilizing generation to meet seasonal and         Harmonize technical and reliability standards.
                        daily demand differences beyond domestic
                        markets.                                         Expand the Pan-Arab electricity database to include
                      Reinforcing existing cross-border                 comprehensive and up-to-date information on each
                        interconnections for bulk electricity trade      country’s expansion plan, investment program, and
                        (for example, Iraq– Syria, Jordan – Egypt,       regulatory changes.
                        Egypt – Libya, Libya– T unisia, Algeria–
                        Morocco).                                        Prepare transmission tariffs and cross-border
                      Upgrading national transmission networks.         transmission capacity auction process.

                    Additional international interconnections:
                      Egypt – Saudi Arabia
                      Egypt – Sudan
                      Mauritania– Morocco
                      Saudi Arabia– Yemen




4
  T he Gulf Cooperation Council Interconnection Authority (GCCIA) has many of the responsibilities proposed for the
subregional transmission system operator (T SO)/market facilitator, but not all (for example, the GCCIA does not publish marke t
prices); therefore, some modifications in its responsibilities would be necessary for it to take on this role.



                                                                 7
   Stage of       Expansion of infrastructure and electricity         Institution building, legal framework , and policy
 development                        trade                                                 decisions


Stage 2:          Introduce competition to large consumers            Agree to open up high-voltage supply to competition and
                  directly connected to the transmission network.     allow tariffs for large customers to be set by competitive
Expanded                                                              market.
transitional      Further improve sustainability and security of
regional market   supply objectives.                                  Separate T SOs through unbundling of the national
focusing on                                                           markets and establish national independent and informed
unbundling        Facilitate trade through further strengthening of   regulatory entities.
TSO s and         transmission networks and synchronization.
introducing       Systems are synchronized at the level of each       Establish a regional regulator (will start with a reporting,
wholesale         subregion (GCC and Maghreb already                  coordinating, and dispute-resolution role before moving
competition       synchronized; synchronize all EIJLLPST              to a full-fledged regional regulator).
                  countries).
                                                                      Replace regional Arab T SOs committee with regional
                  Coordinate investments in transmission              Pan-Arab T SO entity with board of directors and full
                  infrastructure.                                     complement of regular staff.

                                                                      Revise roles of secretariat and regional advisory and
                                                                      regulatory committee to reflect roles of new regional
                                                                      T SO and regulatory entities.

                                                                      Amend role of subregional T SOs/market facilitators to
                                                                      take on more responsibilities relating to the market
                                                                      operator function.

                                                                      Revise regional grid code as necessary and make
                                                                      extensive revisions to general regional electricity market
                                                                      agreement to accommodate competitive trade at
                                                                      wholesale level.




                                                              8
   Stage of         Expansion of infrastructure and electricity           Institution building, legal framework , and policy
 development                          trade                                                   decisions


Stage 3:            Full wholesale competition with all large             Agree to open up market to full wholesale competition.
                    customers and distribution/supply entities
Ultimate            allowed choice of supplier.                           Put into operation additional financial markets (for
regional market                                                           example, day-ahead market) as required by regional
focusing on full    Introduce new financial markets as needed by          market participants.
wholesale           regional market participants such as bid-based
competition         balancing market, day-ahead market, intraday          Replace subregional T SOs/market facilitators with
supported by        market, emissions trading market, and so on.          regional market operator with responsibility for all
multiple                                                                  functional regional financial markets that are not
financial           Promote an economic-dispatch outcome                  implemented and operated by private sector entities.
markets             consistent with objectives of competition,
                    sustainability, and reliability/security of supply.   Disband secretariat and give full regional market
                                                                          oversight responsibility to regional market operator,
                    Consistent with needs of regional market,             regional T SO, and regional regulator, with oversight by
                    further improve transmission capacity and             Arab Ministerial Council for Electricity.
                    synchronization at national and international
                    levels.                                               Modify regional market governance documents as
                                                                          necessary to incorporate full wholesale competition and
                                                                          newly formed financial markets.

                                                                          Ensure regional market institutions have full
                                                                          responsibility to establish transmission tariffs and
                                                                          enforce uniform technical and financial rules across
                                                                          regional market .


Stage 4:            T he three subregions are interconnected and          Prepare and implement a unified Pan-Arab power
                    synchronized (or asynchronized), including            development plan (could include three binding
Fully integrated    countries not currently interconnected with any       subregional development plans that align with national
Arab regional       of the subregions.                                    plans and cover both conventional and renewable
market focusing                                                           generation and transmission).
on fully            T he region is also synchronized with the
interconnected      ENT SO-E and other markets in the surrounding         Develop a plan for synchronization (or asynchronization)
and                 area.                                                 of the three subregions, and synchronization (or
synchronized                                                              asynchronization) with the ENT SO-E and other REMs in
Arab electricity    T here is open access to all transmission and full    the surrounding region.
network             wholesale competition with fully functional
                    regional market institutions and governance
                    documentation.


Note: T SO = transmission system operator; GCC = Gulf Cooperation Council; EIJLLPST = Eight -country Interconnection
(Egypt, Iraq, Jordan, Libya, Lebanon, Palestine, Syria, and T urkey); ENT SO-E = European Net work for T ransmission System
Operators - Electricity; REM = regional electricity market.

Although the four-stage strategy should provide the framework for institution building and
policy decisions, the main emphasis is on articulating the details of what needs to be achieved
during Stage 1. Accordingly, we have developed a specific regional market design for Stage 1
and an implementation plan containing the institutional and policy decisions to be taken during
this stage. The main components of the proposed plan include preparation of the required
governance documents and the regional institutions.
The proposed plan focuses the governance documentation and the regional institution building
on the objective of electricity market integration. As a result, the plan suggests only a limited



                                                                  9
number of regional documents, and also only a very few regional entities. More specifically the
plan envisages the governance documentation to include only four main items:
         A high-level memorandum of understanding (MOU).
         A general agreement.
         A general Pan-Arab electricity market agreement.
         A regional grid code.5
Similarly the plan calls for formation of a secretariat, while addressing other regional
requirements through certain coordinating forums and activities. The coordinating forums
include:
         A regional advisory and regulatory committee that will include one member from the
          regulatory body of each of the countries participating in the regional market.
         A regional Arab TSOs committee.
In the longer term, each of these functions would be performed by a formal entity. However, in
the near term it is desirable that these regional institutions be created in a manner that avoids
additional financial commitments from the member countries. To this end, the proposed
functions would be organized by drawing upon the existing entities, as follows:
         The regional advisory and regulatory function and the regional TSO function would be
          handled through the establishment of two corresponding committees and inviting
          appropriate membership relevant to the function of each committee. In addition, relevant
          stakeholders such as the Arab Union for Electricity and the Arab Electricity Regulators
          Forum would be invited to participate in their relevant committees.
         The secretariat function would be taken up by the (Energy Department) LAS Secretariat.
The plan further proposes that subregional TSOs/market facilitators be established within each of
the GCC, Maghreb, and EIJLLPST regions. The main role of the subregional TSO/market
facilitator is to identify trade opportunities by working closely with the participating countries.
The Gulf Cooperation Council Interconnection Authority (GCCIA) is already in the process of
promoting such a function within the authority. Over time one could review the advantages of
creating a single TSO/market facilitator at the regional level.
Finally, it is worth mentioning that the development of renewable energy sources (RESs) has
taken a prominent position in the regional integration deliberations of the EU, and is becoming a
significant consideration in the network interconnection discussion of the Arab countries. The
impact of RESs on regional integration is fourfold. First, most RES sites (wind farms and solar
fields) are far from the power grids and would require dedicated transmission lines to evacuate
power to the grid; this affects the overall transmission capacity and the possibility of electricity
5
  A memorandum of understanding (MOU) would be a high -level government document signed by the Arab Ministerial Council
for Electricity with the purpose of establishing their commitment to pursue market reform consistent with the objectives of
regional market integration. T he general agreement would be a high -level government document that identifies the objectives and
principles of regional market integration and specifies the roles and responsibilities of the regional market entities. T he general
Pan-Arab electricity market agreement would be a lower-level document that provides more details of how the countries will
meet the commitment identified in the MOU, and specifies the rules relating to trade. T he regional grid code would set the
minimum technical standards for the region as a whole.



                                                                10
trade. Second, RES power supply is expected to grow substantially and provide a source of
electricity export. Third, regional integration of power networks results in larger and more
diversified power generation capacity than in isolated national markets, and thereby provides a
better opportunity for the development of RESs and possibly stronger commercial incentives for
the development of a local industry in the manufacturing of RES equipment. Fourth, there is
substantial international financial support for RES development, which could be tapped by
public and private entities to expand RES-generating capacity while strengthening cross-border
interconnections that offer synergy between RESs and regional integration.
RES development is of particular relevance to the development of the grid codes.
Interconnection of RES generation, particularly wind, to the power grid raises specific concerns
about system stability. To keep grid operations stable, there is a need to ensure that other power
generation sources are available to compensate for hourly variations of RES power generation.
The associated technical issues include backup systems and power quality. The grid code could
also require certain technical specifications from the manufacturers and developers of RES plants
to minimize the impacts on the grid stability.
High-Level Executive Decisions
The above implementation plan would require a set of high-level executive (ministerial)
decisions to move the process forward. There are two immediate decisions to be tabled as soon
as possible. First, an executive decision is needed to set up a secretariat that would move the
process forward. As noted, in the near-term this function would be carried out by the LAS
secretariat whose main responsibilities would include:
      Providing administrative support to the Arab Ministerial Council for Electricity, its
       Executive Bureau, the regional advisory and regulatory committee, and the regional Arab
       TSOs committee.
      Reviewing the proper implementation by the parties of their obligations under the MOU,
       and submitting yearly progress reports to the Arab Ministerial Council for Electricity.
      Building and maintaining comprehensive information systems containing up-to-date data
       on member countries’ expansion plans, regulatory changes, and so on.
Second, a decision is needed by the Arab Ministerial Council for Electricity to approve the Pan-
Arab MOU a draft of which has been finalized by the League of Arab States and consulted with
Arab Countries. This document would provide the political endorsement and direction for
initiating the process. It would define the roles of the various regional market institutions and the
conflict-resolution mechanism. Such documents vary in scope. It is recommended that the Pan-
Arab MOU and general agreement be specific and well focused to cover:
      Energy-trade policy; mutual assistance in the event of disruption, operation and safeguard
       measures, and policy
      The institutional setup and the roles of the Arab Ministerial Council for Electricity, its
       Executive Bureau, the secretariat; the regional advisory and regulatory committee and the
       regional Arab TSOs committee
      The process of decision implementation and dispute settlement
      Other relevant aspects (budget, accession conditions, and so on)

                                                 11
Aside from the above immediate decisions, the following executive decisions are needed by the
time of finalizing the draft MOU:
      Agreement to form a regional advisory and regulatory committee to provide advice to the
       Arab Ministerial Council for Electricity and its Executive Bureau regarding governance
       documents and all cross-border operational matters such as transmission tariffs,
       allocation of transmission capacity, proposals for expansion of international
       interconnections, adequacy of generation reserve criteria, enforcing credit obligations and
       payment default procedures, dispute resolution, and so on
      An agreement to form a regional Arab TSOs committee
      An agreement to set up a subregional TSO/market facilitator for each of the GCC,
       EIJLLPST, and Maghreb interconnections




                                               12
‫)‪Executive Summary (Arabic‬‬
                                                                                                                            ‫ملخـــــص تنفيــــــــذي‬
                                                                                                                            ‫سياق وأهداف هذه الدراسة‬
‫لقد تمتعت الدول العربية بنمو اقتصادي مطرد في السنوات األخيرة‪ ،‬وأحدث هذا النمو الكبير زيادة سريعة في الطلب على‬
‫الطاقة‪ ،‬وال سيما على الكهرباء‪ .‬وبالرغم من أنه يمكن تقييد هذا الطلب المتزايد من خالل سياسات أكثر فعالية تستهدف حفظ‬
‫الطاقة‪ ،‬بما في ذلك استحداث تعديالت في تعريفات االستهالك‪ ،‬إال أنه ثمة حاجة واضحة للتوسع في طاقة توليد الكهرباء‬
‫وإمدادات الوقود في جميع البلدان العربية‪ .‬وفي السنوات األخيرة‪ ،‬تحولت مسألة توافر الغاز إلى قضية مهمة حيث أدركت دول‬
‫مثل الجمهورية العربية السورية والمملكة األرد نية الهاشمية والمملكة العربية السعودية والكويت واإلمارات العربية المتحدة‪،‬‬
‫وغيرها‪ ،‬أن إنتاجها المحلي من الغاز غير كاف لتلبية احتياجات قطاعات الطاقة لديها‪ .‬وقد أثار هذا البحث عن مصادر‬
                           ‫الستيراد الغاز أو الكهرباء‪ ،‬والذي بدوره أدى إلى محاوالت لبناء مرافق بنية تحتية عابرة للحدود‪.‬‬
‫تحقق شبكات الكهرباء المترابطة فيما بينها ‪ -‬إلى جانب توفير واردات الطاقة ‪ -‬سلسلة من فوائد إضافية مثل تحسين االعتمادية‬
‫في نظم الكهرباء‪ ،‬وخفض هوامش االحتياطي‪ ،‬ودعم القدرة غير الفعّالة ‪ ،‬وتبادل للطاقة بين الدول المشتركة من خالل‬
‫االستفادة من التنوع والتباين الذي يطرأ على الطلب اليومي والموسمي وانعكاس ذلك على التكاليف الحدية لإلنتاج‪ .‬وإدراكا‬
‫لفوائد التكامل اإلقليمي‪ ،‬تجري اآلن عدة مبادرات لربط شبكات الكهرباء في الدول العربية في محاولة لوضع نظم متكاملة‬
                 ‫لتبادل الكهرباء والتجارة فيها‪ .‬وتشمل المخططات األساسية للربط اإلقليمي للكهرباء بين الدول العربية ما يلي‪:‬‬
‫في عام ‪ 0591‬بدأ الربط المغاربي اإلقليمي الذي يضم المغرب والجزائر وتونس‪ ،‬وتطور ليصبح شبكات ربط متعددة‬                                                   ‫‪‬‬
‫لنقل التيار الكهربائي عالي الجهد بين البلدان الثالثة‪ .‬و في أواخر التسعينات من القرن الماضي تم ربط شبكتي‬
‫المغرب وأس بانيا‪ ،‬وأصبح اآلن‪ ،‬إلى جانب الجزائر وتونس‪ ،‬مرتبط تزامنيا بالشبكة األوروبية الشاملة لنقل التيار‬
                                                                                    ‫الكهربائي عالي الجهد‪.‬‬
‫الربط اإلقليمي بين ثمانية دول أو ما يسمى بالربط الثماني (وهي مصر‪ ،‬العراق ‪ ،‬األردن‪ ،‬ليبيا ‪ ،‬لبنان‪ ،‬فلسطين‪،‬‬                                              ‫‪‬‬
‫سوريا‪ ،‬وتركيا) بدأته مصر والعراق واألردن وسوريا وتركيا في عام ‪ 0511‬بهدف ترقية شبكات الكهرباء لديها‬
‫ليكون وفق معيار إقليمي محدد‪ . 6‬ثم انضمت لبنان وليبيا وفلسطين بعد ذلك إلى االتفاقية ليصبح عدد المنضمين إليها‬
‫إلى ثمانية‪ .‬ومن المتوقع أن تتزامن الشبكة التركية بالكامل مع الشبكة الكهربائية األوروبية في أوائل عام ‪،2102‬‬
                         ‫وهذه خطوة على طريق تزامن شبكة كهرباء الدول الثمانية مع الشبكات في تركيا وأوروبا‪.‬‬
‫الربط اإلقليمي لدول مجلس التعاون الخليجي يتيح تبادل الكهرباء بين الدول الست األعضاء فيها (وهي الكويت‬                                                   ‫‪‬‬
‫والسعودية والبحرين وقطر واإلمارات العربية المتحدة وسلطنة عمان) بموجب اتفاق وقّع في عام ‪ .2115‬ويستهدف‬
‫الربط تقاسم احتياطي قدرة التوليد وتحسين اعتمادية إمداد الطاقة مما سيقلل من الحاجة إلى االستثمار في قدرات‬
                                                                                             ‫توليد جديدة‪.‬‬
                                                     ‫شكل ‪ :ES1‬شبكات الربط القائمة والمخطط لها‬




‫‪ 6‬على الرغم من أن اتفاقية الربط اإلقليمي بين الدول الثماني قد تم توقيعها في الثمانينات إال أن الربط الفعلي بين سوريا واألردن وبين سوريا ولبنان قد تم إنشاؤه في‬
                                                                                                                                                     ‫السبعينيات‪.‬‬



                                                                              ‫‪1‬‬
                                                 ‫‪Ethiopia‬‬




                                                                                     ‫المصدر‪ :‬البنك الدولي‪ -‬جامعة الدول العربية‬



‫على الرغم من أن شبكات الربط في المنطقة المغاربية والدول الثمانية (‪ ) EIJLLPST‬تعمل منذ فترة ‪ ،‬ظلت تجارة الكهرباء‬
‫بين الدول العربية عند مستويات متواضعة بسبب عقبات تتمثل في محدودية هوامش احتياطي التوليد‪ ،‬وعدم وجود إطار‬
‫تنظيمي متناسق يضم قواعد واضحة تنظم تجارة الكهرباء‪ ،‬بسبب جوانب الضعف المؤسسي على المستويين الوطني واإلقليمي‬
‫(بمعنى أن الهيئات المسئولة تفتقر إلى األدوات‪ ،‬والبيانات‪ ،‬والحوافز الضرورية لتشجيع التجارة)‪ .‬لكن الرغبة في تحسين‬
‫تأمين اإلمدادات من خالل تنويع مصادر إمدادات الطاقة‪ ،‬و ال سيما في سياق البرامج اإلقليمية البينية لتطوير موارد الطاقة‬
                               ‫المتجددة كطاقة الرياح والطاقة الشمسية‪ ،‬قد حسنت من الحافز للتعامل مع نقاط الضعف هذه‪.‬‬
  ‫تجري جامعة الدول العربية اآلن دراسة مكونة من ثالثة أجزاء حول جدوى الربط البيني لألنظمة الكهربائية للدول العربية‪:‬‬
                                               ‫الجزء األول‪ :‬دراسة حول الربط البيني لألنظمة الكهربائية في العالم العربي‪.‬‬
                                                ‫الجزء الثاني‪ :‬دراسة جدوى حول تجارة الكهرباء – الغاز بين الدول العربية‪.‬‬
                                                                   ‫الجزء الثالث‪ :‬دراسة حول األطر المؤسسية والتنظيمية‪.‬‬
‫يتمثل الهدف الرئيسي لهذه الدراسة ذات األجزاء الثالثة ونطاقها في تحديد إستراتيجية وخطة رئيسية لتطوير تجارة الكهرباء‬
                                                  ‫بين الدول العربية‪ .‬وتعتبر األجزاء الثالثة للدراسة مكملة لبعضها‪ .‬ويش ّ‬
‫كل الجزء الثالث من الدراسة ‪ -‬والذي يمثل هذا التقرير‬
                                                         ‫جزءا منه ‪ -‬جهداً مشتركا ً بين جامعة الدول العربية والبنك الدولي‪.‬‬
‫يعتبر البنك الدولي نشطا بشكل خاص في هذه المنطقة من العالم‪ .‬ففي إطار "مبادرة العالم العربي"‪ ،‬أنجز البنك ثالث دراسات‬
‫لتقييم إمكانات التكامل في مجال الطاقة في المناطق دون اإلقليمية العربية الثالث‪ ،‬بما في ذلك الربط المغاربي‪ ،‬ودول الربط‬
‫الثماني ‪ ،‬ودول مجلس التعاون الخليجي‪ ،‬مع تنفيذ برنامج إقليمي رئيسي لزيادة الطاقة الشمسية المركزة ( ‪ )CSP‬في الشرق‬
                                                                                              ‫األوسط وشمال أفريقيا‪.‬‬



                                                            ‫‪2‬‬
‫تركز الدراسة التي تقوم بها الجامعة العربية بالتعاون مع البنك الدولي على الجوانب المؤسسية والتنظيمية للتجارة عبر الحدود‬
‫وتكامل سوق الكهرباء بين اثنتين وعشرين د ولة عربية‪ ،‬وبين الدول العربية واألسواق المجاورة المحتملة‪ .‬و تتألف هذه الدراسة‬
‫من مرحلتين‪ :‬المرحلة األولى‪ ،‬والواردة في هذا التقرير‪ ،‬تدرس هيكل وتصميم السوق اإلقليمية‪ ،‬في حين أن المرحلة الثانية‬
‫ستبحث في مبادئ لوائح السوق والترتيبات القانونية‪ .‬وسيتم تحديد الشك ل الدقيق ونطاق العمل الذي سيتم تنفيذه في المرحلة‬
                                    ‫الثانية بعد لقاءات التشاور بشأن هذا التقرير الخاص بالمرحلة األولى مع الجهات المعنية‪.‬‬
                                       ‫واتساقا ً مع الشروط المرجعية لجامعة الدول العربية تغطي هذه الدراسة ستة مجاالت‪:‬‬
‫تحليل اإلطار القانوني والتنظيمي لقطاعات الطاقة في البلدان المستهدفة‪ ،‬مع توجيه اهتمام خاص بتجارة الكهرباء‬           ‫‪‬‬
‫عبر الحدود‪ ،‬بما في ذلك إعداد وثائق الحوكمة المطلوبة مثل كود الشبكات‪ ،‬وتبادل الطاقة‪ ،‬و أكواد التغذية واإلمداد‬
                                                                                              ‫(قواعد السوق)‪.‬‬
‫تحديد العقبات المحتملة إلنشاء سوق عربية مشتركة للكهرباء باإلضافة إلى عوامل التمكين ‪ ،‬ووضع توصيات‬                   ‫‪‬‬
                                                                        ‫عملية لتذليل هذه العقبات‪.‬‬
‫‪ ‬تحديد الحواجز التي تعترض التبادل الفعال للطاقة بين الدول المعنية‪ ،‬ووضع السبل الممكنة لتسهيل التجارة والتكامل‬
                                                                                                    ‫اإلقليمي‪.‬‬
          ‫تحديد الدعم القانوني المطلوب إلحداث تطور تدريجي نحو سوق كهرباء إقليميةة تتسم بالتنافسية والكفاءة‪.‬‬        ‫‪‬‬
‫تطوير وتقييم الشروط العامة التي بموجبها يتم تجارة الكهرباء‪ ،‬مع األخذ بعين االعتبار القيود الدولية‪ ،‬مثل قواعد‬       ‫‪‬‬
‫االتحاد األوروبي للتداول في السوق‪ ،‬والقيود على الواردات‪ ،‬والقيود المفروضة على اتفاقيات األسعار طويلة‬
                                                                                        ‫األجل‪ ،‬والقواعد البيئية‪.‬‬
‫‪ ‬ا قتراح خطة عمل من أجل التفاوض بشأن المعاهدات أو االتفاقات الدولية الالزمة لتعزيز تجارة الكهرباء بين الدول‬
                                                                                    ‫العربية واألسواق المستهدفة‬
                                                                           ‫هدف التكامل اإلقليمي‪ ،‬ومسارات إنجازه‬
‫الهدف النهائي لسوق الطاقة المتكاملة هو تحسين إمدادات الكهرباء في إطار إقليمي واسع (وال ينحصر داخل الحدود الوطنية)‪.‬‬
‫ويغلب االعتقاد بأن هذا يمكن تحقيقه في بيئة تتوافر لكل طرف فيها فرص متساوية تتيح الوصول إلى جميع الشبكات (المحلية‬
‫واإلقليمية والدولية)؛ وتتسم فيه بيانات ومعلومات السوق (أي التسعير والتشغيل في السوق‪ ،‬وتوزيع القدرات‪... ،‬الخ) بالشفافية؛‬
    ‫وتغطي فيه تعريفة الكهرباء تكلفة اإلمداد‪ ،‬وتتميز فيه أكواد شبكات الكهرباء بالتناغم‪ ،‬والنظم بالتزامن‪ ،‬واألسواق بالتحرر‪.‬‬
‫يتكون الهدف من تكامل السوق من ثالثة أبعاد متم يزة هي‪ :‬تأمين اإلمداد‪ ،‬واالستدامة‪ ،‬والمنافسة‪ .‬وبالرغم من أن األبعاد الثالثة‬
‫كلها تظهر في جدول أعمال التكامل اإلقليمي في أجزاء مختلفة من العالم‪ ،‬إال أن التركيز على كل بعد قد تباين حسب أولويات‬
‫كل منطقة‪ .‬على سبيل المثال‪ ،‬في جدول أعمال تكامل االتحاد األوروبي‪ ،‬كان التركيز منصبا على المنافسة‪ .‬هذا التأكيد يدل‬
‫على أنه يمكن تحقيق تكامل السوق من خالل عملية إصالح منسقة‪ ،‬وهذا بدوره يعني أن تحرير األسواق الوطنية كل على حده‬
‫هو شرط أساسي لتحقيق التكامل اإلقليمي‪ .‬من ناحية أخرى‪ ،‬في شرق آسيا وأمريكا الالتينية وأجزاء من العالم العربي ‪ ،‬تم‬
‫التركيز على تحسين تأمين إمدادات الطاقة عن طريق بناء البنية التحتية المادية الالزمة واالعتماد على قواعد بسيطة لتشغيل‬
‫نظم الربط البيني‪ .‬هذا النهج يعترف بحقيقة أن مستويات التطور في األسواق الوطنية الفردية ليست متساوية‪ ،‬وأنه ال يمكن‬
                                                                     ‫توقع أن تمضي عملية تحرير هذه األسواق بنفس الوتيرة‪.‬‬
‫إن استعراض تجارب عالمية هي الوسيلة األكثر مالئمة لرؤية األمور في سياقها السليم‪ ،‬بمعنى أنه ليس هناك أدلة تشير إلى أن‬
‫أيا من خطط التكامل اإلقليمية القائمة أو الجاري إعدادها قد توصلت إلى النموذج السليم في المرحلة األولى من التكامل‪ .‬ومع‬
‫ذلك‪ ،‬من الواضح أن التعلم من أخطاء اآلخرين يمكن صانعي السياسات من تفادي إهدار الوقت والموارد‪ .‬وفي العقدين‬
‫الماضيين للتكامل‪ ،‬حقق التكامل اإلقليمي مكانة أعلى مع زيادة اإلدراك على نطاق أوسع بالفوائد التي تعود على البلدان‬
‫المتكاملة‪ ،‬على الرغم من أن كل مشروع تكامل استغرق وقتا طويال وجهدا كبيرا لكي يخرج إلى حيز الوجود‪ .‬وجدير بالذكر‬
‫أن المخططات األكثر نجاحا هي تلك التي اتبعت نهج التكيف وتعديل مسارها عند الحاجة‪ ،‬والتي ال تزال مستمرة في التعامل‬
‫مع التحديات المتوقعة وغير المتوقعة على حد سواء‪ .‬فنجاح مثل هذه المخططات يشير إلى الحاجة إلى إعداد خطة تنفيذ‬
‫واضحة‪ ،‬وإيجاد دعم سياسي يمكن االعتماد عليه في وقت مبكر‪ ،‬وإنشاء آلية للرصد يمكن أن تجذب اهتمام صناع القرار إلى‬
                                                                                         ‫العقبات والتحديات فور ظهورها‪.‬‬

                                                           ‫‪3‬‬
‫وقد أكدت مبادرات تكامل الكهرباء في العالم العربي بشكل مناسب على تأمين اإلمدادات‪ .‬ولكن الهدف من تكامل الكهرباء‬
‫اإلقليمي في العالم العربي سوف يتضمن أبعاد االستدامة و المنافسة كذلك‪ .‬ستكون األولوية للبعد األول‪ ،‬أي االستدامة‪ ،‬حيث‬
‫تحرص معظم الدول العربية على ضمان الحفاظ على موارد الطاقة لديها على المدى الطويل والتخفيف من األضرار البيئية‬
‫المحلية والعالمية‪ .‬كذلك سيكون بعد المنافسة مهم أيضا ‪ :‬فمعظم الدول العربية تعمل على إدخال مشاريع القطاع الخاص في‬
‫قطاع الطاقة‪ ،‬ولكنها تود التأكد من أن هذه المشاريع قادرة على المنافسة على الصعيد اإلقليمي‪ .‬ولذا فمن المقترح أن يقوم نهج‬
                                                               ‫التكامل اإلق ليمي في العالم العربي على االعتبارات التالية‪:‬‬
                           ‫اإلقرار بالصعوبة الكامنة في تحريك عدد كبير من البلدان األعضاء في اتجاه التوافق السياسي‪.‬‬                                    ‫‪‬‬
‫اإلقرار بتنوع النظم (واألسواق) الوطنية للكهرباء‪ ،‬وتنوع وتيرة عمليات اإلصالح‪ ،‬واالختالفات بين أنظمة الربط‬                                              ‫‪‬‬
                                                                       ‫البينية دون اإلقليمية الثالث القائمة‪.‬‬
                                                                                    ‫محاولة تنسيق القرارات المتعلقة بإصالح القطاع‪.‬‬                     ‫‪‬‬
                                                                                  ‫تعزيز الربط‪ /‬التكامل داخل كل منطقة دون إقليمية‪.‬‬                     ‫‪‬‬
                                                        ‫وضع اإلطار المؤسسي الالزم لتنسيق التحرك في اتجاه شبكة متناسقة‪.‬‬                                ‫‪‬‬
                                                                                          ‫تصميم مسار الوصول إلى سوق طاقة متكامل‬
‫تبدأ عملية وضع خطط التكامل اإلقليمي غا لبا بمحاولة تصميم نموذج لسوق متكامل‪ .‬لكن سرعان ما يصبح واضحا أنه في حين‬
‫أن النموذج المنشود يحفل بمجموعة من الميزات ‪ 7‬الواضحة‪ ،‬إال أن تحقيقها هو هدف بعيد األجل‪ .‬ومن ثم فإن التحدي المباشر‬
     ‫هو رسم صورة للمسار الذي ينقل المنطقة من وضعها الحالي إلى الحل المرغوب فيه بطريقة محسوبة ومنهجية وعملية‪.‬‬
‫ينبغي أن يأخذ مسار تكامل السوق في الحسبان الحقائق الراهنة‪ ،‬وعلى رأسها حقيقة أنه من غير المحتمل أن تتعامل دولة مع‬
‫دولة أخرى إذا كان سيترتب على ذلك وضع المستفيدين من الدولة األولى تحت رحمة إمدادات ضعيفة االعتمادية‪ .‬وهذا هو‬
‫دائما عامل إعاقة في المرحلة األولى من التكامل اإلقليمي عندما تحتاج كل دولة مشاركة إلى الضمانات والتأكيدات بأن نظم‬
‫الطاقة لدى الدول األخرى يمكن االعتماد عليها‪ .‬وهذا هو أيضا سبب مهم للتمييز بين دول المناطق دون اإلقليمية كدول مجلس‬
‫التعاون الخليجي و دول المغر ب العربي‪ ،‬و دول الربط الثماني‪ .‬وحاليا‪ ،‬تقف األسواق الثالثة دون اإلقليمية في مراحل مختلفة‬
‫من التطور‪ ،‬ويجب أن تعمل بشكل مستقل بسبب إما أنه ال يوجد ربط بينها أو أنها غير متزامنة‪ .‬ولكن من المرجح أن يتغير هذا‬
‫في المستقبل‪ .‬وفي نهاية المطاف‪ ،‬من المتوقع أن تندمج ا ألسواق العربية الثالث الفرعية في سوق واحد‪ ،‬بل وربما تندمج في‬
                                                                    ‫وقت الحق مع أسواق االتحاد األوروبي وآسيا وأفريقيا‪.‬‬
‫يُنظر في كثير من األحيان إلى تجربة االتحاد األوروبي الستنباط دروس في شأن دمج أسواق الكهرباء‪ .‬هذا التقرير يستعرض‬
‫تجربة االتحاد األوروبي من خالل فكرة أنه وثيق الصلة بتصميم النظم الرقابية والقانونية لشبكة الكهرباء العربية‪ .‬وقد يبدو‬
‫للوهلة األولى أن االتحاد األ وروبي قد حقق درجة عالية من التكامل في سوق الكهرباء بوتيرة سريعة‪ ،‬ولكن في واقع األمر‪،‬‬
‫كان االتحاد األوروبي يسعى جاهدا لحل جميع المسائل العملية التي يتم مواجهتها في أقاليم أخرى‪ .‬وقد انتقل العديد من المناطق‬
‫الفرعية في االتحاد األوروبي ببطء أكثر من غيرها في م سار تسهيل تجارة الكهرباء والتكامل‪ ،‬وال زال االتحاد األوروبي‬
‫يواصل تصحيح مسار التكامل بين األسواق المختلفة عن طريق تنقيح التوجيهات واإلرشادات ‪ .‬في الوقت نفسه‪ ،‬فإنه ربما‬
‫تكون التجربة األوروبية ذات قيمة للدراسة بسبب السياسة العامة الثابتة و المهارات المهنية والتقنية العالية التي ساهمت في‬
‫الحفاظ على تكامل السوق على المسار الصحيح‪ .‬إن استعراض تجربة االتحاد األوروبي يوفر مادة هامة في تحليل جانبين‬
‫متميزين من التكامل اإلقليمي للكهرباء‪( :‬أوال) وجود جدول أعمال شامل لتحقيق التكامل‪ ،‬و (ثانيا) وضع إستراتيجية للتعامل‬
‫مع األوضاع المختلفة السائدة في المناطق الفرعية من االتحاد األوروبي‪ .‬كال هذين الجانبين سيكونان مفيدان في تصميم المسار‬
                                                                                 ‫االنتقالي لتكامل األسواق في العالم العربي‪.‬‬
‫وبالنظر إلى الخبرة الدولية والوضع الراهن لقطاعات الكهرباء في الدول العربية‪ ،‬يحدد هذا التقرير مسار السوق نحو التكامل‬
                                                                                    ‫من خالل المراحل األربع التالية‪:‬‬


‫‪ 7‬يرد وصف هذه الميزات في متن التقرير‪ .‬تشمل المتطلبات األساسية لسوق كهرباء عربي مشترك ناجح ما يلي‪ :‬توافر بنية تحتية مادية الزمة (أي خطوط النقل ذات‬
‫الجهد العالي)‪ ،‬وقواعد فنية منسقة لتشغيل أنظمة الربط وكذلك قواعد تنسيق سوق الجملة؛ وفرص عادلة وغير تمييزية للوصول إلى البنية التحتية المادية‪ ،‬بما في ذلك‬
                 ‫آليات تسعير شفافة الستخدام هذه البنية التحتية‪ ،‬وآليات مناسبة للتنظيم والرقابة اإلقليمية على السوق‪ ،‬وإجراءات اإلنفاذ‪ ،‬ومخططات لتسوية المنازعات‪.‬‬



                                                                              ‫‪4‬‬
   ‫المرحلة األولى‪ :‬تنفيذ تصميم انتقالي لسوق عربي مشترك‪ ،‬مع التركيز على تحديد وتوسيع نطاق فرص التجارة‪.‬‬                                       ‫‪‬‬
‫المرحلة الثانية‪ :‬توسيع وظيفة السوق العربي المشترك االنتقالي‪ ،‬مع التركيز على تفكيك مؤسسات مشغلي نظم النقل‬                                    ‫‪‬‬
                                                               ‫(‪ ،) TSOs‬واستحداث المنافسة بنظام الجملة‪.‬‬
‫المرحلة الثالثة‪ :‬االنتقال نحو تصميم نهائي لسوق عربي مشترك‪ ،‬مع التركيز على منافسة كاملة بنظام الجملة‬                                         ‫‪‬‬
                                                                  ‫مدعومة من قبل أسواق مالية متعددة‪.‬‬
‫‪ ‬المرحلة الرابعة‪ :‬تحقيق سوق عربي مشترك تام التكامل‪ ،‬مع التركيز على شبكة عربية للربط الكهربائي التام‬
                                                                                         ‫والمتزامن‪.‬‬
‫ما ورد أعاله من خطة مراحل التنمية األربعة ممكنة من الناحية السياسية‪ ،‬وذلك تمشيا مع أفضل الممارسات‪ ،‬وتعد بتحقيق‬
‫أهداف التكامل طويلة األجل‪ ،‬وتضمن مراحلها نهج تدريج ي لكنه متسق ومتماسك يقود نحو تنمية تجارة الكهرباء وتكامل‬
                                                                                                      ‫األسواق‪.‬‬


                                                                                                         ‫اإلستراتيجية طويلة األجل المقترحة‬
 ‫لترجمة ما ورد أعاله من مراحل الرؤية األربعة إلى واقع عملي‪ ،‬يستلزم ابتكار إستراتيجية واضحة وثابتة على المدى الطويل‬
      ‫تحدد إجراءات محددة لتطبيق السياسات التي ي نبغي اتخاذها في كل مرحلة من مراحل تطوير السوق‪ .‬يلخص الجدول (‬
      ‫‪ )ES1‬مضمون اإلستراتيجية المقترحة‪ ،‬والتي تركز على القرارات الخاصة بالسياسات المتعلقة ببناء المؤسسات واألطر‬
  ‫القانونية والتنظيمية‪ .‬وتعترف اإلستراتيجية بأن المناطق الفرعية الثالث تقف عند مراحل مختلفة من تطور السوق‪ .‬ومع ذلك‬
     ‫فإن بناء المؤسسات للشبكة العربية الشاملة بأكملها سيساعد في نقل المعرفة والمهارات والمعلومات فيما بين المناطق دون‬
  ‫اإلقليمية الثالثة‪ ،‬وكذلك من الدول المجاورة‪ .‬ويالحظ أيضا أن بناء المؤسسات في كل مرحلة مصمم بحيث يلبي متطلبات تلك‬
                                                                        ‫المرحلة واالستعداد لالنتقال إلى المرحلة المقبلة‬
                                        ‫‪.‬جدول ‪ : ES1‬ملخص اإلستراتيجية المقترحة طويلة األجل‬
 ‫البناء المؤسسي‪ ،‬اإلطار القانوني‪ ،‬وطرق‬                       ‫التوسع في البنية األساسية وتجارة الكهرباء‬                         ‫مرحلة التطور‬
          ‫اتخاذ القرارات‬
                        ‫تشكيل أمانة‪/‬سكرتارية‬      ‫تحدد مؤسسات تشغيل نظام نقل الطاقة‪ /‬مسهلو السوق فرص التجارة‬                 ‫المرحلة األولى‪:‬‬
                                                                                 ‫بناء على األسعار الدولية للوقود‬          ‫سوق انتقالي يُركز على‬
                                                                                                                           ‫تحديد فرص التجارة‬
                                                                                                                              ‫والتوسع فيها‬
 ‫تشكيل لجنة استشارية وتنظيمية عربية مشتركة‬              ‫زيادة حجم التجارة المتوقعة بين مجموعة دول الربط الخليجي‪،‬‬
                                                       ‫ومجموعة الدول للربط الثماني‪ ،‬و مجموعة دول الربط المغاربي‬
                                                                                                              ‫العربي‬
  ‫إنشاء لجنة عربية مشتركة تضم المؤسسات‬                 ‫تنفيذ التداول وفق عقود ثنائية مباشرة بين المرافق يتم إبرامها بين‬
                 ‫العربية لتشغيل نظم نقل الطاقة‬                                        ‫الدول المجاورة وغير المجاورة‬
  ‫ميسر‬‫إنشاء مؤسسة لتشغيل نظم نقل الطاقة‪ُ /‬‬                                        ‫تقدم بعض الدول خدمة النقل‪ /‬المرور‬
                       ‫‪8‬‬
                         ‫سوق لكل منطقة فرعية‬
                   ‫تطوير ما يلي والتوقيع عليه‪:‬‬                                           ‫تنفيذ البنية األساسية من خالل‪:‬‬
    ‫‪ ‬مذكرة تفاهم واتفاقية عامة لتكامل سوق‬                ‫‪ ‬توسيع توليد الطاقة لتلبية االحتياجات الوطنية والصادرات‬
                ‫الكهرباء العربي المشترك‬             ‫‪ ‬استغالل توليد الكهرباء في تلبية فروق الطلب الموسمي واليومي‬
        ‫‪ ‬اتفاقية عامة لسوق الكهرباء العربي‬                                  ‫لما هو أبعد من حدود األسواق المحلية‬
                                   ‫المشترك‬          ‫‪ ‬توسيع الربط البيني القائم عبر الحدود بالنسبة لتجارة الجملة في‬
              ‫‪ ‬اكواد الشبكة العربية الموحدة‬             ‫الكهرباء (على سبيل المثال‪ ،‬بين العراق وسوريا‪ ،‬واألردن‬
   ‫تنسيق األساسيات الفنية واالعتمادية للشبكة‬            ‫ومصر‪ ،‬ومصر وليبيا‪ ،‬وليبيا وتونس‪ ،‬والجزائر والمغرب)‬
        ‫توسيع قاعدة البيانات للكهرباء العربية‬                                         ‫‪ ‬تحديث شبكات النقل الوطنية‬
   ‫المشتركة لتتضمن معل ومات شاملة وحديثة‬
                                                                                                                                                ‫‪8‬‬
‫ميسر السوق اإلقليمي‬‫لدى هيئة الربط الكهربائي لدول مجلس التعاون الخليجي (‪ ) GCCIA‬العديد من المسؤوليات المقترحة لمؤسسة تشغيل نظم نقل الطاقة‪ُ /‬‬
‫الفرعي‪ ،‬ولكن ليس للكل (على سبيل المثال‪ ،‬ال تنشر هذه الهيئة أسعار السوق)‪ ،‬وبالتالي سيكون من الضروري إدخال بعض التعديالت في مسئولياتها لتتمكن من‬
                                                                                                                           ‫االضطالع بهذا الدور‪.‬‬



                                                                        ‫‪5‬‬
 ‫لخطط التوسع لكل دولة وبرامج االستثمارات‬                                                     ‫ربط دولي إضافي‪:‬‬
                         ‫والتغيرات التنظيمية‬                                              ‫‪ ‬مصر – السعودية‬
   ‫إعداد تعريفا ت نقل الطاقة واعداد مزاد قدرة‬                                               ‫‪ ‬مصر ‪ -‬السودان‬
                        ‫نقل الطاقة عبر الحدود‬                                             ‫‪ ‬موريتانيا ‪ -‬المغرب‬
                                                                                            ‫‪ ‬السعودية ‪ -‬اليمن‬
‫البناء المؤسسي‪ ،‬اإلطار القانوني وطرق اتخاذ‬                ‫التوسع في البنية األساسية وتجارة الكهرباء‬                      ‫مرحلة التطور‬
                   ‫القرارات‬
‫الموافقة على فتح إمدادات الكهرباء عالية الجهد‬‫توفير عنصر المنافسة أمام كبار المستهلكين المتصلين بشبكة نقل‬               ‫المرحلة الثانية ‪:‬‬
‫أمام المنافسة والسماح بتحديد التعريفات بالنسبة‬                                                      ‫الطاقة مباشرة‬   ‫توسيع السوق اإلقليمي‬
   ‫لكبار المستهلكين بواسطة السوق التنافسي‪.‬‬   ‫مزيد من العمل بهدف تحسين االستدامة وتأمين إمداد الطاقة الكهربائية‬      ‫االنتقالي مع التركيز على‬
                                             ‫تسهيل التجارة من خالل مزيد من التعزيز لشبكات النقل والتزامن‪.‬‬           ‫فصل مؤسسات تشغيل‬
‫ويتم تزامن النظم على مستوى كل مجموعات الربط دون اإلقليمية فصل مؤسسات تشغيل نظم نقل الطاقة من خالل‬                       ‫نظم نقل الطاقة‬
‫(مجموعتي الربط الخليجي و الربط المغاربي متزامنين بالفعل ؛ تفكيك األسواق الوطنية وإنشاء جهات تنظيمية‬                  ‫واستحداث المنافسة‬
                     ‫وطنية مستقلة ومستنيرة‪.‬‬                                      ‫تز امن كافة مجموعة دول الثماني)‬         ‫بنظام الجملة‬
‫إنشاء جهة رقابية عربية (تبدأ بدور يتضمن‬
‫إعداد التقارير والتنسيق وحل المنازعات قبل أن‬                    ‫تنسيق االستثمارات في البنية األساسية لنقل الطاقة‪.‬‬
‫تصبح جهةرقابية تتولى القيام بكامل المهام‬
                               ‫المنوطة بها)‪.‬‬

‫استبدال اللجنة اإلقليمية العربية لتشغيل نظم نقل‬
‫الطاقة بمؤسسة عربية شاملة تتولى ذلك األمر‬
‫ويكون لها مجلس إدارة وهيئة كاملة من‬
                        ‫الموظفين المنتظمين‪.‬‬

‫مراجعة أدوار األمانة واللجنة اإلقليمية‬
‫االستشارية والتنظيمية بما يعكس أدوار‬
‫المؤسسات الوطنية الجديدة لتشغيل نظم نقل‬
                   ‫الطاقة والجهات التنظيمية‪.‬‬
‫تعديل دور المؤسسات شبه االقليمية لتشغيل‬
‫نظم نقل الطاقة‪/‬مُيسري السوق لتتولى‬
     ‫مسئوليات أكثر تتعلق بمهام تشغيل السوق‪.‬‬

‫تعديل كود الشبكة اإلقليمية حسب الحاجة‪ ،‬وعمل‬
‫مراجعات موسعة في االتفاقية العامة لسوق‬
‫الكهرباء العربي المشترك بما يتسع لتجارة‬
                ‫تنافسية على مستوى الجملة‪.‬‬




                                                                     ‫‪6‬‬
 ‫البناء المؤسسي‪ ،‬اإلطار القانوني‪ ،‬وطرق‬                      ‫التوسع في البنية األساسية وتجارة الكهرباء‬                     ‫مرحلة التطور‬
          ‫اتخاذ القرارات‬
‫الموافقة على فتح السوق أمام المنافسة الكاملة‬      ‫تحقيق المنافسة الكاملة على مستوى نظام الجملة مع السماح لكافة كبار‬       ‫المرحلة الثالثة‪:‬‬
                      ‫على مستوى نظام الجملة‪.‬‬                  ‫المستهلكين وجهات التوزيع‪ /‬التوريد حق اختيار المُورِّد‪.‬‬    ‫الوصول إلى السوق‬
                                                  ‫استحداث أسواق مالية جديدة حسبما تقتضي حاجة المتعاملين في‬              ‫اإلقليمي النهائي مع‬
‫تشغيل األسواق المالية اإلضافية (على سبيل‬          ‫السوق العربي المشتركمثل سوق التوازن القائم على المزايدات "‪bid-‬‬       ‫التركيز على المنافسة‬
‫المثال‪ ،‬سوق اليوم التالي " ‪day-ahead‬‬              ‫‪ ،" based balancing market‬و سوق اليوم التالي‪ ،‬وسوق التبادل‬             ‫الكاملة مؤسسات‬
‫‪ )market‬حسبما يحتاج المتعاملون في السوق‪.‬‬          ‫خالل اليوم " ‪ ،" intraday market‬وسوق تداول االنبعاثات‪ ،‬الخ‪.‬‬          ‫تشغيل نظم نقل الطاقة‬
                            ‫العربية المشتركة‬                                                                            ‫وإستحداث المنافسة‬
                                                  ‫تشجيع األسلوب االقتصادي الكفء (بما يتسق مع أهداف المنافسة‬                ‫بنظام الجملة‬
‫استبدال منتدى المؤسسات الوطنية لتشغيل نظم‬                           ‫واالستدامة و اعتمادية‪ /‬تأمين اإلمداد‪.‬‬
‫نقل الطاقة‪ /‬مُيسرو السوق بمؤسسة تشغيل سوق‬
‫إقليمي يكون مسئول عن كافة األسواق المالية‬         ‫عمل مزيد من التحسين لقدرات نقل الطاقة والتزامن على المستويات‬
‫اإلقليمية الوظيفية التي لم يتم تنفيذها وتشغيلها‬   ‫الوطنية والدولية‪ ،‬وذلك باالتساق مع احتياجات السوق العربي‬
           ‫بواسطة مؤسسات القطاع الخاص‪.‬‬                                                                 ‫المشترك‪.‬‬

‫تسريح األمانة وإعطاء مسئولية الرقابة الكاملة‬
‫على السوق العربية المشتركة لمؤسسة تشغيل‬
‫السوق العربية المشتركة ‪ ،‬ومؤسسة تشغيل نظم‬
‫نقل الطاقة العربية ‪ ،‬وجهاز التنظيم العربي ‪،‬‬
‫على أن تكون الرقابة من قبل المجلس الوزاري‬
                             ‫العربي للكهرباء‪.‬‬

‫تعديل وثائق حوكمة السوق العربية المشتركة‬
‫حسب الحاجة لتتضمن المنافسة الكاملة بنظام‬
        ‫الجملة واألسواق المالية المنشأة حديثا‪.‬‬

‫ضمان أن تكون لدى مؤسسات السوق العربية‬
‫المشتركةالمسئولية الكاملة عن تحديد تعريفات‬
‫نقل الطاقة وإنفاذ قواعد فنية ومالية موحدة عبر‬
                       ‫السوقالعربية المشتركة ‪.‬‬
‫إعداد وتنفيذ خطة موحدة لتنمية الطاقة العربية‬      ‫الربط الكهربي المتزامن (أو غير المتزامن) لمجموعات الربط دون‬           ‫المرحلة الرابعة‪:‬‬
‫الشاملة (ويمكن أن تتضمن ثالث خطط‬                  ‫اإلقليمية الثالث بما في ذلك البلدان غير الموصلة حاليا بأي من‬        ‫سوق عربية متكاملة‬
‫لمجموعات الربط دون اإلقليمية تتسق مع‬                                                  ‫تماما مع التركيز على مجموعات الربط دون اإلقليمية‪.‬‬
‫الخطط الوطنية وتغطي كل من قدرات توليد‬             ‫الربط البيني والمتزامن يتم تزامن المنطقة أيضا مع الشبكة األوروبية لمؤسسات نظم نقل‬
               ‫ونقل الطاقة التقليدية والمتجددة)‬   ‫التام بين شبكات الكهرباء الطاقة الكهربائية (‪ )ENTSO-E‬واألسواق األخرى في المنطقة‬
‫إعداد خطة لتزامن (أو عدم تزامن) لمجموعات‬                                                                    ‫المحيطة‪.‬‬        ‫العربية‬
‫الربط الثالث دون اإلقليمية مع الشبكة‬              ‫إتاحة الوصول الكامل إلى شبكة الربط والمنافسة التامة بنظام الجملة‬
‫األوروبية لمؤسسات نظم نقل الطاقة الكهربائية‬       ‫مع تواجد مؤسسات سوق عربية مشتركة تمارس وظائفها كاملة وكذا‬
‫(‪ )ENTSO-E‬وأسواق الكهرباء اإلقليمية في‬                                                         ‫توافر وثائق حوكمة لها‪.‬‬
                            ‫المنطقة المجاورة‪.‬‬


                                                                                                    ‫ملحوظة‪ = TSO :‬مؤسسة تشغيل نظم نقل الطاقة؛‬
                                                                                                                  ‫‪ = GCC‬مجلس التعاون الخليجي؛‬
                                     ‫‪ = EIJLLPST‬الربط الكهربي بين دول الثماني ( مصر‪ ،‬العراق‪ ،‬األردن‪ ،‬ليبيا‪ ،‬لبنان‪ ،‬فلسطين‪ ،‬سوريا‪ ،‬تركيا)؛‬
                                                                             ‫‪ = ENTSO-E‬الشبكة األوروبية لمؤسسات نظم نقل الطاقة الكهربائية)؛‬

                                                                                                                 ‫‪( = REM‬سوق كهرباء إقليمي)‪.‬‬




                                                                         ‫‪7‬‬
‫على الرغم من أنه ينبغي على اإلستراتيجية الرباعية المراحل أن توفر اإلطار الالزم لبناء المؤسسات و وطرق اتخاذ‬
‫القرارات‪ ،‬إال أنه يجب أن يكون التركيز في المقام األول على توضيح تفاصيل ما يجب تحقيقه خالل المرحلة األولى‪ .‬تبعا لذلك‪،‬‬
‫فقد قمنا بتطوير تصميم معين لسوق عربية مشتركة للمرحلة األولى وخطة تنفيذ تحتوي على القرارات المؤسسية وتلك المتعلقة‬
‫بالسياسات التي يجب اتخاذها خالل هذه المرحلة‪ .‬وتشمل العناصر الرئيسية في الخطة المقترحة إعداد الوثائق المطلوبة‬
                                                                                        ‫للحوكمة والمؤسسات اإلقليمية‪.‬‬
‫الخطة المقترحة توجه تركيز وثائق الحوكمة وبناء المؤسسات اإلقليمية على هدف تحقيق تكامل سوق الكهر باء‪ .‬ومن ثم‪ ،‬فهي‬
‫ال تقترح سوى عدد محدود من الوثائق اإلقليمية‪ ،‬وكذلك عدد قليل جدا من الكيانات اإلقليمية‪ .‬بشكل أكثر تحديدا‪ ،‬تتصور الخطة‬
                                                                   ‫أن تشمل وثائق الحوكمة أربعة بنود رئيسية فقط هي‪:‬‬
                                                                                                                    ‫مذكرة تفاهم رفيعة المستوى‬               ‫‪‬‬
                                                                                                                                         ‫اتفاقية عامة‬       ‫‪‬‬
                                                                                            ‫اتفاقية عامة لسوق الكهرباء العربية المشتركة‬                     ‫‪‬‬
                                                                                                       ‫‪9‬‬
                                                                                                        ‫كود شبكة الكهرباء العربية المشتركة‬                  ‫‪‬‬

 ‫وبالمثل‪ ،‬فإن الخطة تدعو إلى تشكيل أمانة‪ ،‬مع معالجة االحتياجات اإلقليمية األخرى من خالل محافل تنسيق معينة وأنشطة‪.‬‬
                                                                                     ‫وتتضمن محافل التنسيق ما يلي‪:‬‬
       ‫لجنة عربية مشتركة استشارية وتنظيمية تشتمل على عضو واحد من الجهاز التنظيمي في كل دولة مشاركة في‬                                                       ‫‪‬‬
                                                                                ‫السوق العربي المشترك‪.‬‬
                                                   ‫لجنة عربية مشتركة للمؤسسات العربية المسئولة عن تشغيل نظم نقل الطاقة‪.‬‬                                     ‫‪‬‬
‫وعلى األجل الطويل سيتم تنفيذ كل هذه المهام بواسطة جهة رسمية‪ .‬ومع ذلك فإنه من المرغوب فيه على األجل القريب أن يتم‬
‫إنشاء مثل هذه المؤسسات العربية المشتركة بحيث تتجنب االلتزامات المالية اإلضافية من الدول األعضاء‪ .‬ولهذا الغرض فإن‬
                                                  ‫المهام المقترحة سيتم تنظيمها اعتمادا على الجهات القائمة طبقا لما يلي‪:‬‬
‫المهمة االستشارية والتنظيمية العربية المشتركة ومهمة المؤسسات العربية المسئولة عن تشغيل نظم نقل الطاقة سيتم‬                                                  ‫‪‬‬
‫القيام بها من خالل إنشاء لجنتين مقابلتين ودعوة أعضاء مناسبين طبقا لمهمة كل لجنة‪ .‬وباإلضافة إلى ذلك‪ ،‬سيتم‬
‫دعوة األطراف الرئيسية ذات الصلة مثل االتحاد العربي للكهرباء والمنتدى العربي لمنظمي الكهرباء للمشاركة في‬
                                                                                        ‫اللجان ذات الصلة‪.‬‬
                                                                          ‫يتولى ا لقيام بدور األمانة إدارة الطاقة بجامعة الدول العربية‪.‬‬                     ‫‪‬‬
‫تقترح الخطة كذلك أن تنشأ مؤسسات تشغيل نظم نقل الطاقة ‪ /‬ميسري السوق لمجموعات الربط دون إقليمية لتيسير األسواق‬
‫داخل كل مجموعة من مجموعات الربط (الخليجي والمغاربي ودول الربط الثماني)‪ .‬ويتمثل دور تلك المؤسسات‪ /‬ميسري‬
‫السوق في مجموعات الربط دون اإلقليمية في تحد يد الفرص التجارية من خالل العمل بشكل وثيق مع البلدان المشاركة‪ .‬وهيئة‬
‫الربط لمجلس التعاون الخليجي بالفعل بصدد عملية تعزيز مثل هذه الوظيفة داخل الهيئة‪ .‬وبمرور الوقت‪ ،‬يمكن للمرء أن‬
                   ‫يستعرض مزايا خلق مؤسسة واحدة لتشغيل نظم نقل الطاقة ‪ /‬ميسر سوق على المستوى العر بي المشترك‪.‬‬
‫أخيرا‪ ،‬تجدر اإلشارة إلى أن تنمية مصادر الطاقة المتجددة قد احتلت مكانا بارزا في مداوالت التكامل اإلقليمي في االتحاد‬
‫األوروبي‪ ،‬وأصبحت تأخذ قدرا كبيرا من االهتمام في مناقشة شبكة الربط بين الدول العربية‪ .‬إن تأثير مصادر الطاقة المتجددة‬
‫على التكامل اإلقليمي هو أربعة أضعاف‪ .‬أوال ‪ ،‬معظم مواقع تلك المصادر (مزارع الرياح وحقول الطاقة الشمسية) بعيدة عن‬

‫‪ 9‬ومن شأن مذكرة التفاهم أن تكون وثيقة حكومية رفيعة المستوى يوقع عليها وزراء الكهرباء في جميع الدول العربية‪ ،‬بهدف وضع التزامهم بمواصلة إصالح السوق بما‬
‫يتفق مع أهداف التكامل بين األسواق اإلقليمية‪ .‬وينبغي أن تكون االتفا قية العامة وثيقة حكومية رفيعة المستوى تحدد أهداف ومبادئ تكامل األسواق اإلقليمية‪ ،‬وتحدد‬
‫أدوار ومسؤوليات الكيانات الخاصة بالسوق العربية المشتركة‪ .‬كما أن االتفاقية العامة الخاصة بالسوق العربية المشتركةللكهرباء ستكون وثيقة ذات مستوى أدنى توفر‬
‫المزيد من التفا صيل عن كيفية استيفاء البلدان االلتزام المحدد في مذكرة التفاهم‪ ،‬وتحدد القواعد المتعلقة بالتجارة‪ .‬أما كود الشبكة العربية المشتركةفسيعين الحد األدنى‬
                                                                                                                                    ‫من المعايير التقنية للمنطقة ككل‪.‬‬




                                                                                 ‫‪8‬‬
‫شبكات الكهرباء وستتطلب خطوط مخصصة لنقل الطاقة إلى الشبكة‪ ،‬مما سيؤثر على القدرة اإلجمالية للنقل وإمكانية تجارة‬
‫الكهرباء‪ .‬ثانيا‪ ،‬من المتوقع أن ينمو إمداد الك هرباء باستخدام مصادر الطاقة المتجددة بشكل متزايد بحيث تساهم كأحد المصادر‬
‫لتصدير الكهرباء‪ .‬ثالثا‪ ،‬سينشأ عن التكامل العربي المشترك لشبكات الكهرباء قدرة أكبر وأكثر تنوعا لتوليد الطاقة في األسواق‬
‫الوطنية المعزولة‪ ،‬مما سيتيح فرصة أفضل لتطوير مصادر الطاقة المتج ددة وربما حوافز تجارية أقوى لتطوير صناعة محلية‬
‫تُعنى بتصنيع معدات خاصة بالطاقة المتجددة‪ .‬رابعا‪ ،‬هناك كثير من الدعم المالي الدولي ألغراض تنمية مصادر الطاقة‬
‫المتجددة ‪ ،‬والتي يمكن استغاللها من قبل مؤسسات القطاعين العام والخاص لتوسيع قدرة توليد الكهرباء من مصادر الطاقة‬
       ‫المتجددة مع تعزيز الربط الكهربي عبر الحدود بما يساعد على االندماج بين مصادر الطاقة المتجددة والتكامل اإلقليمي‪.‬‬
‫ولتنمية مصادر الطاقة المتجددة أهمية خاصة لتطوير أكواد الشبكة‪ .‬فإدماج الكهرباء المنتجة من مصادر الطاقة المتجددة‪،‬‬
‫وخاصة طاقة الرياح‪ ،‬بشبكة الكهرباء يثير مخاوف محددة بشأن استقرار النظام‪ .‬ولكي يمكن الحفاظ على ثبات تشغيل الشبكة‪،‬‬
‫وهناك حاجة للتأكد من وجود مصادر أخرى لتوليد الطاقة لتعويض التنوعات في توليد الكهرباء من مصادر الطاقة المتجددة‬
‫على مدار الساعة‪ .‬وتشمل القضايا الفنية المرتبطة أنظمة الدعم االحتياطي ونوعية الطاقة‪ .‬ويمكن أيضا لكود الشبكة أن يتطلب‬
            ‫مواصفات فنية معينة من مصنعي ومطوري مصادر الطاقة المتجددة للحد من اآلثار المترتبة على استقرار الشبكة‬
                                                                                                                 ‫قرارات تنفيذية رفيعة المستوى‬
‫ستتطلب خطة التنفيذ المذكورة أعاله مجموعة من قرارات تنفيذية على م ستوى رفيع (وزاري) لدفع العملية إلى األمام‪ .‬هناك‬
‫نوعان من القرارات الفورية التي ينبغي جدولتها زمنيا في أقرب وقت ممكن‪ .‬أوال‪ ،‬هناك حاجة إلى قرار تنفيذي إلنشاء أمانة‬
‫من شأنها تحريك العملية إلى األمام ‪ . 10‬وكما ذكرنا‪ ،‬فإن هذه المهمة على األمد القريب سيتم القيام بها بواسطة أمانة جامعة‬
                                                              ‫الدول العربية والتي تشمل المسئوليات الرئيسية لها ما يلي‪:‬‬
‫توفير الدعم اإلداري للمجلس الوزاري العربي للكهرباء ومكتبه التنفيذي‪ ،‬واللجنة العربية المشتركة االستشارية‬                                                 ‫‪‬‬
                            ‫التنظيمية ‪ ،‬واللجنة العربية المشتركة للمؤسسات العربية لتشغيل نظم نق ل الطاقة‪.‬‬
‫استعراض التنفيذ السليم من جانب األطراف اللتزاماتها بموجب المعاهدة‪ ،‬وتقديم تقارير سنوية إلى المجلس الوزاري‬                                               ‫‪‬‬
                                                                         ‫محرز‪.‬‬‫العربي للكهرباء عن التقدم ال ُ‬
‫بناء وصيانة نظم معلومات شاملة تحتوي على أخر البيانات عن خطط التوسع في البلدان األعضاء‪ ،‬والتغيرات‬                                                        ‫‪‬‬
                                                                               ‫التنظيم ية‪ ،‬وهلم جرا‪.‬‬
    ‫ثانيا‪ ،‬هناك حاجة هناك حاجة القرار مذكرة التفاهم العربي الشامل (تم اعداد مسودتها األخيرة من قبل جامعة الدول العربية‬
  ‫باستشارة الدول العربية)‪ .‬هذه الوثيقة ستوفر الدعم السياسي والتوجيه الالزم لبدء العملية‪ ،‬حيث ستحدد أدوار مؤسسات السوق‬
  ‫العربية المشتركة المختلفة‪ ،‬وآلية لتسوية المنازعات‪ .‬وستختلف هذه الوثائق من ناحية نطاقها‪ .‬ومن المستحسن أن تكون مذكرة‬
                                           ‫التفاهم العربي الشاملة واالتفاقية العامة محددة ومركزة بشكل جيد لتغطية ما يلي‪:‬‬
‫السياسات المتعلقة بتجارة الطاقة؛ المساعدة المتبادلة في حالة حدوث اختالل في النظام وإجراءات التشغيل و‪.‬التدابير‬                                           ‫‪‬‬
                                                                                        ‫الوقائية وخطط العمل‪.‬‬
‫البنية المؤسسية ودور كل من المجلس الوزاري العربي للكهرباء ومكتبه التنفيذي‪ ،‬واألمانة‪ ،‬واللجنة العربية المشتركة‬                                           ‫‪‬‬
                              ‫االستشارية التنظيمية‪ ،‬واللجنة المشتركة للمؤسسات العربية لتشغيل نظم نقل الطاقة‪. .‬‬
                                                                                               ‫عملية تنفيذ القرارات وتسوية المنازعات‪.‬‬                   ‫‪‬‬
                                                                  ‫الجوانب األخرى ذات الصلة (الموازنة‪ ،‬وشروط االنضمام‪ ،‬إلخ)‬                              ‫‪‬‬
‫وبغض النظر عن القرارات الفورية المذكورة أعاله‪ ،‬هناك حاجة التخاذ القرارات التنفيذية التالية بحلول موعد االنتهاء من‬
                                                                                           ‫إعداد مشروع مذكرة التفاهم‪:‬‬


                                                                                                                                                             ‫‪10‬‬
‫هناك عدد من مبادرات التكامل اإلقليمي موجودة بالفعل بما في ذلك الربط بين دول مجلس التعاون الخليجي‪ ،‬والمغرب العربي‪ ،‬ودول الثماني‪ ،‬ومبادرة حوض‬
‫النيل (النيل)‪ ،‬والملكية المشتركة بين غينيا ومالي وموريتانيا والسنغال وتقاسم قدرات توليد ونقل الطاقة الكهرومائية‪ .‬وستحتاج األم انة إلى االستفادة من إنجازات‬
                                                                                              ‫وأنشطة هذه الكيانات لالضطالع بواج باتها في المنطقة بأسرها‪.‬‬




                                                                               ‫‪9‬‬
‫االتفاق على تشكيل لجنة عربية مشتركة استشارية تنظيمية لتوفير المشورة للمجلس الوزاري العربي للكهرباء ومكتبه‬       ‫‪‬‬
‫التنفيذي بشأن وثائق الحوكمة‪ ،‬وجميع المسائل المتعلقة بالتشغيل عبر الحدود مثل تعريفات نقل الطاقة‪ ،‬وتوزيع‬
‫قدرات النقل‪ ،‬والمقترحات الخاصة بتوسيع الربط الدولي‪ ،‬وكفاية معايير احتياطي توليد الطاقة‪ ،‬وتطبيق االلتزامات‬
                                                 ‫االئتمانية‪ ،‬وإجراءات التعثر في الدفع‪ ،‬وتسوية المنازعات‪ ،‬إلخ‪.‬‬
                                          ‫اتفاق لتشكيل لجنة مشتركة للمؤسسات العربية لتشغيل نظم نقل الطاقة‪.‬‬      ‫‪‬‬
‫ميسر سوق لكل من شبكات الربط بدول مجلس التعاون الخليجي‪ ،‬ودول‬
                                                          ‫اتفاق إلقامة مؤسسة لتشغيل نظم نقل الطاقة ‪ُ /‬‬          ‫‪‬‬
                                                                        ‫الربط الثماني‪ ،‬والمغرب العربي‪.‬‬




                                                         ‫‪10‬‬
Volume I: Main Report




         11
1        Background, Purpose, and Organization of the Report
1.1      Background
The Arab countries have enjoyed sustained economic growth in recent years, and the high
economic growth has triggered a rapid increase in energy demand, particularly for electricity.
Although part of this growing demand may be curbed through more effective energy
conservation policies, including tariff adjustments, there is a clear need to expand generating
capacity and fuel supply in all Arab countries. In recent years, gas availability has turned into a
serious issue as countries such as Syria, Jordan, Saudi Arabia, Kuwait, the United Arab Emirates
(UAE), and others have realized that their domestic gas production is insufficient to meet the
needs of their power sectors. This has triggered a search for sources of imported gas or
electricity, which has in turn led to attempts to construct cross-border infrastructure facilities.
Besides enabling energy imports, interconnected power networks impart a series of additional
benefits such as improved system reliability, reduced reserve margins, reactive power support,
and energy exchanges that take advantage of daily and seasonal demand diversity and disparities
in marginal production costs. As a result, a world-class electricity supply system can be achieved
with much lower capital expenditures and ongoing expenses than would otherwise be attainable
on an individual-country basis.
Recognizing the benefits of regional integration, several bilateral and subregional initiatives are
under way to interconnect the electricity networks of Arab countries to enable exchange and
trade (see figure 1.1). The primary regional interconnection schemes among Arab countries
currently include:
        The Maghreb regional interconnection, which includes Morocco, Algeria, and Tunisia,
         and was initiated in the 1950s and evolved into multiple high-voltage transmission
         interconnections between the three countries. Morocco was connected to Spain in the late
         1990s, and Morocco, Algeria, and Tunisia are now all synchronized with the pan-
         European high-voltage transmission network.
        The eight-country (Egypt, Iraq, Jordan, Libya, Lebanon, Palestine, Syria, and Turkey
         [EIJLLPST]) regional interconnection, which was initiated in 1988 by Egypt, Iraq,
         Jordan, Syria, and Turkey as part of an effort to upgrade their electricity systems to a
         regional standard.11 Lebanon, Libya, and Palestine later extended the agreement to eight
         countries.12 Turkey is expected to fully synchronize to the European grid early in 2012,
         which could further advance efforts to synchronize the EIJLLPST electricity network
         with the grids in Turkey and Europe.
        The regional power interconnection of the Gulf Cooperation Council (GCC), which
         allows electricity exchange among its six member states—Kuwait, Saudi Arabia,
         Bahrain, Qatar, the UAE, and Oman—under an agreement signed in 2009. The
         interconnection is targeted at sharing capacity reserve and improving supply reliability,
         which will reduce the need for investment in new generation capacity.

11
   Although the EIJLLPST Interconnection Agreement was signed in the 1980s, physical interconnections between Syria and
Jordan and between Syria and Lebanon were constructed in the 1970s.
12
   According to the Minutes of the Eighteent h Annual Meeting of Medelec, the EIJLLPST interconnection will be renamed
Electrical Interconnection of T hree Continents (EIT C) at the next ministerial meeting.



                                                          12
Though the Maghreb and EIJLLPST interconnections have existed for some time, electricity
trade among the Arab countries has remained at modest levels due to obstacles such as limited
generation reserve margins, the absence of a harmonized regulatory framework with clear rules
governing electricity trade, and institutional weaknesses at both the national and regional level
(that is, governing bodies lack the tools, data, and incentives necessary to promote trade). But the
desire to improve supply security through the diversification of energy supply resources,
particularly in the context of the interregional programs for the development of renewable wind
and solar resources, has boosted motivation to deal with these weaknesses.
1.2      The Context and Purpose of This Study
This study, which focuses on the development of the institutional and regulatory framework for
electricity trade in the Arab world, is one of three currently being carried out by the League of
Arab States (LAS) on the development of regional electricity markets (REMs):
Part I: Study of Interconnections of Electrical Systems in the Arab World.
Part II: Study of Electricity-Gas Trade among the Arab Countries.
Part III: Study of Institutional and Regulatory Frameworks.
The main objective and scope of the three-part study is to establish a strategy and a master plan
for the development of electricity trade among Arab countries. The three parts of the study are
considered complimentary. Part III of the study— which is the subject of this report—is a joint
effort between the LAS and the World Bank.
The World Bank, which is conducting this study jointly with the LAS, has been particularly
active in this area of the world. Under the Arab World Initiative, the World Bank has completed
three studies to assess the potential of energy integration in the three Arab subregions, including
Maghreb, EIJLLPST, and the GCC, while implementing a major regional program for scaling up
concentrated solar power (CSP) in the Middle East and North Africa (MENA) region.
This study focuses on the institutional and regulatory aspects of cross-border trade and electricity
market integration among the 22 Arab the League of Arab States member countries,13 and
between the Arab countries and potential neighboring markets. Consistent with the LAS Terms
of Reference, the study covers six primary areas:
        Analyzing the legal and regulatory framework for the power sectors of the target
         countries, with particular attention to cross-border electricity trade, including
         development of required governance documents such as grid code, power exchange, and
         supply code (market rules)
        Identifying potential obstacles (and auspicious factors) to the creation of an REM and
         developing operational recommendations to surmount these obstacles
        Identifying barriers to efficient energy trading among the concerned countries and
         developing possible workable solutions to facilitate trade and regional integration
        Defining the legal support required for a gradual progression toward a competitive and
         efficient REM
13
  Algeria, Bahrain, Comoros, Djibouti, Egypt, Iraq, Jordan, Kuwait, Lebanon, Libya, Mauritania, Morocco, Oman, Palestine,
Qatar, Saudi Arabia, Somalia, Sudan, Syria, T unisia, the United Arab Emirates (UAE), and Yemen.



                                                           13
          Developing and assessing the general terms under which electricity is to be traded, taking
           into consideration international constraints such as European Union (EU) market trading
           rules, limitations on imports, limitations on long-term price agreements, and
           environmental rules
          Proposing an action plan for the negotiation of the necessary treaties or international
           agreements to promote electricity trade among Arab countries and target markets
This study comprises two phases. Phase 1, contained in this main report (Volume I), examines
regional market structure and design (see table 1.1). Phase 2 (Volume 2) examines principles of
market regulations and legal arrangements including a draft road map for a transition path toward
market integration and governance documentation including drafts Memorandum of
Understanding, General Agreement, General Pan Arab Electricity Market Agreement, and
Regional Grid Code (see table 1.2)
               Table 1.1 Summary of Phase 1 Tasks and Volume I Report Structure
                                                Task                                      Report Location
      1.   Sector and regional overview                                                  Chapter 2
      2.   Current market structure and operation                                        Chapter 2
      3.   Context for regional electricity trade                                        Chapter 3
      4.   Strategic and technical consultation meeting (I)                              N/A
      5.   The “ultimate regional market” parameters                                     Chapter 4
      6.   The “transitional regional market” design                                     Chapter 5
      7.   Strategic and consultation meeting (II)                                       N/A
      8.   Final phase 1 report                                                          N/A
N/A = Not applicable.

               Table 1.2 Summary of Phase 2 Tasks and Volume II Report Structure
                                           Task                                           Report Location
      1. Draft Roadmap for Implementing the Pan-Arab Electricity Market Integration      Section 1
      2. Draft Memorandum of Understanding for Development of the Pan-Arab Electricity   Section 2
         Market
      3. Draft General Agreement                                                         Section 3
      4. Draft General Pan-Arab Electricity Market Agreement                             Section 4
      5. Draft Regional Grid Code                                                        Section 5
1.3        Approach and Organization of the Study and this Report
The study starts by recognizing that the eventual objective of power sector integration is to
optimize the supply of electricity within a broad, regional (rather than confined, national)
framework. Such optimization is possible if every party has equal access to all networks
(domestic, regional, and international), if market data (pricing, market operation, capacity
allocation, and so on) are transparent, tariffs cover the cost of supply, power grid codes are
harmonized, systems are synchronized, and markets liberalized. But the study also recognizes
that Arab countries are at various stages of power sector development, each with its own
characteristics and constraints. Therefore, the cross-border interconnection plans must take
current sector conditions into consideration.
While this study identifies current issues associated with transmission infrastructure and the
synchronization of power networks, it does not attempt to analyze and present solutions to
overcome such constraints. Such issues are the focus of the LAS’s feasibility study (Part I), as
mentioned above.

                                                              14
This study’s approach is to consider Pan-Arab regional electricity market development from the
perspective of building on the three current Arab REMs: Maghreb, EIJLLPST, and the GCC. Six
of the 22 Arab countries—Mauritania, Sudan, Yemen, Somalia, Djibouti, and Comoros—are not
currently interconnected with these regions, and are therefore not addressed in as much detail in
this report. While these countries may at some point become important partners in a Pan-Arab
electricity market, in the absence of electrical interconnection, such prospects appear to be far off
in the future.
This Volume 1 report is organized into six chapters, with this introduction as chapter 1. The
remaining chapters are:
Chapter 2 —Current Market Structure and Organization: Provides an overview of current
regional and national electricity markets, including market structure, institutions, and regulation.
Chapter 3 —Context for Regional Electricity Trade : Develops the context for regional trade,
identifying opportunities as well as the primary obstacles and challenges to the development of a
regional electricity market.
Chapter 4 —Ultimate Regional Electricity Market Design: Develops a proposed ultimate
regional market design as a long-term goal to serve as a guide for market restructuring.
Chapter 5 —Transitional Regional Electricity Market Design: Develops a transitional market
design that takes current constraints and obstacles into account.
Chapter 6 —Next Steps: Considers what may be involved in Phase 2 of the study.
There are a number of terms used throughout the report relating to market restructuring and
reform. These terms often mean different things to different people, so in an attempt to clarify,
we provide our definitions in table 1.3.




                                                 15
                                     Figure 1.1 The Arab electricity network




Source: Arab Union of Electricity.




                                                       16
                        Table 1.3 Definitions of commonly used terms

Market restructuring and reform : The process whereby changes are made in a power sector in
an attempt to provide incentives for improvement in the efficiency of power production,
delivery, and consumption. It often includes the introduction of competition in certain
components of the electricity sector.
Vertically integrated utility : A utility, often state owned, that performs most or all functions of a
power market including generation, system operation, transmission, distribution, and supply.
Unbundling : The separation of the various components of a vertically integrated utility into
smaller groups or companies by function, including generation, system operation, transmission,
distribution, and supply.
Single buyer: The single buyer in an unbundled electricity sector responsible for purchasing all
power from generators and selling that power at the wholesale level to supply companies or
directly to large industrial customers.
Wholesale competition: A system under which customers at the wholesale level, including
supply companies, large industrial customers directly connected to the transmission system, and
traders and brokers, have the right to choose their supplier.
Independent and informed regulation: A regulator that provides oversight of the electricity
sector. An “independent regulator” is able to make decisions in the absence of political
interference. An “informed regulator” has the background, expertise, and skills necessary to
make decisions on behalf of all participants in the power sector.
Economic dispatch: The practice of operating a coordinated power system so that the lowest-
cost generators are used as much as possible to meet demand, with more expensive generators
brought into production as loads increase (and conversely, more expensive generation eliminated
from production as loads fall). The United States Environmental Protection Act’s definition of
economic dispatch is: “the operation of generation facilities to produce energy at the lowest cost
to reliably serve consumers, recognizing any operational limits of generation and transmission
facilities.”
Grid code : A document that includes the technical rules governing connection to, and use of, the
transmission network.
Market rules or commercial code : A document that includes the commercial and financial rules
governing participation in the electricity market.
Open access: All authorized market participants are allowed fair and nondiscriminatory access to
the transmission network under published terms, conditions, and prices.




                                                 17
2         Sector and Regional Overview
This chapter of the report discusses the current regional markets in the Arab world, including its
three existing regional interconnections: the Maghreb; Egypt, Iraq, Jordan, Libya, Lebanon,
Palestine, Syria, and Turkey (EIJLLPST); and the Gulf Cooperation Council (GCC). The chapter
also examines the state of each national market served by the interconnections, with a focus on
the structure, institutions, regulation, and development of electricity markets. The chapter also
includes a brief summary of a number of markets bordering the Arab countries, including
Europe, Turkey, Iran, the Nile Basin Initiative (NBI), and the West African Power Pool (WAPP).
Key energy statistics relating to the 22 Arab countries are provided in table 2.1.
                                     Table 2.1 Arab country key statistics
Country         Population       GDP             Electricity     Peak             Capacity         Electrical      Average
                (millions)       (US$            generation      electricity      reserve          energy sales    electricity
                                 billions)       capacity        demand           margin           (TWh)           tariff (US
                                                 (MW)            (MW)             (%)                              cents/kWh)
EIJLLPST
Egypt            83.0           441.6            24,504           22,079          11              119.4            2.5
Iraq             26.1           105.8            8210             9950            -17             26.9             1.2
Jordan           5.9            31.2             2979             2482            20              12.8             7.1
Syria            21.2           94.2             8025             7873            2               29.7             5.0
Lebanon          4.1            47.9             2312             2499            -7              4.9              6.1
West Bank
                 3.9            4.0              140              810             -83             3.9              14.1
and Gaza
Libya            6.3            102              6006             5759            4               21.1             3.3
GCC
Kuwait           2.7            121.1            12,579           10,970          15              49.3             0.6
Saudi Arabia     25.4           589.5            49,138           45,661          8               211.1            3.3
Bahrain          0.8            21.9             3227             2633            23              11.0             2.6
Qatar            1.7            71.0             7881             5090            55              18.8             2.2
UAE              4.5            226.1            25,252           18,111          39              83.0             9.0
Oman             2.8            56.6             4100             3594            14              11.4             3.6
Maghreb
Algeria          34             276              11,332           7718            47              35.7             4.7
Morocco          31.3           136.9            5596             4550            23              23.3             11.2
T unisia         10.3           82.1             3580             2793            28              12.9             9.5
Others
Mauritania       3.0            6.0              189              86              120             0.6              24.0
Yemen            22.9           26.4             1334             1125            19              4.7              6.8
Sudan            40.3           54.7             2585             1386            36.8            6.0              8.7
Somalia          8.9            0.9              80               72              11              0.3              ---
Djibouti         0.8            1.0              130              63              106             0.3              25.7
Comoros          0.6            0.5              10               ---             ---             0.1              ---
Note: (1) Population and GDP data based on World Bank Statistics for 2009. GDP data is based on purchasing power parity. T he
World Bank had not yet compiled 2010 data at the time the report was submitted.
(2) Data reflect 2010 values supplied by the League of Arab States (LAS).
(3) Reserve margin is based on installed capacity. It may actually be lower depending on generation and fuel availability. In the
case of Sudan, reserve margin based on available capacity.
(4) Unless provided directly by the LAS, average tariff from February 2009 World Bank report entitled, Tapping a Hidden
Resource—Energy Efficiency on the Middle East and North Africa .
GDP = gross domestic product; kWh = kilowatt -hour; T Wh = terawatt -hour; MW = megawatt.

2.1       Maghreb Region
2.1.1 Overview



                                                               18
The Maghreb regional market lies in the northwestern part of the African continent, comprising
Algeria, Morocco, and Tunisia. Work on the Maghreb interconnection began in the 1950s, and
evolved into multiple high-voltage transmission interconnections between the three nations. 14
The Maghreb regional market comprises a mix of resource endowment: Algeria is a major
producer of crude oil and gas and is a net exporter of energy; Morocco is a net importer of
energy; and Tunisia produces small amounts of crude oil and gas and is a net exporter of crude
oil, albeit in small amounts. Although the electricity grids of the Maghreb countries are
connected, power exchange is limited to specific annual contracts.
Key electrical statistics for each of the Maghreb countries are provided in table 2.2.
                         Table 2.2 Key Statistics for Maghreb countries —2010
Country      Peak demand        Installed           Annual sales       Forecast            Average tariff     Electricity
             (MW)               capacity            (TWh)              annual growth       (US cents/         consumption
                                (MW)                                   rate (%),           kWh)               (kWh/capita)
                                                                       2010 – 20
Algeria      7,718              11,332              35.7               6.0                 4.7                1050
Morocco      4,550              5596                23.3               6.0                 11.2               744
T unisia     2,793              3580                12.9               5.7                 9.5                1252
Source: League of Arab States. Growth rates based on various World Bank reports.
Note: kWh = kilowatt -hour; T Wh = terawatt-hour; MW = megawatt.

2.1.2      Demand/Supply Balance
Electricity demand in the Maghreb region has been growing over the past decade at an annual
rate of 5 to 7 percent. This is primarily attributed to a growing population, increased economic
development, and increased electricity access.
Figure 2.1 shows each country’s contribution to Maghreb’s peak demand. Figure 2.2 gives the
appearance that there is enough installed capacity to meet this demand reliably, but in reality, not
all of the installed capacity is available. For example, 20 percent of installed capacity in Morocco
is hydropower, which, owing to water limitations, is not always available.
                     Figure 2.1 Contribution by country to Maghreb peak demand

                                               Tunisia
                                                                         Morocco




                                             Algeria




14
   In February 1989, the Maghreb countries signed a treaty with Mauritania and Libya focusing on economic integration and
establishing the Arab Maghreb Union (AMU), which is closely modeled on the European Union (EU). Currently, Mauritania is
not interconnected with the Maghreb countries, and Libya, although interconnected, is not synchronized, so for the purposes of
this report, they are not considered part of the Maghreb regional market.



                                                             19
          Figure 2.2 Electricity supply and demand in the Maghreb region (MW)
     30000

     25000

     20000
                                                                    Peak Demand
     15000
                                                                    Installed Capacity in 2010
     10000                                                          Additional Capacity Needed

      5000

         0
                      2010                     2020
While the Maghreb region does not currently experience significant outages in electricity supply,
it is forecast that demand growth will continue into the next decade, leading to an 80 percent
increase in peak demand between 2010 and 2020 (see figure 2.2). This growth will require
significant investment in new generation, on the order of an additional 16 gigawatts (GW) by
2020, and this does not include investment necessary to replace retired plants. Additionally,
capacity may need to be increased if renewable energy production is scaled up in the region as
suggested by a number of solar plans. For example, Morocco has announced plans to add 2,000
megawatts (MW) of solar power by 2020. Integrated regional electricity markets (REMs) with
reserve sharing will help to incorporate large-scale renewable energy development and reduce
the amount of capacity needed for backup.
2.1.3 Generation Mix
The generation mix varies by country in the Maghreb region (see figure 2.3), dependent to a
large extent on each country’s natural resources. Given Algeria’s significant gas resources, and
to a lesser extent Tunisia’s, natural-gas-fired generation makes up the majority of the generation
mix in these countries and in the region as a whole. Generally, gas-fired generation has relied on
low-efficiency simple-cycle gas turbines, but combined-cycle generation has recently been
gaining market share, reflecting a heightened awareness of the limited nature of gas resources.
Unlike Algeria and Tunisia, Morocco relies heavily on imported coal, which represents about 52
percent of its generation mix. Hydropower contributes another 20 percent to Morocco’s
generating capacity but only represents 12 percent of its production. Imports from Spain meet
about 20 percent of Morocco’s electricity requirements.




                                               20
                            Figure 2.3 Generation mix in the Maghreb region
      Other
       RES        Morocco                                             Algeria
                                                                      Hydro       Oil
          Hydro
                            Oil
                                         Natural
                                          Gas                           Natural
                Coal                                                     Gas




                   Tunisia                                          Maghreb
                                                    Hydro
                                                                        Other               Oil
                                                             Coal        RES
                         Oil

                  Natural                                                     Natural
                   Gas                                                         Gas




Source: The League of Arab States (LAS) and various World Bank reports.
Note: RES = renewable energy source.
2.1.4 Maghreb Interconnection
As stated above, work on the Maghreb interconnection began in the 1950s and led to several
interconnections between member nations. Meanwhile, the Maghreb countries have committed
to further development. At the Euro-Mediterranean Ministerial meeting in late 2003, the
European Commission and the energy ministers of the Maghreb nations signed a protocol aimed
at developing a REM that would be progressively integrated into the EU electricity market. The
protocol is not legally binding, but rather a declaration of intent, indicating commitment to
reform (see table 2.3). Algeria has clearly committed to the introduction of competition in
generation, distribution, and supply in the gas and electricity market, and to the liberalization of
electricity imports and exports. Morocco is willing to open its market to retail competition over
time by gradually reducing the threshold on the size of customers eligible to select their own
supplier. Tunisia is less aggressive in its commitment. 15 The protocol creates a number of joint
forums and institutions to bring the Maghreb countries together in the formation of an electricity
market. The institutions envisaged are shown in table 2.4.




15
  See ECA report prepared for T he World Bank entitled, Maghreb: Scoping Study —Regional Energy Trade in the Maghreb
Region , dated June 2007.



                                                        21
Table 2.3 Maghreb reform objectives in the 2003 protocol




                          22
Table 2.4 Institutions arising from the 2003 protocol




                         23
The protocol envisages the creation of a number of mechanisms to facilitate trade, including how
to deal with tariffs, transborder networks and constraints, and compensation for network damage.
The Algiers Declaration, signed in 2010, further shows the Maghreb nations’ commitment to
integration. According to this declaration, the nations agree to pursue actions aimed at
harmonizing laws and regulatory frameworks and economic and technical conditions for the
creation of a viable market for electricity in and between the three Maghreb countries and
integration with the EU. Further, the nations agree to work toward creating a genuine Maghreb
electricity market, with network access provided on a nondiscriminatory and transparent basis
and properly priced to promote trade. They also invite the network operators to draft a common
set of rules to facilitate cross-border trade in electricity, and the regulators (or public authorities
who are currently assuming this position) to present a draft common methodology for pricing
and cross-border access to transmission infrastructure for electricity, with reference to the
principles used in the EU. They agree to work together toward the improvement and
harmonization of market rules for electricity, access to the network, and operating systems. The
document emphasizes the importance of developing new and renewable energy, and promoting
energy efficiency and environmental conservation in the integration of electricity markets using a
sustainable development approach. The nations’ electricity ministers agreed to meet in June 2011
to assess progress and provide, where appropriate, necessary guidance.
Currently, exchanges among Maghreb countries are mainly limited to mutual aid, with each
country’s yearly balance close to zero (see table 2.5). The only exception, of course, is
Morocco’s large imports from Spain, representing 20 percent of its power needs.
                      Table 2.5 Power exchanges between Maghreb countries
    Interconnection             Max transfer capacity     Energy exchanged     Load factor
                                (MW)                      (GWh/Year)           (%)
     Algeria– T unisia          150                       141                  11.0
     T unisia– Algeria          150                       122                  9.0
     Morocco – Algeria          400                       613                  17.0
     Algeria– Morocco           400                       662                  19.0
     Morocco – Spain            700                       15                   0.2
     Spain – Morocco            700                       4227                 69.0
Source: T he LAS and various World Bank reports.
Note: Data for 2010 or most recent year available.
MW = megawatt; GWh = gigawatt -hour.

The Maghreb nations have been synchronized with the European Network for Transmission
System Operators– Electricity (ENTSO-E) since 1997 via the 2x400 kilovolt (kV) AC
interconnection between Spain and Morocco. But a number of transmission interconnection
reinforcement projects among the Maghreb countries are planned:




                                                        24
           A 400 kV interconnection between Morocco and Algeria with a thermal limit of 1,200
            MW is planned for operation in 2011.

           A 400 kV interconnection between Algeria and Tunisia with a thermal limit of 1,200
            MW is planned for operation in 2011.

           A 400 kV interconnection between Tunisia and Libya with a thermal limit of 1,200 MW
            is planned for operation in 2012.

Consideration has been given to establishing interconnections between Algeria and Spain,
Algeria and Italy, and Tunisia and Italy (Sicily), the one between Tunisia and Sicily being the
most promising. The plan is to export electricity generated from a new power plant (3x400 MW
gas or 2x660 MW coal) through a 400 kV high-voltage direct current (HVDC) submarine cable
(30 kilometers on land and 195 km undersea at a depth of 600 meters). The capacity of the line
would be 1,000 MW, and commissioning is planned for 2016. About 80 percent of the line
capacity would be allocated to the new power plant, leaving 20 percent for other parties. 16

As part of the Medring initiative, a test of the Libya-Maghreb synchronization in April 2010
failed; future synchronization studies are under way. Mauritania is not interconnected with the
Maghreb countries, but there have been studies of a potential interconnection with Morocco.

2.1.5 National Power Markets in the Maghreb

2.1.5.1 Morocco
Morocco’s power sector includes public and private operators; principle players include the
Office National d’Electricité (ONE), independent power producers (IPPs), and the distributors.
ONE is responsible for managing and operating the country’s transmission grid, its generators,
and part of the distribution network, and it serves about 50 percent of the nation’s customers,
primarily in rural areas. ONE holds power-purchase agreements (PPAs) with private producers.
Morocco has both public and private distribution companies. Private distribution companies are
located in Rabat, Casablanca, Tangiers, and Tetouan.

The activities of the electricity market participants are regulated by various ministries, including
the Ministry of Energy and Mines, the Ministry of Interior, the Ministry of Finance, and the
Ministry of Economic Affairs. Since 1994 (Law Dahir 2-94-502), Morocco has a single-buyer
market model with state-owned ONE purchasing all power generated in Morocco through PPAs
and importing power from Spain and Algeria. A schematic showing the organization of
Morocco’s power sector is provided in figure 2.4.




16
     See Minutes of the Eighteenth Annual Meeting of Medelec —Algiers, September 27 – 29, 2010.



                                                             25
                            Figure 2.4 Organization of Morocco’s power sector




Note: IME: Interconnection Morocco – Europe; IMA: Interconnection Morocco – Algeria.

Morocco needs to make some legal and regulatory adjustments to allow for change. Currently,
there is no independent regulatory authority in Morocco. Neither is there a published
transmission tariff for establishing access to the transmission system. But the nation is currently
undertaking a study on power sector reform that would include the creation of a free market to
operate in parallel with the regulated market, and a consultant has been hired to define the
parameters of a new regulatory authority. The Government of Morocco supports renewable
energy and energy efficiency through a number of laws that are met through several programs
with objectives relating to energy security and low-carbon energy developments.

Morocco’s retail tariffs are less than the economic cost of supply. The World Bank has reported
that residential customers in Morocco consuming 700 kilowatt-hour (kWh) per month pay only
63 percent of a benchmark tariff based on an average of the tariffs of France, Greece, Italy,
Spain, Portugal, and Turkey. 17

Morocco’s electricity sector is summarized as follows:

         Reform: Limited, but under study.

         Market structure : Single buyer with some unbundling.

         Separate regulator 18: No.

         Open access: No.

         Grid code/distribution code : No/no.

         Private-sector participation: Yes, in generation and distribution.

17
   See February 2009 World Bank report entitled, Tapping a Hidden Resource —Energy Efficiency on the Middle East and North
Africa .
18
   A separate regulator means that an entity exists with sole responsibility for regulating the electricity sector. T he regulator m ay
or may not be independent in the sense that it is free to set tariffs in the absence of political interference.



                                                                 26
      Tariffs: Subsidized.

2.1.5.2 Algeria
Liberalization of Algeria’s power sector started with the approval of Law no. 02 -01 on February
5, 2002. The law includes provisions for unbundling the former vertically integrated utility,
SONELGAZ; the roles and responsibilities for each market participant; and the market model,
including the creation of a power exchange. SONELGAZ has since been restructured as a
holding company. The primary companies within the holding company are shown in table 2.6.

                 Table 2.6 Companies within SONELGAZ holding company

   Sector        Initials   Name
   Generation    SPE        Société Algérienne de production de l'électricité
                 GRTE       Société Algérienne de Gestion du Réseau de Transport de l'Electricite
   Transmission OS          Operateur Systeme Electrique
                 SDA        Société de Distribution de l'Electricite et du Gaz d'Alger
                 SDC        Société de Distribution de l'Electricite et du Gaz du Centre
                 SDE        Société de Distribution de l'Electricite et du Gaz de l'Est
    Distribution SDO        Société de Distribution de l'Electricite et du Gaz de l'Ouest

Algeria has implemented a single-buyer market model with SONELGAZ/OS as the independent
system operator (ISO) responsible for transmission grid planning and operation. The
transmission assets are owned by SONELGAZ/GRTE. Four IPPs with significant international
ownership also participate in the Algerian power market. There are four distribution companies
with franchises covering the various geographic areas across the country.

Law 02-01 created a regulatory authority known as CREG which contributed significantly to the
adoption of legislation, including on tariffs on the power sector’s regulated activities. The law
also envisions a market operator, but it has not yet been implemented. Procedures for the
operation of the power exchange also have yet to be implemented, though they were defined in
2008.

The government has been increasingly emphasizing efficiency and renewable energy. The
current share of renewable energy sources (RESs) is not significant in the total energy balance,
but an ambitious development program was established under a 2004 law that includes
incentives for RES use and created a support fund and a renewable energy institute known as the
IAER. Algeria currently envisages the development of 2,570 MW of renewable generation by
2020, including 1,500 MW of CSP; 800 MW of photovoltaics (PV); and 270 MW of wind
power. By 2030 it is envisaged that 12,000 MW of renewable generation will be developed,
including 7,200 MW of concentrated solar power; 2,800 MW of photovoltaics; and 2,000 MW of
wind.




                                                   27
Retail electricity tariffs in Algeria are well below the economic cost of supply. The World Bank
reports that residential customers in Algeria consuming 700 kWh per month pay only 31 percent
of a benchmark tariff based on an average of the tariffs of France, Greece, Italy, Spain, Portugal,
and Turkey.19

Algeria’s electricity sector is summarized as follows:

        Reform: Under way with new law passed.

        Market structure : Single buyer with unbundling.

        Separate regulator: Yes.

        Open access: No.

        Grid code/distribution code : Yes/yes.

        Private sector participation: Yes, in generation and distribution.

        Tariffs: Subsidized.

2.1.5.3 Tunisia
Until 2002 Tunisia’s sole supplier of electricity generation, transmission, and distribution was
Société Tunisienne de l’Electricité et du Gaz (STEG), a state-owned, vertically integrated
monopoly. The Tunisian government terminated STEG’s monopoly over power generation in
1996 to encourage private power generation (April 1, 1996, Decree no. 96-27). The first IPP in
Tunisia was the 471 MW combined-cycle plant at Rades (Rades II), which commenced operation
in 2002. The second IPP followed shortly thereafter, commencing operation in 2004. STEG
continues to maintain control over distribution, but the Tunisian government is seeking to
encourage further private investment in power generation. STEG and the two IPPs are the main
participants in Tunisia’s power sector today. The organization of Tunisia’s energy sector is
shown in figure 2.5.




19
  See February 2009 World Bank report entitled, Tapping a Hidden Resource —Energy Efficiency on the Middle East and North
Africa .



                                                           28
                          Figure 2.5 Organization of Tunisia’s Energy Sector




In February 2009, a new law (no. 2009-7) was promulgated requiring STEG to purchase the
surplus power generated by self-producers from RES and to lease its transmission system to
transport the surplus from one establishment to another within the same group. The law also
allowed companies to equip themselves with cogeneration equipment for their own consumption.
Nonetheless, Tunisia’s power sector remains vertically integrated (STEG) without independent
regulation.

Tunisia has been a pioneer among developing countries in terms of its energy management
policy, having formulated and implemented a policy for the rational use of energy and the
promotion of RESs as early as 1985. The 11th Development Plan (2007– 11) sets the broad
direction of energy policy, including the gradual reduction of energy subsidies, and calls for a
scaling up of investment in renewable energy and energy efficiency. The Tunisian Solar Plan
was launched in 2009 for the period 2010– 16. It aims at increasing the share of RESs and energy
efficiency.

Retail tariffs in Tunisia are below the economic cost of supply. The World Bank reports that
residential customers in Tunisia consuming 700 kWh per month pay only 61 percent of a
benchmark tariff based on an average of the tariffs of France, Greece, Italy, Spain, Portugal, and
Turkey.20

Tunisia’s electricity sector is summarized as follows:

        Reform: Limited.

        Market structure : Vertically integrated.

        Separate regulator : No.

        Open access: No.


20
  See February 2009 World Bank report entitled, Tapping a Hidden Resource —Energy Efficiency on the Middle East and North
Africa .



                                                           29
         Grid code/distribution code : No/No.

         Private sector participation: Yes, in generation.

         Tariffs: Subsidized.

2.2       EIJLLPST Region

2.2.1 Overview
The EIJLLPST regional market lies along the eastern half of the Middle East and North Africa
(MENA) region. It includes Egypt, Iraq, Jordan, Libya, Lebanon, Palestine, and Syria. The
EIJLLPST countries have signed a comprehensive interconnection agreement, and numerous
regional projects and initiatives are under way to enhance cooperation and development within
the EIJLLPST as well as across the region.

Electricity demand has been on the rise in the EIJLLPST region over the past few years, with
peak demand increasing from 19,040 MW in 1990 to 51,452 MW in 2010—a 170 percent
increase. Peak demand is expected to increase more than 4 percent annually until 2030.

The EIJLLPST region is endowed with significant gas resources, which are predominantly
concentrated in Egypt, Libya, and Iraq. Because gas is central to electricity generation in the
EIJLLPST region, future capacity constraints could create issues.

Key statistics for the EIJLLPST countries are provided in table 2.7.

                           Table 2.7 Key statistics for EIJLLPST countries, 2010
Country          Peak demand          Installed      Annual sales        Forecast          Average tariff    Electricity
                    (MW)              capacity         (TWh)           annual growth        (US cents/      consumption
                                        (MW)                             rate (%),            kWh)          (kWh/capita)
                                                                         2010 – 20
Egypt                22,079            24,504             119.4               6.6                 2.5           1,439
Iraq                  9,950             8,210              26.9               3.3                 1.2           1,031
Jordan                2,482             2,979              12.9               6.0                 7.1           2,169
Syria                 7,873             8,025              29.7               3.8                 5.0           1,401
Lebanon               2,499             2,312               4.9               2.4                 6.1           1,195
Libya                 5,759             6,006              21.1               5.4                 3.3           3,349
West Bank and           810               140               3.9               6.0                14.1           1,000
Gaza
Source: T he League of Arab States. Demand growth rates from various World Bank reports.
Note: kWh = kilowatt -hour; T Wh = terawatt -hour; MW = megawatt.

2.2.2 Demand/Supply Balance
Sustained high economic growth in the EIJLLPST countries has triggered a rapid increase in
energy demand. From 2010 through 2020, peak demand is forecast to increase by more than
36,000 MW, representing an average annual growth rate of 5.5 percent. Each country’s
contribution to the EIJLLPST peak demand is shown in figure 2.6.
Although part of this demand may be curbed through more effective energy conservation
policies and technologies, there is a clear need to expand generating capacity in all countries in

                                                            30
the region. Indeed, most countries have been facing power disruptions, which impose a heavy
burden on economic activities. To ensure reliable electricity supply, each country would need to
maintain reserve margins (that is, the difference between installed generating capacity and peak
demand) on the order of 10 to 15 percent. The reserve margin in the EIJLLPST countries
declined from 55 percent in 1990 to -1 percent in 2010,21 resulting in frequent power outages.
                     Figure 2.6 Contribution by country to EIJLLPST peak demand

                           Palestine
                                                      Syria
                             Lebanon
                                                                                  Egypt
                                      Libya



                                                          Iraq
                                Jordan




Figure 2.7 shows the supply-demand situation in the EIJLLPST countries, illustrating that at
least 44,000 MW of new capacity will be needed by 2020. But the EIJLLPST countries have
struggled thus far to bring new generating capacity online. Iraq, Syria, and Lebanon have all
experienced significant electricity outages in recent years. Jordan and Syria have recently added
new generation capacity, but challenges remain. Egypt’s current supply capacity is meeting
demand with adequate levels of reliability, but the level of unsupplied energy has been
increasing. All EIJLLPST countries must continue to aggressively expand generation capacity if
they are to meet high levels of demand growth in the future.
                            Figure 2.7 EIJLLPST demand/supply situation (MW)
         100000
          90000
          80000
          70000
          60000                                                                            Peak Demand
          50000
                                                                                           Installed Capacity in 2010
          40000
          30000                                                                            Additional Capacity Needed
          20000
          10000
              0
                                 2010                            2020

2.2.3        Generation Mix

21
     T he reserve figures for both 1990 and 2010 are somewhat overstated as available generation was likely lower.



                                                                 31
One of the significant bottlenecks in developing new generating capacity in the EIJLLPST
region is the supply of fuel. The region depended in the past on oil for power generation. This
dependence was substantially reduced as gas became a desirable substitute owing to its economic
and environmental attributes. But in recent years gas availability has turned into a serious issue,
as countries such as Syria and Jordan have realized that their domestic gas production and
existing contracts for gas imports are not sufficient to meet their generating needs. This has
triggered a search for sources of imported gas or electricity.
The generation fuel mix for the EIJLLPST region is shown in figure 2.8. Oil and gas generation
are split about evenly, at 47 percent, with hydropower accounting for the remaining 6 percent.
The specific ratio of fuels varies by country; Egypt and Jordan rely primarily on natural gas and
the remaining countries rely primarily on oil.
                   Figure 2.8 Generation fuel mix in the EIJLLPST region

          Other
  Hydro    RES    Egypt                                           Iraq
                                                          Hydro

                          Oil

              Natural
               Gas


                                                                          Oil


                  Jordan                                          Libya
                           Oil
                                                Natural
                                                 Gas
              Natural                                                           Oil
               Gas




              Lebanon                                             Syria
                  Hydro                                       Hydro

                                               Natural
                                                Gas
                                                                                Oil
                        Oil




                                                32
                  Palestine                                                 EIJLLPST
                                                                             Hydro

                                                                                            Oil
                                                                          Natural
                          Oil                                              Gas




Source: T he LAS and various World Bank reports.
Note: RES = renewable energy sources.

2.2.4 EIJLLPST Interconnection
The EIJLLPST interconnection was initiated in 1988 by a five-country agreement between
Egypt, Iraq, Jordan, Syria, and Turkey, and has since grown to include Libya, Lebanon, and
Palestine. Through the agreement, each country committed to upgrading its electricity system to
a minimum standard.
In October 1992 the original five countries signed a general trading agreement22 documenting
their commitment to cooperate fully on interconnection, to provide mutual assistance and share
benefits, to improve the reliability of supply, and to improve the region’s economies through the
exchange of surplus power. This agreement was followed up in 1996 with a comprehensive
agreement23 outlining the terms and conditions for use of the interconnection, including:
        Reserve sharing during emergencies
        Capacity transactions
        Interchange of surplus power and energy
        Regulation of energy flows to maintain schedules
        Regulation of reactive power flows
        Transmission services, making available each country’s transmission facilities for the
         purpose of transmitting power and energy to other parties
        Operating reserves, including the maintenance of minimum levels of reserves and their
         sharing between countries
        Coordination of maintenance schedules
        Coordination of planning so as to increase reliability and maximize the value of the
         interconnection




22
   See General T rading Agreement for the Electrical Interconnection among the Five Countries (EIJST ).
23
   See General Interconnection Agreement for the Electrical Interconnection among the Five Electrical Power Utilities of Egypt,
Iraq, Jordan, Syria, and T urkey (EIJST ) dated November 1996.



                                                             33
The interconnection agreement also set out the scope and duties for permanent committees
including a Steering Committee, a Planning Committee, and an Operating Committee. The
committees meet regularly and their decisions must be unanimous.
       Steering committee . Includes one member from each country. Responsible for
        coordinating design, planning, and operating activities to promote the reliable and
        efficient operation of the interconnection and the interconnected power systems.
       Planning committee. Includes two members from each country. Each country determines
        the capacity and energy requirements for a 10-year planning period identifying
        significant generation and transmission additions. The Planning Committee meets once
        per year to analyze the plans to ensure coordination among the countries and determine if
        the plans conform to Steering Committee rules and guidelines.
       Operating Committee. Each pair of neighboring countries is required to maintain a
        bilateral operating committee. The operating committees are required to take all actions
        necessary to ensure delivery and payment for power in accordance with the
        interconnection agreement and any agreement between the countries.
Despite the interconnection agreement, trade among the EIJLLPST countries has been modest.
The committees do not appear to be fully functional. Primary obstacles to electricity trade are
tight generation supply, lack of a harmonized regulatory framework, limited access to national
transmission networks, and the fact that trade is generally limited to a single government-owned
entity in each country. Additionally, the interconnected systems are often not synchronized,
meaning that part of a national grid system may have to be isolated from the main grid to accept
imports from another country. Additionally, the lack of surplus generating capacity and
generation fuel in the interconnected countries means they often do not have spare energy to
trade. Further, in some areas the transmission system is not synchronized, necessitating isolated
generation to facilitate trade. For example, when Syria exports energy to Lebanon, part of the
Lebanese grid must be disconnected from the main national grid. Power exchanges among the
EIJLLPST counties are shown in table 2.8.
                      Table 2.8 Power exchanges among EIJLLPST countries
                                   Max transfer capacity     Energy exchanged
                                   (MW)                      (GWh/year)         Load factor (%)
             Syria– Jordan         200                       20                 1
             Jordan – Syria        350                       69                 2
             Syria– Lebanon        50                        144                33
             Lebanon – Syria       160                       419                30
             Jordan – West Bank    20                        158                90
             Egypt – Gaza          17                        134                90
             T urkey – Syria       250                       97                 4
             Libya– Egypt          180                       152                10
             Egypt – Libya         180                       70                 4
             Jordan – Egypt        200                       9                  1
             Egypt – Jordan        450                       363                9
             Egypt – Syria                                   140
             Syria– Egypt                                    5
             Egypt – Lebanon                                 527
Note: GWh = gigawatt-hour; MW = megawatt.



                                                           34
Regardless, the EIJLLPST interconnection has brought significant benefits. For example, Jordan
can rely on its interconnections with Egypt and Syria for about 250 MW of capacity during
system emergencies. In 2007 Jordan’s reserve margin was negative 130 MW. In the absence of
its interconnections, Jordan’s loss -of-load expectation was 53 hours, more than triple the target
level of 15 hours. The interconnections therefore enabled Jordan to avoid considerable load
shedding in 2007. In addition, Jordan, Egypt, and Syria share spinning reserves. By minimizing
spinning reserve requirements in this manner, generation is operated closer to its optimum output
level, thus improving efficiency and reducing fuel and maintenance costs. Opportunities for
short-term trades have also been realized through the diversity of demand. Syria has a winter
peak while Egypt and Jordan have summer peaks. Syria can make sales to Egypt and Jordan
during summer when it has surplus generating capacity, and Jordan and Egypt can make sales to
Syria in winter when they have surplus generating capacity. These staggered sales are
particularly relevant when there are different generation technologies in the countries.
Overall, the value of the EIJLLPST interconnection is currently suboptimal. It is used primarily
for ancillary services such as reserve sharing, while energy transactions to take advantage of
differences in production costs are limited.
2.2.5 EIJLLPST’s National Power Markets
2.2.5.1 Egypt
In Egypt the Ministry of Electricity and Energy is responsible for the electricity sector, including
policy formation and the implementation of government decrees. The Egyptian Electricity Utility
and Consumer Protection Regulatory Agency has regulatory oversight responsibility for the
electricity sector. The agency’s role is to optimize the technical, operational, financial, and
procedural systems of the electricity business. But it does not have responsibility for tariffs; these
remain the responsibility of government. The structure of the electricity sector is shown in figure
2.9.




                                                 35
                           Figure 2.9 Structure of Egypt’s electricity sector




Reporting to the Ministry of Electricity and            Energy are a number of executive authorities with
responsibility for specific components of               the electricity sector. These authorities are the
Hydropower Projects Executive Authority,                 New and Renewable Energy Authority,24 Rural
Electrification Authority, Nuclear Materials            Authority, Atomic Energy Authority, and Nuclear
Power Plants Authority.
The Egyptian Electricity Holding Company (EEHC) and its affiliates are responsible for the day-
to-day operation of the electricity industry including generation, transmission, and distribution.
In the generation sector, there are six government-owned companies, three private build-own-
operate-transfer (BOOT) companies, and six IPPs. The government-owned generating
companies include hydropower plants, RES plants, and four companies divided by geographic
area, including Cairo, East Delta, West Delta, and Upper Egypt. The state-owned Electricity
Transmission Company carries out all transmission activities and acts as the single buyer of all
generation. The transmission company, in turn, sells all power to the nine state-owned regional
distribution companies. Therefore, Egypt has a single-buyer market model with elements of a
monopoly model under the EEHC. A schematic of EEHC and its affiliates is shown in figure
2.10.




24
   T he New and Renewable Energy Authority acts as the national focal point for expanding development of renewable energy
technologies in Egypt on a commercial scale.



                                                           36
                    Figure 2.10 Organization of Egypt’s electric utilities




Egypt’s retail electricity prices are far below levels reflecting the economic cost of supply. The
World Bank reports that a residential customer in Egypt consuming 700 kWh per month pays
only 17 percent of a benchmark tariff based on an average of the tariffs of France, Greece, Italy,




                                               37
Spain, Portugal, and Turkey. Egypt’s retail tariff for its industrial customers is likewise far below
the European benchmark. 25
Egypt’s electricity sector is summarized as follows:
        Reform: Limited.
        Market structure : Vertically integrated under the EEHC.
        Separate regulator : Yes, but without responsibility for tariffs.
        Open access: No.
        Grid code/distribution code : No/no.
        Private sector participation: Yes, in generation.
        Tariffs: Subsidized.
2.2.5.2 Iraq
In Iraq the Ministry of Electricity is responsible for generating, transmitting, and distributing
electrical energy. The ministry has three departments that report to the minister: the Electric
Energy Production Office, the Electric Energy Transmission Office, and the Electric Energy
Distribution Office. Each office has a number of directors-general who cover various geographic
areas of the country. The organization of the ministry is shown in figure 2.11.

                               Figure 2.11 Iraq’s energy sector structure




                                                       Ministry of
                                                       Electricity




                   Electric Energy                    Electric Energy                   Electric Energy
                  Production Office                    Transmission                      Distribution
                                                           Office                           Office




25
  See February 2009 World Bank report entitled, Tapping a Hidden Resource —Energy Efficiency on the Middle East and North
Africa .



                                                           38
Despite the separate divisions for generation, transmission, and distribution under the ministry,
the electricity sector acts as a vertically integrated monopoly without the benefit of independent
regulation. The Ministry of Electricity is responsible for policy development, regulatory
oversight, and planning for the sector.
Retail electricity tariffs are heavily subsidized and woefully inadequate to generate the revenues
necessary to expand the power sector. The World Bank reports that Iraq’s retail electricity price
for a residential customer consuming 700 kWh per month is less than 1 percent of a benchmark
tariff based on an average of the tariffs of France, Greece, Italy, Portugal, Spain, and Turkey. 26
The country’s retail tariff for industrial customers likewise is far below the European benchmark.
Iraq’s electricity sector is summarized as follows:
        Reform: None.
        Market structure : Vertically integrated.
        Separate regulator : No.
        Open access: No.
        Grid code/distribution code : No/no.
        Private sector participation: No.
        Tariffs: Subsidized.
2.2.5.3 Jordan
In 1999 Jordan’s National Electric Power Company (NEPCO) was unbundled into three
operating companies: the Central Electricity Generating Company (CEGCO), Electricity
Distribution Company (EDC), and NEPCO, which retained responsibility for transmission.
In 2001 the Electricity Regulatory Commission (ERC) was formed to regulate the electricity
sector. The ERC is responsible for setting tariffs and issuing licenses for activities in the sector.
The commission monitors and ensures that entities operate consistently with the obligations
documented in their licenses. The ERC exists to ensure that tariffs enable power companies to
finance operations and earn a fair return on investment.
Jordan currently has a single-buyer market structure, but the law allows progression to a
competitive market. The ERC suggests the timetable for the introduction of competition through
annual reports issued to the minister. The competitive market, once introduced, would feature
bilateral contracts at the wholesale level, similar to that in Europe.
The state-owned NEPCO performs the role of a single buyer, purchasing all supply from
generators and, and in turn, selling all purchased power to the distribution companies and large
consumers directly connected to the transmission system. The NEPCO is also responsible for
transmission asset management, dispatch, demand forecasting, and purchasing natural gas to
meet the needs of the power generation companies.



26
  See February 2009 World Bank report entitled, Tapping a Hidden Resource —Energy Efficiency on the Middle East and North
Africa .



                                                           39
The CEGCO is the primary generation company in Jordan. The company was privatized in 2007
and is currently 51 percent privately owned. It generated 8,009 gigawatt-hours (GWh) in 2009,
which accounted for 56 percent of the country’s total in 2009. Jordan has a second private power
generation company, AES PCS Jordan, which accounted for 16 percent of production in 2009, as
well as a state-owned generation company known as Samra, which accounted for 25 percent of
Jordan’s electricity production in the same year. A number of industrial complexes, a small
hydropower project, and a biogas facility accounted for the remaining 3 percent of production.
Jordan has three private distribution companies: the Jordan Electric Power Company (JEPCO),
the Electricity Distribution Company (EDCO), and the IRBID District Electricity Distribution
Company. The private sector is mainly responsible for generation and distribution, while the
public sector is responsible for transmission and dispatch, with some limited involvement in
generation. The organization of Jordan’s power sector is shown in figure 2.12.

                   Figure 2.12 Organization of Jordan’s electricity sector




The World Bank reports that a residential customer in Jordan consuming 700 kWh per month
pays only about 50 percent of a benchmark tariff based on an average of the tariffs of France,




                                              40
Greece, Italy, Portugal, Spain, and Turkey. 27 Jordan’s retail tariff for its industrial customers is
likewise well below the European benchmark. But Jordan’s retail electricity prices reflect the
cost of electricity supply in the country. Jordan has done an excellent job of expanding its
electricity supply, relying on low-cost gas imports and reserve-sharing arrangements with Egypt
and Syria over its interconnections. Cost-reflective tariffs have enabled Jordan to launch a
successful IPP program aided by the elimination of all primary fuel subsidies in 2008.
Jordan’s electricity sector is summarized as follows:
        Reform: In advanced stage.
        Market structure : Single buyer with unbundling.
        Separate regulator : Yes.
        Open access: No.
        Grid code/distribution code : Yes/yes.
        Private sector participation: Yes, in generation and distribution.
        Tariffs: Reflect cost of supply.
2.2.5.4 Libya
The General Electricity Company of Libya (GECOL) is a vertically integrated monopoly with
control and ownership over all electricity generation, transmission, and distribution in Libya. The
GECOL reports to the General Peoples Committee for Electricity, Water and Gas, which is
responsible for policy, planning, and regulation of Libya’s electricity sector. Therefore, Libya’s
power sector does not have an independent regulatory authority.
In 2010 Libya’s peak electricity demand was 5,759 MW, and it had an installed generating
capacity of 6,006 MW. About 60 percent of generation fuel requirements were met with oil
products and the other 40 percent met with natural gas. Demand has been growing rapidly and is
forecast to continue doing so in the future at growth rates of about 5.5 percent through 2020.
Generation additions have struggled to keep pace with demand, and Libya has responded with an
aggressive generation and transmission expansion plan. Libya plans to add 13,000 MW of
generating capacity by 2020. About 4,600 MW are already under construction and 2,400 of new
generation capacity has been awarded contracts. New generating capacity will be a mix of
cogeneration, combined-cycle, and steam plants relying heavily on natural gas as the fuel. Libya
also has numerous transmission projects planned to transmit the new generation to areas of the
country with rapidly increasing demand. The transmission plans include a number of studies for
expanding international interconnections as discussed earlier in the report.
Currently, the primary objective for the power sector is to ensure the secure and adequate supply
of power to all areas of the country. Libya has a goal to improve service quality and efficiency,
reduce technical and nontechnical losses, and reinforce interconnections with neighboring
countries.


27
  See February 2009 World Bank report entitled, Tapping a Hidden Resource —Energy Efficiency on the Middle East and North
Africa .



                                                           41
Libya does not have independent regulation of its power sector, and not surprisingly, its retail
electricity prices are heavily subsidized. The World Bank reports that residential customers in
Libya consuming 700 kWh per month pay only 10 percent of a benchmark tariff based on an
average of the tariffs of France, Greece, Italy, Spain, Portugal, and Turkey. 28 Heavily subsidized
retail tariffs will pose a significant challe nge to Libya’s aggressive expansion plans.
Libya’s electricity sector is summarized as follows:
        Reform: None.
        Market structure : Vertically integrated.
        Separate regulator : No.
        Open access: No.
        Grid code/distribution code : No/no.
        Private sector participation: No.
        Tariffs: Subsidized.
2.2.5.5 Syria
Syria’s electricity sector is managed and regulated by the Ministry of Electricity, while the
Public Establishment for Electricity Generation and Transmission (PEEGT) plans, develops,
operates, and maintains the generation and transmission components of the electricity sector, and
the Public Establishment for Distribution and Exploitation of Electric Energy (PEDEEE) and its
14 regional subsidiaries are responsible for the power distribution network. Figure 2.13 shows
the organization of Syria’s electricity sector.
                         Figure 2.13 Organization of Syria’s electricity sector

                                                Ministry of Electricity
         Electromechanical                                                            Public Establishment for
       Intermediate Institutes                                                            Communication




                                                     National Energy
                  PEEGT                              Research Center                            PEDEE

The Ministry of Electricity is responsible for both policy and regulation. Although distribution is
separate from generation and transmission, the electricity sector operates as a vertically
integrated, monopolistic structure without competition or independent regulation.
In the summer of 2007, Damascus experienced daily power interruptions lasting as long as five
hours. In response, Syria’s governme nt has indicated that addressing electricity supply shortages
is a top priority. A November 15, 2010, decree mandates that the electricity sector be unbundled

28
  See February 2009 World Bank report entitled, Tapping a Hidden Resource —Energy Efficiency on the Middle East and North
Africa .



                                                           42
into three institutions for generation, transmission, and distribution; the private sector will be
allowed to invest in generation and distribution in partnership with the government, but
privatization of existing assets does not appear likely. 29
Syria’s retail electricity prices are far below the economic cost of supply. The World Bank
reports30 that Syria’s retail electricity prices for a residential customer consuming 700 kWh per
month are only 10 percent of a benchmark tariff based on an average of the tariffs of France,
Greece, Italy, Portugal, Spain, and Turkey. Its retail tariff for industrial customers is likewise far
below the European benchmark.
Syria’s electricity sector is summarized as follows:
        Reform: Limited, but new law recently passed.
        Market structure : Vertically integrated, but some unbundling could be implemented
         following the passage of a new law.
        Separate regulator : No.
        Open access: No.
        Grid code/distribution code : In development/no.
        Private sector participation: No, but IPP generation projects (fuel and wind) are being
         tendered now, and the new electricity law allows private participation in generation and
         distribution.
        Tariffs: Subsidized.
2.2.5.6 Lebanon
Lebanon’s Ministry of Energy and Water (MEW) directs the country’s energy policy, while
Electricité du Liban (EDL) is a state-owned, vertically integrated utility with a monopoly over
generation, transmission, and distribution of electricity. EDL incurs significant financial losses
owing to high primary fuel costs and low retail tariffs. As a result, the utility receives significant
subsidies from the government via the Ministry of Finance. Lebanon does not have independent
regulation. Figure 2.14 shows the country’s energy sector structure.




29
   See November 15, 2010, announcement entitled, “President al -Assad Issues Decree No. 32 Regulating Electricity Sector Policy
in Syria.”
30
   See February 2009 World Bank report entitled, Tapping a Hidden Resource —Energy Efficiency in the Middle East and North
Africa .



                                                             43
                           Figure 2.14 Structure of Lebanon’s energy sector




Source: Ministry of Energy and Water.

Lebanon’s retail electricity prices are far below the levels necessary to recover the cost of supply.
The World Bank reports that Lebanon’s retail electricity tariff for a residential customer
consuming 700 kWh per month is only 31 percent of the benchmark tariff based on an average of
the tariffs of France, Greece, Italy, Portugal, Spain, and Turkey. 31 The retail tariff for Lebanon’s
industrial customers is also far below the European benchmark. The financial impact of
Lebanon’s retail tariffs is particularly dismal when one considers that the country’s cost to
supply electricity is well above industry norms.
Lebanon’s electricity sector is summarized as follows:
        Reform: None.
        Market structure : Vertically integrated.
        Separate regulator : No.
        Open access: No.
        Grid code/distribution code : No/no.
31
  See February 2009 World Bank report entitled, Tapping a Hidden Resource —Energy Efficiency in the Middle East and North
Africa .



                                                           44
        Private sector participation: None.
        Tariffs: Subsidized.
2.2.5.7 Palestine
The Palestinian Energy and Natural Resources Authority (PEA) oversees the development of the
Palestinian energy sector development in West Bank and Gaza. It has wide-ranging powers over
the policy, coordination, and development of the energy sector. The PEA is responsible for
consolidating power supply and distribution arrangements in the West Bank into four electricity
distribution utilities. It has created three utilities for the West Bank: the Northern Electric
Distribution Company (NEDCO), Hebron Electric Power Company (HEPCO), and Southern
Electric Power Company (SELCO). Additionally, the long-established Jerusalem District
Electric Company (JDECO) serves the central area around Jerusalem, and the Gaza Electricity
Distribution Company (GEDCO) is responsible for electricity transmission and distribution in
Gaza.
The Palestinian Authority encourages private sector investment in the energy sector. The law
requires that new generation capacity be developed by the private sector, and also allows private
shareholders of the public distribution companies. The PEA has established an internal Energy
and Environment Research Center in charge of preparing studies and conducting research on
RES in cooperation with Palestinian universities.
The electricity supply to West Bank and Gaza depends almost entirely on the Israel Electric
Corporation (IEC) for electricity supply. The West Bank is also served through a 2 x 33 kV
interconnection with Jordan (about 30 km in length), which supplies up to 20 MW, but the
electricity can be supplied only on an isolated-grid basis to Jericho. The Gaza IPP power plant, a
2 x 70 MW combined-cycle plant burning diesel fuel, supplements Gaza’s power supply. Since
2006 Gaza has also received up to 17 MW from Egypt on an emergency basis over a 1 x 22 kV
line to Rafah that is operated in an islanded mode
Retail electricity prices in West Bank are close to collecting the full economic cost of supply.
The World Bank reports that the retail electricity tariff for a residential customer in West Bank
and Gaza consuming 700 kWh per month is 86 percent of the benchmark tariff, based on an
average of the tariffs of France, Greece, Italy, Portugal, Spain, and Turkey. 32 The Palestinian
industrial tariff is about 65 percent of the European benchmark.
A new law passed in May 2009 set the policy and framework for developing the Palestinian
electricity sector included in this was the establishment of a new regulatory commission, a
transmission company, and distribution companies to which electricity services will be
transferred from the municipalities and villages. Figure 2.15 shows the structure of the electricity
sector as envisaged by the law.
The Palestinian electricity sector is summarized as follows:
        Reform: Under way with passage of new law.
        Market structure : Unbundled into regional distribution companies.

32
  See February 2009 World Bank report entitled, Tapping a Hidden Resource—Energy Efficiency in the Middle East and North
Africa .



                                                          45
   Separate regulator : Yes.
   Open access: No.
   Grid code/distribution code : No/no.
   Private sector participation: Yes, in generation and part of distribution.
   Tariffs: Reflect cost of supply.




                                             46
                         Figure 2.15 Structure of Palestinian electricity sector as required by the electricity law

                                                                  T h e P E A
           Setting the Policies and general regulations related to developing the Power Sector, licensing and concluding agreements for
           power generation, concluding agreements concerning interconnections with the neighboring countries, issuing conditions and
           regulations on public safety, issuing necessary environmental conditions implementation requirements, licensing power
           distribution and sales, and setting the power tariffs approved by the Cabinet


                                                                                       Electric Power
                                           Power Distribution                          Transmission
                                             to Consumers                                                                RE Power Plant
                                                                                    • Power Transmission
                                                    Gaza Governorates                 from power plants
              Customers                              Distribution Co.                 into distribution                      Egypt
              supplied by                                                             utilities and
              up to 36 kV                                JEDCo                        consumers supplied                    Jordan
                                                                                      by over 36 kV
                                                        NEPCo                       • Power importation                 North West Bank
                                                                                      and exportation                     Power Plant

                                                 South West Bank (Hebron              trough Electric
              Customers                              Governorate) Co.
                                                                                      Interconnection                  Gaza Power Plant
              supplied by
              over 36 kV                                                                                                      IEC




                                           E l    e c t r ic    P o w e r      R e g u l a t o r y   C o u n c il
           Monitoring the application of agreements concerning generation, transmission, and Selling and distribution, reporting to
           the PEA to set the tariffs, recommend the acceptance or refusal of licensing, renewal of license, withdrawal of license, and
           forfeiting it. In addition to quality control of services provided to customers by distribution companies


Source: Draft Energy Sector by the Palestinian Energy and Natural Resources Authority (PEA).


                                                                                  47
2.3         GCC Region
2.3.1 Overview
The GCC regional market was established in May 1981 by a cooperation agreement between
Bahrain, Kuwait, Oman, Qatar, Saudi Arabia, and the UAE. 33 The GCC states account for 40
percent of the world’s crude oil reserves and 25 percent of its gas reserves. Electricity and ene rgy
demand is projected to increase by 6.8 percent annually in the region, requiring substantial
investment in energy infrastructure. The GCC states have made significant progress integrating
their electricity networks to facilitate cross-border trade in electricity, through the GCC
interconnection.
Key electricity statistics for the GCC countries are shown in table 2.9. Saudi Arabia is the
dominant electricity player in the region.
                              Table 2.9 Key statistics for GCC countries, 2010
                    Peak demand       Installed         Annual sales   Forecast        Average tariff   Electricity
                    (MW)              capacity          (TWh)          annual growth   (US cents/       consumption
                                      (MW)                             rate (%),       kWh)             (kWh/capita)
                                                                       2010 – 20
Kuwait                  10,970            12,579             49.3              8.5            0.6           18,259
Saudi Arabia            45,661            49,138            211.1              5.1            3.3            8,311
Bahrain                  2,633             3,227             11.0              5.4            2.6           13,750
Qatar                    5,090             7,881             18.8              9.5            2.2           11,059
UAE                     18,111            25,252               83              9.0            9.0           18,444
Oman                     3,594             4,100             11.4              8.7            3.6            4,071
Source: LAS. Forecast load growth figures derived from various World Bank reports.
Note: kWh = kilowatt-hour; TWh = terawatt-hour; MW = megawatt.

2.3.2 Demand/Supply Balance
There is currently adequate generation capacity to reliably supply demand. Figure 2.16 shows the
breakdown of GCC peak demand by country. But demand is growing rapidly, and the GCC
countries have struggled to invest in enough generation capacity to keep pace. Increasing growth
in demand will require significant investment, exceeding 80 GW of new generation capacity by
2020 (see figure 2.17).
                        Figure 2.16 Contribution by country to GCC peak demand




33
     Yemen is currently negotiating accession to the GCC.



                                                             48
                                             Oman

                                                     Kuwait
                                       UAE

                               Qatar
                                                          Saudi Arabia

                     Bahrain




                       Figure 2.17 GCC demand/supply situation (MW)
 180000
 160000
 140000
 120000
 100000                                                           Peak Demand
  80000                                                           Installed Capacity in 2010
  60000                                                           Additional Capacity Needed
  40000
  20000
        0
                     2010                     2020

2.3.3       Generation Mix
The current generation mix in the GCC region, as shown in figure 2.18, is split between natural
gas with a 55 percent share, and oil with a 45 percent share. In the GCC, the demand for water
and the use of multipurpose power and water desalination plants makes it more attractive to
generate electricity close to the water demand centers and to import natural gas rather than
electricity. The UAE has embarked on a plan to develop nuclear as a generation supply option in
the future, but currently generates 98 percent of its electricity from natural gas.




                                                49
                       Figure 2.18 Generation fuel mix in the GCC region


                 Kuwait                                     Saudi Arabia
      Natural
       Gas                                        Natural
                                                   Gas

                             Oil
                                                                            Oil




                Bahrain                                          Qatar


                   Natural                                        Natural
                    Gas                                            Gas




                   UAE                                          Oman
                       Oil

                                                                      Oil
            Natural                                         Natural
             Gas                                             Gas




                   GCC

                             Oil
             Natural
              Gas




Source: The LAS and various World Bank reports.
Note: GCC = Gulf Cooperation Council.


                                                   50
2.3.4 GCC Interconnection
The GCC interconnection, show in figure 2.19, allows for electricity exchange among the six
member states. The interconnection is aimed at capacity reserve sharing and improved supply
reliability. The interconnection reduces the investment needs for new generation.
The GCC member states established an Interconnection Authority in 2001 and signed a power
exchange and trading agreement in 2009. Although transfer capacities are relatively high,
scheduled power exchanges to date have been limited owing to the emphasis on reserve sharing
and the limited experience in trade under the new trading agreement (see table 2.10). Trade has
in fact been increasing as experience is gained with energy exchanges to date in 2011 about 60%
greater than 2010 levels.
                          Table 2.10 Power exchanges among GCC countries
                                           Max transfer               Energy exchanged
                                           capacity (MW)              (MWh/year)         Load factor (%)
         Saudi Arabia – Import             1200                       207                -
         Saudi Arabia – Export             1200                       25,072             0.3
         Kuwait – Import                   1200                       54,551             0.7
         Kuwait Export                     1200                       98,849             1.2
         Qatar – Import                    750                        41,554             0.8
         Qatar – Export                    750                        73,078             1.4
         Bahrain – Import                  600                        57,268             1.4
         Bahrain – Export                   600                       48,426             1.2
         UAE – Import                       900                       27,513             0.4
         UAE – Export                       900                       35,941             0.6
Note: MWh = megawatt-hour; MW = megawatt.
Exchange data relevant for period January 1, 2011 through October    17, 2011.
Exchange data include both scheduled and unscheduled transactions.

2.3.4.1 Background
The GCC region accounts for 40 percent of the world’s oil reserves and 25 percent of its natural
gas reserves, making the region a significant player in global primary fuels markets. The grid
allows electricity exchange among the six member states, with the primary objective being
capacity reserve sharing to reduce the need for investment in new generation capacity and
improve supply reliability.
The GCC interconnection project is almost completed. It includes three phases:
        Phase I: The power grids of the northern states of Kuwait, Saudi Arabia, Bahrain, and
         Qatar were interconnected in 2009 to form the GCC north grid. Phase I included the
         construction of a 400 kV grid in Kuwait, Saudi Arabia, and Qatar with a 400 kV
         submarine cable link to Bahrain. It also included a back-to-back HVDC transmission line
         to connect the 60 hertz (Hz) Saudi Arabian system with the 50 Hz systems of the other
         GCC countries.
        Phase II: The UAE and Oman completed interconnection in 2006 through a 220 kV line
         to form the GCC south grid. The project also integrated the isolated networks of the
         various emirates into the Emirates National Grid (ENG) and created an integrated
         northern grid in Oman.



                                                            51
         Phase III: The GCC north and south grids are to be interconnected in 2011. Phase III
          includes a double-circuit 400 kV line from Salwa to Shuwaihat (UAE); and a double- and
          single-circuit 220 kV, 50 Hz line from Al Ouhah (UAE) to Al Waseet (Oman).34
The GCC interconnection allows imports of 1,200 MW between Kuwait and Saudi Arabia, and
between 600 MW and 900 MW between Bahrain, Qatar, and the UAE. The interconnection to
Oman will be 400 MW. Figure 2.20 is a single-line diagram showing transfer limits between
countries.




34
   It is understood that Phase III may not go as planned. It has been suggested that it may be more desirable for Oman to connec t
directly to the GCC grid rather than through the UAE network.



                                                               52
                                     Figure 2.19 GCC interconnection




Source: Arab Union of Electricity.

                                                   53
                 Figure 2.20 Single-line diagram of GCC interconnection showing transfer limits




Source: GCCIA.

                                                       54
A distinguishing feature of the GCC network is its HVDC function, which automatically
supports system stability on the national power systems during severe disturbances through a
dynamic power reserve sharing control system. This and other systems have enabled the GCC
Interconnection Authority (GCCIA), to be discussed further, to achieve a high level of stability
and reliability in the region.
2.3.4.2 GCC Interconnection Authority
The GCCIA is a regional grid operator based in Dammam, Saudi Arabia. It was established in
2001 by royal decree to manage the interconnection and eventually become a regional player in
the electricity-trading market. The GCCIA is a joint-stock commercially registered entity that
acts independently of any country and organization. It has a 12-member board, with 2 members
from each GCC member country, and a chief executive officer who oversees four operational
divisions: system operations and maintenance, engineering and planning, finance and
accounting, and support services. Figure 2.21 shows the GCCIA’s legal and organizational
framework.
                 Figure 2.21 Legal and organizational framework of the GCCIA




Source: GCCIA.

2.3.4.3 Legal Framework
The GCC interconnection is governed by a General Agreement and a Power Exchange Trading
Agreement (PETA). The General Agreement sets out the terms for each member’s rights of

                                              55
interconnection, connection fees, performance standards, defaults, governing law, and
termination, as well as defining regulatory principles in terms of policy and regulation. The
PETA includes three primary components:
      A trading agreement setting out the terms and conditions for use of the interconnection
       and for scheduling power and energy transfers
      An interconnection and use of system agreement, setting out the terms and conditions for
       connecting to and accessing the interconnection
      A transmission code setting out detailed technical rules for connection and access to the
       interconnection
Parties to the PETA are determined by the structure and legislation of each member state, and
include TSOs responsible for transmission and the procurement and sale of power and energy.
When a member state has separate entities for transmission and procurement, it is allowed two
parties: one TSO and one procurement entity. Currently, there are eight parties to the PETA.
2.3.4.4 Organization
The GCC has established a cooperative and fully regulated environment for power exchange, as
described below.
GCC Electricity and Water Ministerial Committee
The GCC Ministerial Committee, which comprises ministers of electricity and water from each
of the member countries, is the forum where member states make necessary decisions pursuant
to legal agreements and receive and consider submissions and recommendations from the
Advisory and Regulatory Committee (ARC). The committee guides the GCCIA Board of
Directors on its policies and procedures.
Advisory and Regulatory Committee
The ARC meets every three months and is responsible for ensuring all concerned parties comply
with regulatory principles and performance standards. Each member state nominates a senior
national electrical regulatory official to be its representative on the ARC. The ARC also advises
the member states and GCCIA on the use of the interconnection. Member states must enforce the
regulatory decisions of the ARC, consistent with its charter.
The regulatory duties of the ARC include:
       Reviewing and approving the principles and methodologies applied by the GCCIA in
preparing its annual budget, tariffs, and charges in line with the PETA, and reviewing and
recommending the GCCIA’s budget for approval by its shareholders
      Ensuring that the GCCIA and member states comply with their roles
      Reviewing and approving performance standards proposed by the GCCIA and setting the
       standards’ effective date
      Conducting hearings in the event of default, whether alleged or admitted, under the
       PETA
      Applying the appropriate actions to be taken when standards are not met
      Resolving any disputes and obtaining expert opinions or appointing mediators as needed
                                               56
      Coordinating with national regulatory agencies in the member states
      Reviewing, approving, and supervising the          implementation of revisions to the
       interconnector transmission code
      Penalizing parties in default under the PETA
      Supervising the implementation of charges, compensations, fees, and tariffs
      Evaluating modifications and amendments to the legal documents
      Reviewing proposals for the expansion of the interconnection
      Reviewing the installed capacity obligations for each party
      Taking actions necessary to execute the decisions of the GCC Electricity and Water
       Ministerial Committee related to regulating the interconnection’s use
GCCIA Board of Directors
The GCCIA Board of Directors includes 12 members—2 from each country—with the chair
rotated among member states every three years. It addresses issues of policy (board of directors),
strategy (CEO, corporate services, and executive affairs), and operations (support services,
finance and accounting, system operations and maintenance, and engineering and planning).
Planning and Operations Committees
Each member state nominates a representative for the Operations Committee and the Planning
Committee. The objective of the Planning Committee is to coordinate planning between the
GCCIA and member states and to advise the GCCIA on planning issues. The Planning
Committee’s duties include:
      Collecting information pertaining to load forecasts, generation and transmission
       expansion plans, installed capacity obligations, and operating reserve requirements from
       each national TSO
      Assessing member states’ compliance with their installed-capacity obligations
      Recommending rules and procedures to the GCCIA as required to determine the
       capability of installed capacity resources and produce coincident peak-load forecasts, and
       publishing rules and procedures once approved
      Advising the GCCIA and member states on the adequacy of the interconnection with
       respect to reliability, reserves, delivery of operating reserves, and power exchange
       flexibility
      Advising the GCCIA and member states on load-forecast accuracy, loss-of-load
       expectation, installed reserve-margin target values, and transition periods, and proposing
       long-term solutions to operational problems and issues that may arise
      Reviewing changes or additions proposed by the GCCIA to the interconnection as well as
       related estimates of the required expenditures, and raising recommendations to the ARC
      Recommending to the GCCIA charges to be imposed on procurement parties



                                               57
      Ensuring that each member state meets its installed capacity obligation, and
       recommending corrective action for any deviations to the ARC
      Overseeing the development of the interconnection and presenting recommendations to
       the GCCIA
      Reviewing fees, charges, and tariff proposals raised by the Operations Committee and
       presenting recommendations to the ARC
      Advising the Operations Committee on required changes to the interconnector
       transmission code
The objective of the Operations Committee is to coordinate operations issues between the
GCCIA and the member states and to advise the GCCIA on operations matters. The Operations
Committee’s duties include:
      Handling operational matters such as metering, accounting, and payment
      Handling security and stability, including proposing Loss of Load Expectation (LOLE)
       target values to the Planning Committee
      Coordinating maintenance schedules
      Considering short-range load forecasts and related capacity requirements
      Advising the GCCIA on the operating-reserve measurement methodology
      Determining and allocating losses
      Handling interconnector transmission code matters
      Recommending tariff-, rate-, and charge-calculation methodologies to the Planning
       Committee
      Annually reviewing the operation and use of the interconnection to identify any actions
       that need to be taken and to monitor actions previously agreed to by the parties
      Investigating major faults related to the interconnection and reporting the findings to the
       GCCIA for forwarding to the member states and the Planning Committee
      Considering such other operating matters as may arise in carrying out the above duties, or
       such other matters as may be referred to it by the board
2.3.4.5 Trade
Currently, there are two primary vehicles for trade on the GCC interconnection:
      Scheduled exchanges. Prearranged bilateral trades between member states. These
       transactions are freely negotiated between the members. Once agreement is reached, the
       members must procure transmission capacity rights for use of the GCC interconnection
       from the GCCIA. Following GCCIA confirmation, the trade is consummated. A standard
       template has been developed and approved by the board to be used as a guideline for
       bilateral contracts.
      Unscheduled exchanges. Unscheduled exchanges may be needed during unforeseen
       contingencies. Member states are entitled to use the interconnection during emergency

                                               58
       situations to improve their reliability of supply. Member states are required to maintain
       operating reserves, to be called upon to support other members states when contingencies
       occur.
There have been a significant number of unscheduled transactions that have had a positive
impact on supply reliability, avoiding a number of cases where loads would have been
interrupted if not for the interconnection. Unscheduled transactions are paid for in kind; that is,
energy taken during the peak period is returned in the peak period. No money exchanges hands.
There has been only one scheduled exchange on the GCC interconnection to date, though
member states have requested the GCCIA to facilitate bilateral trades between interested
members in the future. The tariff for use of the interconnection is determined through an auction
process, with a floor price in place. If an emergency situation arises on the system during a
scheduled transaction, the transaction is cancelled.
The GCCIA believes it can become a launch pad for energy trading, opening the door to the
establishment of a common market in the region. A next step is to implement competition in
generation, with vertical and horizontal unbundling of the power sectors in each GCC country.
This would be accompanied by open access to the transmission system and full wholesale
competition, allowing generators in one country to sell power to buyers in another.
A brief description of the power sector in each GCC country follows. Although not currently
interconnected with the GCC, Yemen’s national electricity market is discussed owing to its close
proximity and the possibility of interconnecting with Saudi Arabia in the future.
2.3.5 GCC’s National Power Markets
2.3.5.1 Saudi Arabia
The Saudi Electric Company (SEC), a vertically integrated monopoly, dominates all aspects of
Saudi Arabia’s electric supply. SEC is a joint-stock company with shares traded publicly in the
Saudi Capital Market, though about 81 percent of the company is owned by the government and
the Saudi Arabian Oil Company.
The Saline Water Conversion Corporation (SWCC), Saudi Aramco, Tihamah Power Generation
Company, the Power and Water Utility Company (MARAFIQ), the Water and Electricity
Company (WEC), and a number of large industrial firms also generate electricity. The SEC is
responsible for tendering and procurement of IPPs, while the WEC, which is equally owned by
the SEC and SWCC, is responsible for tendering and procurement of independent water and
power producers (IWPPs).
Government agencies involved in the electricity system include the Ministry of Water and
Electricity, which establishes policy, plans, and strategy for the electricity sector, and the
Electricity and Cogeneration Regulatory Authority (ECRA), which reviews electricity costs and
tariffs. Electricity prices in Saudi Arabia must reflect the economic costs of providing service,
and the industry is not entitled to government subsidies.
The current structure of the electricity sector is shown in figure 2.22.
                  Figure 2.22 Structure of Saudi Arabia’s electricity sector




                                                 59
Source: ECRA 2007 Annual Report.

The ECRA provides regulatory oversight and issues licenses to entities engaged in activities in
the electricity and water desalination industry. The ECRA is a financially and administratively
independent Saudi organization. Its mission is to develop and pursue a regulatory framework in
accordance with government laws, regulations, policies, and standards, as well as international
best practices, to guarantee the provision of safe, reliable, reasonably priced, and efficient
electric power and desalinated water to the consumers of Saudi Arabia. A key responsibility of
the ECRA is to encourage private sector participation and investment in the electricity sector,
which is considered essential to the development and sustainability of the sector.
A 2005 law granted the ministry and the ECRA joint responsibility for transitioning the power
sector to a competitive market. They are to encourage the private sector to invest in the
electricity sector and ensure consumers’ right to choose their electricity supplier. The law also
ensures third-party access to the transmission and distribution networks and guards against
uncompetitive behavior and abuse of market power. The ECRA has approved a transmission grid
code and a distribution code to govern operation and use of the grid.
Saudi Arabia is far from having a competitive electricity market at this time. But the next stage
in the electricity sector reform effort, which will include unbundling and third-party access to the
transmission system, is under way. The first stage of the unbundling plan is expected to be
implemented in 2011. At this time, it appears that the SEC will be unbundled into one
transmission company, one distribution company, and four generation companies, all under the
direction of an SEC holding company. The SEC holding company would also be responsible for
fuel procurement on behalf of all generators in the country. The transmission company, which
has already been established, will lease the transmission assets from the SEC holding company.
Later, it is expected that distribution will be further unbundled into four or more companies.
It is anticipated that there will initially be a single-buyer market structure with the single buyer
purchasing all generation in the country and selling all power to wholesale buyers —the
distribution company, or, later, companies. The single buyer will reside within the SEC holding
                                                60
company. But it will be some time before any significant competition is introduced in the
electricity sector.
Retail tariffs in Saudi Arabia are far below the economic cost of supply. The World Bank reports
that residential customers consuming 700 kWh per month pay only 8 percent of a benchmark
tariff based on an average of the tariffs of France, Greece, Italy, Spain, Portugal, and Turkey. 35
Saudi Arabia’s electricity sector is summarized as follows:
        Reform: Under way with passage of new law, but progress is slow.
        Market structure : Vertically integrated, but there are plans for the unbundling and
         implementation of a single-buyer market.
        Separate regulator : Yes.
        Open access: No.
        Grid code/distribution code : Yes/yes.
        Private sector participation: Yes, in generation.
        Tariffs: Subsidized.
2.3.5.2 Kuwait
Kuwait’s power sector is dominated by a vertically integrated utility owned and operated by the
Ministry of Electricity and Water. There has been little reform—there is no independent
regulation and Kuwait has only recently approved its first IPP.
There are five generating stations located along the Arabian Gulf coast. All are steam or gas
turbines with the bulk of generation fuelled with oil. With high levels of forecast demand
growth, Kuwait will need over 18 GW of new generation capacity by 2020, and has announced
plans to tender new generation capacity requiring investment exceeding $2.5 billion. But the
proposed new plants will have total nominal capacity of only 4.8 GW, making Kuwait a prime
candidate for long-term electricity purchases over the GCC interconnection.
Retail tariffs in Kuwait are far below the economic cost of supply. The World Bank reports that
residential customers in Kuwait consuming 700 kWh per month pay only 4.5 percent of a
benchmark tariff based on an average of the tariffs of France, Greece, Italy, Spain, Portugal, and
Turkey.36
Kuwait’s electricity sector is summarized as follows:
        Reform: Limited.
        Market structure : Vertically integrated with no unbundling.
        Separate regulator: No.
        Open access: No.

35
   See February 2009 World Bank report entitled, Tapping a Hidden Resource—Energy Efficiency on the Middle East and North
Africa .
36
   See February 2009 World Bank report entitled, Tapping a Hidden Resource —Energy Efficiency on the Middle East and North
Africa .



                                                           61
        Grid code/distribution code : No/no.
        Private sector participation: None, but plans for introducing IPPs in generation.
        Tariffs: Subsidized.
2.3.5.3 Bahrain
Generation in Bahrain follows the build-own-operate (BOO) model, with several privately
owned facilities. The Electricity and Water Authority acts as the single buyer of power from the
BOO plants. But it also acts as the regulatory authority for the power sector, so there is no
independent regulatory agency. The Ministry of Electricity and Water is responsible for
electricity production and distribution in Bahrain.
Bahrain is a very small player in the region in terms of electricity, with only about 3,000 MW of
installed generating capacity in 2010. At present, two combined water and power production
complexes and two smaller electricity-only plants provide all of Bahrain’s electricity. Recently,
the government announced an international bid for an additional 1,200 MW power and
desalination plant, which is expected to be commissioned by the summer of 2011.
Bahrain’s retail electricity prices are far below the economic cost of supply. The World Bank
reports that residential customers in Bahrain consuming 700 kWh per month pay only 4.5
percent of a benchmark tariff based on an average of the tariffs of France, Greece, Italy, Spain,
Portugal, and Turkey. 37
Bahrain’s electricity sector is summarized as follows:
        Reform: Limited.
        Market structure : Single buyer, partial unbundling.
        Separate regulator : No.
        Open access: No.
        Grid code/distribution code: No/no.
        Private sector participation: Yes, in generation.
        Tariffs: Subsidized.
2.3.5.4 Qatar
Qatar has embarked on the restructuring and privatization of its electricity sector. All power
generation in Qatar is now done by the private sector and IWPPs. Qatar Petroleum supplies the
IWPPs with natural gas, and the Qatar General Electricity and Water Corporation
(KAHRAMAA) buys power from the IWPPs. KAHRAMAA is also responsible for planning
new generating capacity, and is working on several large-scale power projects with foreign
companies. Installed generating capacity in Qatar in 2010 was 7,660 MW. Planned additions will
bring the total to 8,750 MW in 2011. KAHRAMAA is required to privatize its power and water
transmission and distribution systems, but a firm date for the privatization has not yet been
established.
37
  See February 2009 World Bank report entitled, Tapping a Hidden Resource—Energy Efficiency on the Middle East and North
Africa .



                                                          62
The Ministry of Energy and Industry issues licenses for power generation and transmission. The
ministry monitors and ensures that licensees comply with standards, specifications, and laws
regulating these activities. The government has not yet appointed a regulator, so KAHRAMAA
takes on this role, administering a transmission grid code, a distribution planning manual, a
distribution code of practice, and a distribution construction manual.
Owing to the small size of the transmission and distribution system, the government is
considering the implementation of a single-buyer market model. KAHRAMAA will purchase all
electrical energy and act as the single wholesaler, or bulk trader, of electrical energy in Qatar.
Qatar’s residential tariff is 2.2 US cents/kWh for consumption up to 4,000 kWh/month, and 2.7
US cents/kWh for consumption above 4,000 kWh/month. The World Bank reports that
residential customers in Qatar consuming 700 kWh per month pay only 12 percent of a
benchmark tariff based on an average of the tariffs of France, Greece, Italy, Spain, Portugal, and
Turkey.38
Qatar’s electricity sector is summarized as follows:
        Reform: Under way.
        Market structure : Moving to single buyer with some unbundling.
        Separate regulator : No.
        Open access: No.
        Grid code/distribution code : Yes/yes.
        Private sector participation: Yes, in generation.
        Tariffs: Subsidized.
2.3.5.5 The UAE
The UAE’s power sector is organized differently in each of the seven emirates. Curr ently, there
are four service providers: ADWEA, DEWA, SEWA, and FEWA. Each operates as a separate
entity, but the Ministry of Energy is studying a common federal framework. The UAE’s
governing body, the Federal National Council, has approved a plan to privatize the FEWA.
Abu Dhabi has one of the more advanced power reform programs in the GCC, including an
independent regulatory agency, the Abu Dhabi Regulation and Supervision Bureau, which
regulates all companies undertaking activities associated with electricity production,
transmission, and distribution. The ADWEA, a public agency owned by the Abu Dhabi
government, is a holding company for unbundled electricity entities, including two generation
companies, the single buyer (ADWEC), the transmission company, and two distribution
companies. The ADWEA also develops, implements, and manages electricity policy. Abu Dhabi
has both a grid code and distribution code to govern connection to, and use of, the networks.
Five IWPPs have been commissioned on a BOO basis as joint ventures between the ADWEA
and various international companies. In each IWPP, the ADWEA has a 60 percent share while

38
  See February 2009 World Bank report entitled, Tapping a Hidden Resource —Energy Efficiency on the Middle East and North
Africa .



                                                           63
overseas private investors own the remaining 40 percent. All IWPPs sell electricity to the single
buyer.
Abu Dhabi is the only emirate to implement a privatization program in the electricity sector, and
the only emirate to separate the transmission function from generation (albeit under the same
holding company). But Dubai has also introduced the IWPP model for new generation and plans
to reform its power sector similar to that of Abu Dhabi and privatize assets as was done with the
ADWEA.
In 2008 the UAE projected escalating electricity demand from 15.5 GW in 2008 to over 40 GW
in 2020. With natural gas supplies sufficient for only half of this amount, coal dismissed owing
to environmental and energy security implications, and renewables able to supply only 6 to 7
percent of the needed power by 2020, the UAE is taking steps to embark on a nuclear power
program in close consultation with the International Atomic Energy Agency (IAEA). It has
accepted a $20 billion bid from a South Korean consortium to build four commercial nuclear
power reactors with a combined capacity of 5,600 MW by 2020.
Retail electricity tariffs continue to be subsidized. According to the government website,
residential customers in the UAE consuming 700 kWh per month pay only 28 percent of a
benchmark tariff based on an average of the tariffs of France, Greece, Italy, Spain, Portugal, and
Turkey.39
The UAE’s e lectricity sector is summarized as follows:
           Reform: Under way in several of the Emirates.
           Market structure : Single buyer in Abu Dhabi with partial unbundling. Other Emirates
            mostly vertically integrated with little unbundling.
           Separate regulator : Yes, in Abu Dhabi; no, in other Emirates.
           Open access: No.
           Grid code/distribution code : Yes, in Abu Dhabi; no, in other Emirates.
           Private sector participation: Yes, in generation.
           Tariffs: Subsidized.
2.3.5.6 Oman
Oman was the first GCC country to introduce the IPP and IWPP models and has successfully
privatized many of its power plants. The state-owned Oman Electricity Transmission Company
is responsible for the transmission network, while the state-owned Oman Power and Water
Procurement Company acts as the single buyer, purchasing all electricity from generators and
selling it on to the distribution companies and large consumers. The Oman Power and Water
Procurement Company is responsible for determining and securing new capacity when needed,
subject to regulatory approval, and has the exclusive right to import and export power. There are
three state-owned distribution and supply companies of which the Electricity Holding Company
owns 99.99 percent and the Ministry of Finance owns the other 0.01 percent. There is a high
level of private ownership in the generation sector.

39
     www.rsb.gov.ae.



                                                     64
Oman’s Ministry of Water and Electricity is responsible for policy while regulation is the
responsibility of the financially and administratively independent Authority for Electricity
Regulation (AER). The AER is also responsible for facilitating privatization of the electricity
sector. The law requires the AER to document tariffs and quantify the government subsidy to be
paid by the Ministry of Finance. The AER has approved a grid code, a distribution code, and a
formal connection-and-use-of-system charging methodology for Oman.
Figure 2.23 shows the organization of Oman’s power sector.
                                       Figure 2.23 Oman’s power sector




Source: www.aer-oman.org/index.php?option=com_content&view=article&id=120&Itemid=178 .

Oman will require between 3,000 and 4,000 MW of new generating capacity by 2016. The Oman
Power and Water Procurement Company has initiated competitive procurement for two new gas-
fired IPPs, each having a capacity of 650– 750 MW with an expected commissioning in 2013.
Temporary generating capacity using diesel or open-cycle gas-turbine technology is also under
consideration for 2011.40 Use of gas for power generation is expected to double by 2020.
Retail electricity tariffs remain far below the economic cost of supply in Oman. The World Bank
reports that residential customers in Oman consuming 700 kWh per month pay only 15 percent




40
     See Oman Power and Water Procurement Comp any’s 7 -Year Statement, 2010 – 16.



                                                           65
of a benchmark tariff based on an average of the tariffs of France, Greece, Italy, Spain, Portugal,
and Turkey.41
Oman’s electricity sector is summarized as follows:
        Reform: Under way with passage of new law.
        Market structure : Single buyer with full unbundling. Potential to move to wholesale
         competition under new law.
        Separate regulator : Yes.
        Open access: No.
        Grid code/distribution code : Yes/yes.
        Private sector participation: Yes, in generation.
        Tariffs: Subsidized.
2.3.5.7 Yemen
Yemen is discussed in this section of the report owing to its close proximity to the GCC and the
possibility that it might be interconnected with the GCC in the future.
In Yemen the Ministry of Electricity and Power is responsible for policy making in the
electricity sector. The state-owned Public Electricity Corporation (PEC) is a vertically integrated
utility and the country’s primary provider of electricity.
A 2009 law establishes an independent regulator and access to the transmission and distribution
networks on a fair and nondiscriminatory basis. The PEC is to be unbundled into generation,
transmission, and distribution companies. But detailed regulations have not yet been developed
under the new law. The law allows for a three-year transition period during which the PEC is
required to create generation, transmission, and distribution companies.
The new independent regulator, the Regulating Board of Electricity Activities, will prepare the
detailed regulations required under the law. The Minister of Electricity and Power will chair the
board, which will regulate tariffs for generation, transmission, and wholesale supply and
distribution. Although the board has responsibility for regulating tariffs, ultimate approval of
tariffs lies with the Council of Ministers. Transmission access will be governed by the
regulations being developed by the board.
Yemen has a small power sector with generating capacity of about 1,200 MW installed and an
additional 1,068 MW available. Demand is expected to increase substantially in the future, to
over 3,000 MW (peak) by 2020. Over 3,000 MW of new generating capacity will be required by
2020 after allowing for retirements. Most new generation is expected to be fired with gas. A 180
MW wind farm is also under consideration.
Yemen’s retail electricity tariffs are below the economic cost of supply. The World Bank reports
that residential customers in Yemen consuming 700 kWh per month pay only 24 percent of a


41
  See February 2009 World Bank report entitled, Tapping a Hidden Resource —Energy Efficiency on the Middle East and North
Africa .



                                                           66
benchmark tariff based on an average of the tariffs of France, Greece, Italy, Spain, Portugal, and
Turkey.42
Yemen’s electricity sector is summarized as follows:
        Reform: Under way with passage of new law, but progress stalled.
        Market structure : Vertically integrated, but plans for unbundling and implementation of
         single-buyer market.
        Separate regulator : Yes, but does not have full responsibility for tariffs.
        Open access: No.
        Grid code/distribution code : No/no.
        Private sector participation: None.
        Tariffs: Subsidized.
2.3.6 Summary of Arab Market Status
The power sectors in the Arab countries are facing significant challenges. High levels of
electricity demand growth that are expected to continue into the future are taxing the ability of
the countries to finance and construct new generating capacity necessary to meet this demand
with adequate levels of reliability while replacing older plants due for retirement. Retail tariffs
are woefully inadequate in most Arab countries; an assessment of retail tariffs in Arab countries
is provided in attachment 2.A.
In order to address the financing and construction challenges, significant institutional reform is
necessary, going well beyond retail tariff reform if the Arab countries are to successfully attract
investment. Private sector investment can play a major role in meeting the Arab countries’
electricity sector challenges, as has been proved around the world. The private sector can help
mobilize the huge amounts of capital necessary to fund projects needed to meet increasing
electricity demand. Further, private sector management expertise can significantly improve the
operational efficiency of an electricity market. Details of private sector participation in 14 Arab
countries are provided in attachment 2.B.
As will be addressed in chapter 3, institutional reforms generally relate to leveling the playing
field so that investors, both public and private, are assured of a fair opportunity to recover their
investment plus profit. This generally means that the market will be administered in a fair and
transparent manner, with open access to the transmission system and key administrators of the
market (that is, regulator, system operator, market operator, and so on) skilled and informed in
market operations and independent of outside influences. A summary of key institutional bodies
and governance documents in place in Arab countries is provided in table 2.11.
                       Table 2.11 Key institutions and governance documents




42
  See February 2009 World Bank report entitled, Tapping a Hidden Resource —Energy Efficiency on the Middle East and North
Africa .



                                                           67
                                                                         Transmission Grid Code




                                                                                                                            Sector Structure/reform
                                                                                                  Distribution Grid Code




                                                                                                                                                            Regional electricity
                                                  Electricity Law




                                                                                                                                                                   forums
                                 Regulator
            Algeria             CREG               Yes                      Yes                    Yes                     SB/UNB
                                                   No                                                                      SB/Part                    AUE, AMU,
            Morocco                No                                         No                       No
 Maghreb




                                                  (RES)                                                                       UNB                        IMME, EU,
                                                                                                                                                         COMELEC
            T unisia               No            Decree                       No                       No                   VER
                                                  Yes
            Egypt                ERA                                          No                       No                   VER
                                                 (RES)
            Iraq                   No             No                          No                       No                   VER
                                                  Yes                                                                                                 AUE, AERF,
            Jordan               ERC                                        Yes                    Yes                     SB/UNB
                                               (EE&RES)                                                                                                  Steering,
 EIJLLPST




                                                  Yes                                                                                                    Planning &
            Lebanon                No                                         No                       No                   VER
                                                 (PPP)                                                                                                   Operating
            Palestine           PERC              Yes                         No                       No                  SB/UNB                        Committees
                                                  Yes
            Syria                  No                                         No                       No                   VER
                                               (EE&PPP)
            Libya                  No             No                          No                       No                   VER
                                                                                                                           SB/Part
            Bahrain                No                No                       No                       No
                                                                                                                              UNB
            Kuwait                No              No                        No                     No                       VER
                                                                                                                                                      AUE, AERF, GCC
            Oman                 AER              Yes                       Yes                    Yes                     SB/UNB
                                                                                                                                                         Ministerial
            Qatar                 No              Yes                       Yes                    Yes                     SB/UNB
 GCC




                                                                                                                                                         Committee,
                                                  Yes
            Saudi Arabia        ECRA                                        Yes                    Yes                      VER                          ARC, GCCIA
                                              (RES-Future)
                                                                                                                           SB/Part
            UAE                 Bureau              Yes                     Yes                    Yes
                                                                                                                              UNB
            Yemen                 No              No                        No                     No                       VER
            Comoros                ?                ?                        ?                      ?                         ?
            Somalia                ?                ?                        ?                      ?                         ?
 Others




            Sudan                 Yes              Yes                      Yes                    Yes                     SB/UNB                     AUE
            Mauritania           ARE                Yes                       No                       No                   VER
            Djibouti               No                No                       No                       No                   VER
Note: SB = single buyer; UNB = unbundling exists; VER = vertically integrated; ? = no information; RES = renewable energy
source; EE = energy efficiency; PPP = private-public partnership; UAE = United Arab Emirates.

2.4         Neighboring Regions
2.4.1       Europe
The European Commission’s Electricity Market Directives have significantly transformed
Europe’s energy industry with the objective of promoting competition in the internal electricity
market. The focus of the directives has been on unbundling monopoly elements such as network
operation from the other functions, ensuring third-party transmission access, ensuring
independent regulatory oversight including for cross-border exchanges and trade, and providing
that all customers choose their supplier.
During the past 15 years electricity consumption in the EU has increased at an average annual
rate of 1.7 percent. Based on the International Energy Agency’s (IEA’s) World Energy Outlook
(2009) reference scenario forecast, electricity demand in the EU is expected to grow at a
compounded annual average rate (CAGR) of 0.9 percent from 2,840 terrawatt-hours (TWh) in

                                                                    68
2007 to 3,485 TWh in 2030. This compares with a forecast of 1 percent annual growth for the
Organisation for Economic Co-operation and Development (OECD) member countries and 2.5
percent for the world.
Table 2.12 summarizes the electricity supply-demand balance in the EU for the period 2002– 07.
The installed generation capacity has increased from 716 GW in 2002 to around 811 GW in
2008. About 7 percent of this capacity was owned by auto-producers (industries producing
power mainly for their own consumption). The remaining 93 percent was for public supply.
                     Table 2.12 EU electricity demand/supply balance, 2002 – 07
Item/unit                                       2002       2003        2004       2005        2006       2007       2008
T otal installed capacity (GW)                  716        728         737        747         762        779
 Hydro                                          142        137         138        139         140        140
 Wind                                           23         29          34         41          48         56         65
 Geothermal                                     0.68       0.72        0.66       0.69        0.70       0.70       0.85
 Nuclear                                        138        137         136        135         134        133
 Conventional thermal                           412        424         427        432         440        449
Capacity in utilities (GW)                      670        682         685        690         717        731
Capacity of auto producers (GW)                 46         47          51         53          53         54
Gross generation (T Wh)                         3,117      3,216       3,288      3,309       3,540      3,362      3,260
 Hydro                                          348        338         357        341         345        344        414
 Wind                                           36         44          59         70          82         104
 Geothermal                                     5          5           6          5           6          6          6
 Nuclear                                        990        996         1,008      998         990        935        936
 Conventional thermal                           1,738      1,832       1,857      1,893       1,929      1,969      1,904
Net generation (T Wh)                           2,953      3,049       3,117      3,134       3,178      3,185      3,096
Imports into EU (T Wh)                          285        290         281        324         311        318        297
Exports from EU (T Wh)                          272        292         288        313         307        308        285
Self-consumption by producers (including        289        298         302        305         296        298        45
pumped storage)
Network losses (T Wh)                           208        215         223        219         202        204
Final consumption (T Wh)                        2,600      2,668       2,722      2,763       2,826      2,843
 Of this industry                               1,092      1,102       1,126      1,135       1,133      1,150
 T ransport                                     72         72          72         74          71         72
 Households                                     739        771         784        795         807        801
 Services, others                               697        722         738        758         816        821
Source: http://epp.eurostat.ec.europa.eu/cache/IT Y_OFFPUB/KS-PC-09-001/EN/KS-PC-09-001-EN.PDF.
Note: Data for 2008 are provisional from Monthly Statistics issue 11/2009 of Eurostat. In 2008 hydropower generation includes
wind power and self-consumption relates to pumped storage units. T he data exclude solar, biomass, and waste-based generation
and capacity.

The IEA forecasts that the total annual electricity generation will increase from 3,325 TWh in
2007 to 3,765 TWh in 2030, an annual increase of 0.8 percent. The generation levels and
generation mix envisaged for 2015, 2020, and 2030 are summarized in table 2.13.
     Table 2.13 Forecast generation levels and generation mix in the EU through 2030
Electricity generation (TWh)                                                              Share (%)        CAGR (%)
                        1990        2007        2015      2020       2025      2030       2007   2030      2007 – 30
T otal generation       2,568       3,325       3,432     3,587      3,765     3,968      100    100       0.8
Coal                    1,050       1,024       907       870        876       862        31     22        -0.7
Oil                     221         112         69        51         43        43         3      1         -4.1
Gas                     191         725         746       861        929       995        22     25        1.4
Nuclear                 795         935         874       773        721       736        28     19        -1.0
Hydro                   286         309         351       381        400       408        9      10        1.2
Biomass and waste       20          105         143       172        191       212        3      5         3.1
Wind                    1           104         300       412        508       581        3      15        7.8


                                                            69
Geothermal               3       6          8     9         11        13       0      0       3.6
Solar                    0       4          34    56        80        107      0      3       15.7
T otal and wave          1       1          1     2         4         9        0      0       13.4

Source: World Energy Outlook, IEA 2009.
Note: CAGR = compound annual growth rate.

The EU currently depends on imports for 50 percent of its overall energy needs, and this figure is
expected to rise to 64 percent by 2020 and 67 percent by 2030. Between now and 2030 the
import dependency for gas is expected to increase from 59 percent to 84 percent, the oil import
dependency will rise to 95 percent, and the import dependency for solid fuels is expected to rise
from 40 percent to 63 percent. Import dependency for uranium is already at nearly 98 percent
(IEA Energy Policy Review EU 2008). Aside from this dependency on fuel imports, there is
little direct import dependency for electricity.
The EU is a desirable trading partner for the Arab countries due to its diversity of demand.
Demand in the EU peaks in winter, while the Arab countries, with the exception of Syria, are all
summer peaking. This poses significant potential for reserve sharing and economy energy trade
to take advantage of production cost differences in the summer and winter periods.
More details on Europe’s power sector are provided in a ttachment 2.C.
2.4.2     Turkey
Turkey has been implementing significant reforms in recent years in an effort to join the EU
internal electricity market. The original state-owned vertically integrated Turkish Electricity
Corporation (TEK) has been unbundled to enable private sector participation and the
implementation of a competitive electricity market.
Electricity demand has been growing at an average annual rate of about 8 percent during the past
four decades. The Turkish Power Transmission Company forecasts a compound annual growth
rate (CAGR) of 7.45 percent in the base case and 6.6 percent in the low case over 2008 – 17 (see
table 2.14).
                     Table 2.14 Demand forecast for the Turkis h electricity system
                              Base Case                          Low Case
                  Year        Peak demand    Gross energy        Peak demand       Gross energy
                              (MW)           demand (GWh)        (MW)              demand (GWh)
                  2008        32,478         204,000             32,143            204,000
                  2009        35,053         219,013             34,571            216,992
                  2010        37,832         236,182             37,182            230,705
                  2011        40,716         253,837             39,573            246,181
                  2012        43,819         272,812             42,331            262,696
                  2013        47,159         293,205             45,167            280,319
                  2014        50,753         315,123             48,193            299,124
                  2015        54,622         338,679             51,421            319,190
                  2016        58,560         363,695             54,788            340,379
                  2017        62,782         390,559             58,376            362,975
                  CAGR (%)    7.60           7.45                6.85              6.60
Source: 10-Year Generation Capacity Projection (2008– 17), www.teias.gov.tr.
Note: CAGR = compound annual growth rate; GWh = gigawatt-hour; MW = megawatt.

Turkey nearly doubled its generation capacity between 1998 and 2008, but the demand-supply
balance remained tight. Demand is expected to outstrip supply in 2011 if additional new
generation capacity does not come on line. In response, Turkey plans to add 17,136 MW of new

                                                    70
generating capacity with an annual production capability of 77.9 TWh during the 2008– 15 time
frame. About 68 percent of the new capacity will be hydroelectric, 26 percent will be thermal,
and the remaining 6 percent will be based on renewable sources such as wind and geothermal.
The expansion plan scenarios are shown in table 2.15.
                        Table 2.15 Turkey’s generation expansion plan (2008–15)
                                                Additional            Additional annual   Additional annual
  Categories                                    generation capacity   generation (GWh)    firm power generation
                                                (MW)                                      (GWh)
  A. Base case
  State-owned power plants under construction   4,318.7               16,825.9            12,520.4
  Private sector power plants licensed          12,817.5              61,061.8            47,339.7
  T otal                                        17,136.2              77,887.7            59,860.1
  Hydropower capacity                           11,682.4              41,587.4            24,537.9
  T hermal power capacity                       4,523.2               32,586.4            32,312.8
  Wind / geothermal / other                     930.6                 3,713.9             3,189.4
  T otal                                        17,136.2              77,887.7            59,860.1
  B. Low case
  State-owned power plants under construction   4,318.7               16,825.9            12,520.4
  Private sector power plants licensed          8,598.8               41,848.9            33,581.6
  T otal                                        12,917.5              58,674.8            46,102.0
  Hydropower capacity                           8,627.2               29,455.4            17,542.9
  T hermal power capacity                       3,791.5               27,194.7            26,921.1
  Wind / geothermal / other                     498.8                 2,024.7             1,638.0
  Total                                         12,917.5              58,674.8            12,520.4
Source: www.teias.gov.tr.
Note: GWh = gigawatt-hour; MW = megawatt.

Turkey has electrical interconnections with Bulgaria, Greece, Georgia, Armenia, Azerbaijan,
Iraq, Iran, and Syria; however, the volume of electricity exchanges has been less than 2 percent
of Turkey’s annual consumption. Turkey has plans to expand interconnection capacity with
Georgia, Iran, Iraq, and Romania. Turkey has excellent prospects as an electricity export
destination and as a transit country for exports to the EU. It has attractive electricity prices, an
open, competitive market structure with third-party access, and numerous market participants,
and it will soon be a member of the ENTSO-E with synchronous operation with the European
grid. More details on Turkey’s electricity sector are provided in attachment 2.D.
2.4.3    Iran
Iran is well endowed in terms of oil and gas with proven oil reserves at year end 2008 estimated
at 18.9 billion tonnes (10.9 percent of the world’s total and the second-largest in the world after
Saudi Arabia) and proven natural gas reserves estimated at 29.61 trillion cubic meters (16
percent of the world’s total and the second-largest in the world after Russia).
The electricity sector is unbundled vertically by function and horizontally by the existence of
multiple companies for generation and distribution. The Ministry of Energy is very much
involved in the power sector, owning and operating hydropower and thermal generating stations,
as well as the Iranian Grid Management Company, which is responsible for the operation of the
transmission system, system dispatch, and market operations at the wholesale level. In the
generation segment, public sector generation units owned by the regional electric companies
operate alongside a number of privately owned IPPs. As shown in table 2.16, Iran uses a broad
variety of generation methods.
               Table 2.16 Energy generation in FY 2007 – 08, by type of unit (GWh)

                                                       71
Types of power-plant units                  Units under MO E         O ther units          System total         Percentage
                                                                                                                share
Steam power stations                        90,900
                                                                     13,953                131,832              64.6
Simple cycle gas turbines                   26,979
Gas-fired combined-cycle units              53,796                   0                     53,796               26.4
Diesels                                     225                      0                     225                  0.1
Subtotal for thermal power units            171,900                  13,953                185,853              91.1
Hydropower units                            17987                    0                     17,987               8.8
Wind power units                            141                      0                     141                  0.1
Subtotal for hydro and wind units           18,128                   0                     18,128               8.9
T otal for all units                        190,028                  13,953                203,983              100.0
Source: www.tavanir.ir.
Note: MOE = ministry of energy; GWh = gigawatt -hour.

The Iranian Ministry of Energy estimated in 2008 that peak demand of the system was forecast
to grow from 37,053 MW in FY 2007– 08 to 88,166 MW by FY 2020– 21 (see table 2.17). To
meet the forecast demand, the ministry planned to raise total installed generation capacity to
about 125,000 MW by FY 2020– 21. So far, 22,204 MW of new generating capacity is expected
to be added during FY 2008– 16, bringing the total installed capacity in the country to 71,617
MW by that date. The new capacity will consist of 14,380 MW of gas-fired combined-cycle
units; 4,570 MW of hydropower units; 2,614 MW of gas-turbine units; and 640 MW of steam-
turbine units. About 55 percent of the total capacity additions will be in the private sector in the
form of BOT and BOO projects; the remainder will come from the public sector.
                                        Table 2.17 Peak demand forecast
                      Year                Peak demand (MW)                    Annual growth rate (%)
                     2007 – 08                  37,053                                  -
                     2008 – 09                  40,189                                  8
                     2009 – 10                  43,762                                  9
                     2010 – 11                  47,501                                  9
                     2011 – 12                  51,484                                  8
                     2012 – 13                  55,797                                  8
                     2013 – 14                  60,500                                  8
                     2014 – 15                  64,843                                  7
                     2015 – 16                  69,473                                  7
                     2016 – 17                  72,293                                  4
                     2017 – 18                  76,261                                  5
                     2018 – 19                  80,230                                  5
                     2019 – 20                  84,198                                  5
                     2010 – 21                  88,166                                  5

Source: Presentation by the Ministry of Energy of Iran on February 19, 2008, www.igmc.ir/usrFiles/../ElectricPowerIndustry-iri-
feb2008.

Iran has numerous international interconnections with the power systems of Armenia,
Azerbaijan, Turkey, Turkmenistan, Afghanistan, Pakistan, and Iraq. In spite of the large number
of international interconnections, trade plays a relatively minor role in the Iranian power sector.
The total volume of trade of 4.36 TWh in FY 2007– 08 was about 2.1 percent of the total
generation in the country. Details of Iran’s power sector are provided in a ttachment 2.D.
2.4.4 Nile Basin Initiative (NBI)




                                                              72
The riparian states of the Nile River43 have formed a partnership called the Nile Basin Initiative
(NBI) seeking to develop the river in a cooperative manner, share its socioeconomic benefits
equitably, and promote regional peace and security. One of the subsidiary programs is the
Eastern Nile Subsidiary Action Program sponsored and advanced by the Eastern Nile Technical
Regional Office (ENTRO). The Ethiopia-Sudan electricity interconnection project was
implemented as part of this subsidiary program. Promoting power trade through regional
cooperation to increase access to electricity and lower costs is a key part of the program. Several
major hydropower projects are being studied under the program for facilitating energy trade
among Ethiopia, Sudan, Kenya, and Egypt.
Meanwhile, countries belonging to the East African Community (EAC) 44 are promoting the
Eastern Africa Power Pool (EAPP), which will be greatly facilitated by the interconnections and
studies pursued under the NBI’s program. The interconnections implemented and under
consideration in the EAPP are shown in figure 2.24. The project, with a total cost of $43.1
million, consists of a recently completed 296.5 km double-circuit 230 kV transmission link
between Bahir Dar substation in Ethiopia and the Sudan border. Additionally, the Sudanese
National Electric Corporation is constructing a 155 km double-circuit 230 kV link from the
Sudan-Ethiopia border to Gedaref Substation in Sudan. Power export from Ethiopia to Sudan
would be on the basis of a three-year power-purchase agreement (PPA) under which an annual
firm supply of 100 MW would be purchased. Additional supply would be agreed upon in the
future.
Ethiopia has a large hydropower potential and, having recently commissioned three new
hydropower projects, will have surplus power to export. The nation could however benefit from
imports of thermal power from Sudan to manage seasonal variations in domestic generation.
Ethiopia has already completed an interconnection to Djibouti and is pursuing an interconnection
with Kenya to export the surplus from these projects and those under construction. Sudan also
has significant hydropower resources; it has recently commissioned two new plants and is
investigating and preparing studies and designs for several more.
                                  Figure 2.24 Eastern Africa Power Pool




43
   T he countries include Burundi, the Democratic Republic of Congo, Egypt, Ethiopia, Kenya, Rwanda, Sudan, T anzania, and
Uganda with Eritrea as an observer.
44
   T hese countries are Burundi, the Democratic Republic of Congo, Egypt, Ethiopia, Kenya, Rwanda, and Sudan.



                                                           73
Further details of the NBI are provided in attachment 2.F.
2.4.5 West African Power Pool (WAPP)
The Economic Community of West African States (ECOWAS) adopted the West African Power
Pool (WAPP) initiative in 1999 to integrate electricity markets and address lack of electricity
access in its 15 member countries —Benin, Burkina Faso, Cape Verde, Côte d’Ivoire, the
Gambia, Ghana, Guinea, Guinea-Bissau, Liberia, Mali, Niger, Nigeria, Senegal, Sierra Leone,
and Togo. Following the adoption of the WAPP Articles of Agreement in October 2005, the
WAPP organization was established in January 2006. The WAPP aims to enhance information
sharing among the ECOWAS member countries, harmonize electricity operating standards,
design priority investments, improve electricity system reliability and cost effectiveness, and
encourage cross-border electricity trade.
A number of interconnection projects are either under way or in the planning stages in the WAPP
(see figure 2.25). The goal of these projects is to establish secure, reliable transmission corridors

                                                 74
for the transfer of low-cost hydroelectric and gas-fired power to displace diesel-based sources.
The WAPP generation and transmission projects are shown in figures 2.26 and 2.27.
                              Figure 2.25 WAPP interconnection projects




Source: ECOWAS WAPP Project, Nigeria, Benin, T ogo, and Ghana Interconnection Project.

   Figure 2.26 WAPP generation projects                   Figure 2.27 WAPP transmission integration




Source: WAPP Presentation, Africa Investment Project Summit, November 8, 2007.
2.4.6 Trade with Countries to the East
The market vision for the Pan-Arab network has the flexibility to accommodate electricity trade
with its Asian neighbors to the east. There are numerous initiatives in the Asian region to
interconnect electricity systems. The Association of Southeast Asian Nations (ASEAN) countries
have launched the most systematic effort. The first interconnection project was implemented in
1971 when the Nam Ngum 1 hydropower project between Laos and Thailand commenced
operation. This was followed by power exchange agreements among Thailand, Malaysia, and
Singapore in 1978, and introduction of the concept of the ASEAN Power Grid in 1980, which
did not receive formal high-level endorsement until 1997, but moved rather quickly afterwards.
The underlying vision of the ASEAN Power Grid is based on a stepwise progression where
initial trade takes place on cross-border, bilateral terms, gradually expanding to subregional and
eventually regional levels. Of the 14 interconnection projects identified by the ASEAN Power
Grid master plan, 3 are already in operation and the other 11 are planned through 2015.

                                                          75
Aside from the ASEAN network, there have been some other relevant experiences in South and
Central Asia. The Central Asia projects have a high profile in the international community due to
their prevailing controversies. Central Asia has considerable hydropower resources that could be
developed and traded within or outside the region. But the prospects for expanding electricity
generation and trade are uncertain due to the lack of trust and genuine cooperation among the
relevant stakeholders. The infamous energy-water nexus among the Central Asian states has
been addressed by a number of international institutions, with limited success. Frustrated with
the slow progress in intraregional trade, Central Asian countries are now seeking the possibility
of exporting electricity to countries outside the region, including Afghanistan, China, Iran, and
Pakistan. This has resulted in a new initiative among Afghanistan, Kyrgyzstan, Pakistan, and
Tajikistan to develop a Central Asia Regional Electricity Market (CASAREM). The idea behind
this initiative is to utilize the Central Asia’s surplus hydropower in summer to meet high and
growing demand in South Asia.
2.5      Summary
The high growth in electricity demand that Arab countries have experienced in recent years is
expected to continue into the future (see figure 2.28). Peak demand is forecast to be 84 percent
greater than 2010 levels by 2020, requiring an additional 135 GW of generating capacity. The
total investment that will be needed for the expansion of generation, transmission, and
distribution (to meet additional energy demand of about 700 TWh) in the Arab countries could
exceed $450 billion by 2020. 45 Mobilizing such levels of investment poses a huge challenge for
the Arab countries, particularly considering the poor financial condition of many of the
incumbent utilities.
                   Figure 2.28 Supply/demand balance without regional planning
      350000

      300000

      250000

      200000                                                                   Peak Demand

      150000                                                                   Installed Capacity in 2010
                                                                               Additional Capacity Needed
      100000

       50000

            0
                             2010                        2020

Source: T he LAS and various World Bank reports.

Regional integration could provide significant assistance in this regard as demand profiles across
countries differ and peak demands are not coincidental. If it is assumed that global coincidental


45
  Based on estimates for Egypt’s expansion plan of approximately $101 billion to meet 150,000 GWh of demand growth
(October 10, 2008, World-Bank-sponsored report, Energy Cost of Supply and Pricing Report ).



                                                       76
peak demand is 10 percent below the sum of the peak demands in each country, there would be a
reduction of 31 GW in required generation capacity by 2020 (see figure 2.29).
                Figure 2.29 Supply/demand balance with regional planning
     300000

     250000

     200000
                                                                   Peak Demand
     150000
                                                                   Installed Capacity in 2010
     100000                                                        Additional Capacity Needed

      50000

          0
                       2010                    2020

In addition, enhanced interconnections across the Arab countries and increased electricity trade
would reduce the share of expensive fuel oil and gas-oil in favor of more competitive and clean
natural gas, assuming natural gas is available. For instance, Qatar, a country abundant with
natural gas resources, could sell gas-fueled electricity to Kuwait or Saudi Arabia, which would
save large amounts of oil for more value-added sectors. Similar opportunities exist in the
EIJLLPST countries. For example, Egypt has significant amounts of gas generation that could be
used to displace oil generation in places such as Syria.
A simulation was performed on Morocco, Algeria, and Tunisia to quantify the benefits of
increased trade among the three countries. Utilities dispatch their generation according to
economic merit, so the units with the lowest production costs are used as much as possible while
higher cost units are brought online only when load increases during peak periods of demand.
The current generation mix with no electricity exchange between the countries is shown in figure
2.30. Using Matlab, a linear-programming software package, optimal dispatch among the three
countries is solved with energy freely exchanged between the countries to minimize production
costs for the region, assuming no capacity constraints. The resulting generation mix is shown
figure 2.31.
       Figure 2.30 Morocco, Algeria, and Tunisia current generating mix in MWh




                                              77
Note: Imports from Spain are not included. MWh = megawatt-hour.
 Figure 2.31 Morocco, Algeria, and Tunisia optimized generation mix (regional dispatch)




In the case of regional economic dispatch, natural-gas-fueled generation in Algeria and Tunisia
would substitute oil-fueled generation in Morocco, increasing the share of natural gas in the
global generation mix from 74 to 80 percent, while oil-fueled electricity would become
negligible. Algeria and Tunisia would become net exporters of electricity, while Morocco would
become a net importer (3 TWh,46 or 1,000 MW on average over 8 hours per day). This is
equivalent to annual savings estimated at $300 million.
Existing/committed and potential electrical interconnections between Arab countries are
summarized in figure 2.32. It is anticipated that the EIJLLPST and the GCC regions will
ultimately be synchronized with the ENTSO-E.

46
     T his is in addition to the current 4.6 T Wh import from Spain.



                                                                 78
  Figure 2.32 Existing/committed and potential interconnections among Arab countries


                    EU Electricity
                                                                             Turkey
                      Markets
                                           Italy            EIJLLPST
                                                         Interconnection

                              Under
                           Consideration                              Lebanon         Syria
                                                                                                      Iran
      Spain

                                                                              Jordan      Iraq
                                                          Libya Egypt

  Morocco               Algeria            Tunisia

       Maghreb                                                                  Kuwait           Bahrain
   Interconnection

   Mauritania                                           Under                                      Qatar
                                                     Consideration               KSA
           400 kV
                                                                     Sudan
          220 kV
          150 kV                                                 Yemen                             UAE
          90 kV
          66 kV                                                  Djibouti
         Existing                                                                                  Oman
                                                                 Somalia
         Not operational/Island operation                                              GCC
         Under-consideration,-study,-construction                Comoros         Interconnection


Note: Medium voltage interconnections between Jordan and West Bank e and between Egypt and Gaza exist and operate in
island mode. - Source: The World Bank

Regional electricity market initiatives in the neighboring regions of Europe, Turkey, Iran, the
NBI, and the WAPP provide valuable lessons learned for the regional integration of electricity
markets in Arab countries. Further, these neighboring regions represent potential trading
partners, so their electricity market designs influence regional market integration initiatives in
the Arab countries.
Europe’s REM design has been evolving over the past 14 years, and will continue to evolve in
the future. It has a huge regional market with robust trade among numerous market participants.
Joining the EU market would vault the electricity sectors of the Arab countries to world-class
status with its attendant economic benefits. Europe also provides a market for potential RES
developments being pursued by many of the Arab countries.
Turkey is expected to join the EU electricity market in 2012. This would pave the way for the
EIJLLPST countries, and potentially the GCC through the proposed Saudi Arabia – Egypt
interconnection, to synchronize and join the EU market in the future.
A new interconnection that is under consideration between the UAE and Iran could open the
door to electricity trade between Iran and the GCC. Iran also provides a gateway to further trade
through its international interconnections with Armenia, Azerbaijan, Turkey, Turkmenistan,
Afghanistan, Pakistan, and Iraq.

                                                            79
The EAC is promoting the EAPP, along with several potential new hydropower projects and
interconnections. This would facilitate trade among Ethiopia, Sudan, Kenya, and Egypt, and
through Egypt to the rest of the EIJLLPST and Arab REM.
In the WAPP, a number of transmission interconnection projects are either under way or in the
planning stages. As Mauritania already shares generation and transmission facilities with some
of the WAPP countries, and is considering interconnection with Maghreb, the WAPP could
ultimately become integrated with Maghreb and the rest of the Arab regional market.




                                             80
3      The Context for Regional Electricity Trade
This chapter covers the context for regional electricity trade, including the benefits of developing
and implementing regional electricity markets (REMs) and the challenges and lessons learned
from attempts to establish REMs elsewhere in the world. Several sections address efforts to
develop large-scale renewable energy projects in the Arab countries, and discuss the need to
synchronize regional power systems to support trade. The chapter finishes with a discussion of
the requirements for regional integration and trade and an assessment of the REMs in the Arab
world.
3.1    Benefits and Challenges of Integrating Regional Electricity Markets
Countries around the world are increasingly pursuing and benefitting from the integration of
national electricity markets into larger regional power markets to provide reliable, affordable
electricity to consumers. Increased cooperation in the trade of power among countries can bring
numerous benefits, including:
      Increased energy security
      Improved reliability
      Access to resources
      More efficient and effective use of infrastructure
      Economies of scale in investments
      Facilitation of financing for new investments
      Increased energy efficiency
      Greater renewable energy penetration
      Reduced environmental impact—that is, reductions in greenhouse gases
      Reduced cost of supply for consumers
At the same time, many regional electricity market (REM) development efforts around the world
are facing challenges that slow progress and reduce the benefits of regional integration. It is
important to understand these challenges when designing a strategy for increased trade among
Arab countries. The challenges include:
      Difficulty in aligning national and regional investment decisions
      Differences in regulatory environments between countries
      Limited scope of regional institutions
      Limited financing
      Changes in political framework
      Concerns about national sovereignty and energy independence
Establishing regional markets is more complex than establishing single-country markets because
the number and scope of risks increase with the number of countries involved. The technology
risks associated with electricity trade are relatively minor; generation, transmission, distribution,

                                                 81
and fuel-delivery technologies are all well developed. If tariffs reflect costs, the economic risks
are relatively minor as well, since demand is significantly increasing in all Arab countries. The
economic risks would be further reduced if power markets were more fully integrated, as this
would increase the number of potential buyers of services. But while increasing demand reduces
market risk by increasing the probability of a buyer for generation and transmission services, it
also elevates risks in that it places increasing pressure on the financial, economic, and technical
capacity of each country. Developing a regional market with regional coordination and
governance would reduce risks because it would optimize generation and transmission planning
and operations for the broader region.
Regardless of the type of regional trade, there needs to be a legal, regulatory, and governance
structure in place conducive to international trade, even if trade is only bilateral between two
countries. The participating countries must have the political will to relinquish a portion of their
energy supply responsibilities to the greater good of the region.
3.2      Experience with Market Integration
A report commissioned by the World Bank/Energy Sector Management Assistance Program
(ESMAP)47 provides a summary of lessons learned in the development of REMs around the
world. The report is based on the analysis of 12 regional power markets. The cases included in
the study cover a broad spectrum of market types, from simple bilateral trade between two
countries through multicountry trading around a set of regional rules with fully integrated
competition. The findings of the report indicate that:
        One size does not fit all. The circumstances under which regional markets are being
         developed vary enormously. Countries have diverse motivations, electricity sectors are at
         different stages of reform and development, financial capabilities and levels of openness
         to private sector involvement differ, and social and environmental impacts vary. As a
         result, the approach to regional market development must be tailor-made to suit the
         circumstances. Political factors and the historical evolution of the regional arrangements
         are typically at least as important as the technical and economic factors. Regional market
         development is almost always a fractured process with temporary reversals as well as
         periods of progress and consolidation. The design, approach, and phasing of regional
         integration efforts must adapt to local realities with considerable room for flexibility and
         adjustment as conditions and attitudes change. There is no unique regional power market
         design, institutions, or processes, and no hard-and-fast rules about issues such as
         ownership, financing, and pricing that will ensure the success of regional integration
         efforts.
        There are various levels of regional power integration . There are many levels and types
         of regional power sector integration, ranging from simpler forms that may include only
         individual cross-border generation projects, to more advanced forms that may include
         some combination of unified multinational power markets, technical and regulatory
         harmonization, a single power exchange, high interconnection levels, regional
         coordination of investment, and competition across borders with few impediments. Full
         integration of multiple national electricity systems into an REM offers the greatest
47
  An ESMAP report prepared by the (Economic Consulting Associates (ECA) entitled “Regional Power Sector Integration —
Lessons from Global Case Studies and a Literature Review” (March 2010).



                                                         82
    benefits. However, few regions have yet achieved this —Nordpool in Scandinavia is
    probably the closest. Substantial benefits can still be achieved at all levels of regional
    market integration. Simple interconnections between national systems and one-off cross-
    border electricity trade projects can offer substantial benefits, and countries may be
    content to stay at this or other intermediate levels of integration. The time needed to
    move from no integration to full integration can be measured in decades, but moving
    from intermediate to higher levels of integration can be relatively rapid. The rate at which
    progress is made toward full power sector integration depends on many factors, including
    the institutional capacity of the participating countries.
   There are efficiencies to be gained under any integration scheme . The optimization of
    generation and transmission investment on a regional rather than a national basis can
    offer substantial cost reductions. But these cost reductions often go unrealized when
    countries follow national priorities, including domestic energy security, economic
    nationalism, and sovereignty concerns. Recognizing as legitimate and appropriately
    addressing these and other important national priorities is essential to achieving regional
    investment optimization and the full benefits of regional integration. Approaches for
    doing so will differ depending on local circumstances and the combinations of planning
    and market forces that drive investment decisions. Few, if any, regions impose mandatory
    regional planning, although several encourage the use of indicative regional plans with
    buy-in from politicians to ensure commitment. Explicit mechanisms to share benefits,
    such as allocating shares in cross-border projects, may help overcome reluctance to
    implement regional plans.
   There is a need to establish the required regional institutions . Regional institutions are
    vital for regional markets, but there is no single institutional form that is appropriate for
    all regional power integration schemes. The strongest institutions are those that grow
    organically from local initiatives rather than being imposed from outside. Opportunities
    to build on existing arrangements should be explored first before new institutions are
    created.
   Technical and regulatory harmonization should be addressed as soon as possible.
    Harmonization of technical standards is needed to avoid endangering the reliability of
    neighboring systems or loading excessive costs from one country to another.
    Harmonization of relevant economic regulations among participating countries is not a
    prerequisite for initial levels of regional integration, but is increasingly required as cross-
    border competitive power trade develops. Deepening regional integration will tend to
    require a gradual move toward uniform approaches by national regulators, creating a
    common regulatory framework for regional markets, or possibly some form of “regional
    regulator” with discretionary powers in the regional market.
   There should be a flexible approach to power sector reform. Competitive power
    markets are not a prerequisite for initial regional market integration. Different levels of
    power sector reform among participating countries can be accommodated by careful
    design of regional integration schemes. Deeper levels of integration will tend to require
    national power markets to be at similar stages of reform to address concerns that the
    benefits of integration are captured by countries where power monopolies persist.
    Competitive power markets can facilitate and complement regional market integration,


                                              83
          but can also create barriers to electricity trade due to the potential to reduce the market
          power of incumbents and added difficulties associated with financing cross-border
          projects as long-term contracting becomes more challenging.
Although each case study offers valuable lessons, there are three cases that are of particular
       interest to the Arab countries, in terms of how they have developed institutional capacity
       and processes; these include the Central American Electric Interconnection System
       (SIEPAC), South East Europe (SEE), and the Pennsylvania-Jersey-Maryland (PJM)
       interconnection. Table 3.1 provides key characteristics of these three regional markets. A
       brief description of the salient points of each experience is provided below. 48
              Table 3.1 Characteristics of SIEPAC, SEE, and PJM regional markets
     Market        Year           Number of               MW             Maximum                Trade arrangements
                                 participants                            trade (%)
SIEPAC             2010                 6                  9,700                          MER regional market
SEE                2005                 9                 43,600                 14       EU single market
PJM                1927                14                163,500                100       Multiple markets


Note: EU = European Union; MER = Mercado Eléctrico Regional; MW = megawatt; PJM = Pennsylvania -Jersey-Maryland
Interconnection; SEE = Southeast Europe; SIEPAC = Central American Electric Interconnection System.

3.2.1 SIEPAC
The large-scale development of generation projects in Central America, particularly hydropower,
can only be attained in the broader regional market, which includes, potentially, Central
America’s large neighboring systems in Mexico and Colombia. Me anwhile, six Central
American countries—Guatemala, El Salvador, Honduras, Costa Rica, Nicaragua, and Panama —
have created the Central American Electrical Interconnection System (SIEPAC), an integrated
REM, to expand international trade. The SIEPAC promises to generate efficiency gains through
economic dispatch on the broader regional level as well as shared reserves. The objective of the
SIEPAC project is to achieve potential gains from integration.
The initial feasibility study for the SIEPAC was completed in 1987. The legal foundation for the
project is an intergovernmental framework agreement known as the Marco Treaty, which was
signed in 1996 and came into effect in 1999. This treaty provides the legal basis for both the
regional market and the supporting institutional and physical infrastructure. A regional planning
organization represents the six national utilities and includes planning, advisory, and steering
groups.
The market structures among the six countries vary from fully competitive wholesale markets to
monopoly-integrated utilities acting as single buyers. Some countries have significant private
sector participation in their power sectors, while others are limited to independent power
producer (IPP) investment in generation. All countries have cross-subsidization in their tariff
structures. To accommodate the wide range of development and capacity in the national markets,
the REM known as the Mercado Eléctrico Regional (MER) has been designed as a seventh
market that operates on top of the six national markets, connecting the national markets while
remaining separate from them. The design is an attempt to allow the individual countries to

48
  T his summ ary is based on a report by ECA entitled, “T he Potential of Regional Power Sector Integration —Central American
Electric Interconnection System (SIEPAC) T ransmission and T rading Case Study,” dated March 2010.



                                                            84
develop at their own pace while enabling trade at the regional level. Gradualism is explicitly
identified in the Marco Treaty.
The SIEPAC consists of two components. The first is an REM referred to as the Mercado
Eléctrico Regional (MER), which includes a set of market rules to govern trade at the regional
level on top of trade in the national markets. The MER includes a regional regulator and a
regional transmission system operator that were specifically identified in the Marco Treaty. The
regional regulator, known as the Comisión Regional de Interconexión Eléctrica (CRIE), began
operations in 2000, and the regional system and market operator, known as the Ente Operador
Regional (EOR), began operations in 2001. The design of the MER was based on principles
enshrined in the Marco Treaty and took two years to develop before being approved by the six
governments in 2000. The CRIE and EOR have supranational legal status, granting them
independence from the six national legal systems. The regional market and supporting
institutions are now operating, and trade in the MER using the existing interconnectors is under
way, albeit at very low levels.
The second component of the SIEPAC is the construction of a new 1,800 km transmission line
from Panama in the south to Guatemala in the north. The new transmission line will increase the
transfer capacity from something less than 50 megawatts (MW) to 300 MW at all borders in the
region. The transmission route is shown in figure 3.1.
                        Figure 3.1 SIEPAC transmission line route




                                              85
Source: EPR.

Construction of the new transmission line has been delayed since its original 2008
commissioning. It is now expected that the line will be operational in 2011. It will be owned and
operated by a project company formed for this purpose. The company is owned in equal shares
by each of the six state-owned national transmission companies, the dominant state-owned
utilities of Mexico and Colombia, and a private sector partner that is managing the transmission
project.
In addition to the main SIEPAC line, an interconnection between Mexico and Guatemala is
under construction. A southern extension of the SIEPAC line is also under study, which would
interconnect the SIEPAC with Colombia.
3.2.2 SEE
Combined with the potential for future European Union (EU) membership, Albania, Bosnia and
Herzegovina, Bulgaria, Croatia, Kosovo, Macedonia, Montenegro, Romania, Serbia, and the EU
signed the treaty establishing the Energy Community in 2005. 49 A study commissioned as part of
49
   Bulgaria and Romania have since become EU members; Kosovo is not universally recognized as an independent country —the
signatory in 2005 was the United Nations Interim Administration Mission in Kosovo (UNMIK) pursuant to the UN Security
Council Resolution 1244.



                                                          86
the regional power integration process determined that the least-cost investment in generation
and transmission in southeast Europe (SEE) would achieve savings of €3 billion in the period
between 2005 and 2020. 50 There are numerous potential benefits from increased electricity trade
in the SEE region, owing to:
       Coordination of a regional least-cost investment plan, particularly in SEE where
        investment requirements are substantial due to growing demand and old and inefficient
        generation and transmission infrastructure
       Many of the countries in the region being small and only able to reap economies of scale
        through exports to a broader regional market
       Power exports that provide a significant source of revenue in some countries
       Enhanced security of supply and economic efficiencies from cross-border trading
The treaty establishing the Energy Community was the last of a number of documents forming
the REM in SEE. The first agreement was the Thessaloniki Declaration in 1999, signed by
Albania, Bosnia &Herzegovina, Macedonia, Bulgaria, Romania, Greece, and the EU. The
Thessaloniki Declaration established the objectives of the REM and targeted 2006 as the initial
year of operation. But the declaration failed to identify steps for practical implementation, and
made no reference to the EU, and was replaced by the Athens Memorandum of 2002. The
signatories to the Athens Memorandum included the Republic of Albania, Bosnia &
Herzegovina, the Republic of Bulgaria, the Republic of Croatia (to sign later), the Hellenic
Republic, the of Romania, Turkey, the Federal Republic of Yugoslavia, the Former Yugoslav
Republic of Macedonia, and the United Nations Interim Administration Mission in Kosovo
(UNMIK).
The Athens Memorandum includes a detailed blueprint of what each party must do to prepare for
a regional market, and an approximate timetable. The European Commission, in conformance
with the legal constraints of Article 300 of the EC Treaty, obtained a negotiating directive from
the council in May 2004 to conclude a legally binding agreement, the Energy Community
Treaty, with essentially the same content as the two memoranda. The Energy Community Treaty
was signed in Athens in October 2005 and came into force in July 2006.
The Energy Community Treaty established government-level institutions supplemented by
regulatory and technical working groups. The primary features of the regional power integration
process in SEE include:
       Competition, over time, in wholesale and retail supply
       A common regulatory framework with independent national regulators
       Functionally and financially unbundled transmission system operators (TSOs)
       Unbundling of previously vertically integrated utilities
       Establishment of a regionally integrated network linked to the wider EU network,
        including a common set of rules governing generation, transmission, and distribution

50
    REBIS, Generation Investment Study (the GIS study) undertaken under the EU CARDS framework:
http://siteresources.worldbank.org/INT ECAREGT OPPOWER/Home/20551044/Volume%201%20 -%20Exec%20sum_final.pdf.



                                                    87
        Coordination of regional planning and facilitation of competitive investment; the treaty
         itself does not mandate investment
The various treaties led to the following organizational structure to develop the regional market
      in SEE:
        A ministerial council to lead the effort, making strategic decisions
        A permanent high-level group (PHLG) to support the ministerial council and ensure its
         smooth operation
        A regional energy community secretariat (residing in Vienna) funded out of the EU
         general budget as a separate legal body to serve the ministerial council and PHLG
        The South East Europe Electricity Regulation Forum to coordinate the expertise of two
         working groups, including:
                          The SEE Energy Regulators Work Group that manages the regulatory
                           aspects of market coordination
                          The SEE Transmission System Operators Work Group that manages the
                           technical aspects of market coordination
A new body has been created to replace the woringk groups, and is known as the Energy
Community Regulatory Board (ECRB). It provides a cross-border dispute board, but also plays
the role of advisor to the ministerial council and PHLG on statutory technical and regulatory
rules. It has extended its role to establish working groups, which can coordinate development
work.
Progress toward meeting the objectives of the Energy Community Treaty has been substantial.
Each country has been resynchronized with the European Network for Transmission System
Operators for Electricity (ENTSO-E),51 and has established institutions and working groups that
can call on the support of industry players through organizations such as the ENTSO-E and that
provide benchmarking and monitoring processes to measure progress against commitments
under the Energy Community Treaty. A compensation mechanism for cross-border transmission
has been developed to share revenues from cross-border trade among the transmission providers,
based on EU principles. Independent regulation and transmission system operators (TSOs) have
been formed, and progress has been made toward development of independent distribution
network operators in most countries. The status of progress in 2006 toward achieving the goals
of the treaty is summarized in table 3.2.
                  Table 3.2 Progress toward power market development in SEE




51
  Driven by the Union for the Coordination of T ransmission of Electricity (UCT E), which imposed a unified operational
handbook on the different transmission system operators (T SOs) and undertook all necessary testing.



                                                         88
Source: “World Bank Framework for Development of a Power Market in South East Europe,” March 2006.

Countries are following parallel paths to harmonize rules governing national markets; each
country is adopting the EU Directives and establishing market rules that permit competition. The
goal to integrate the national markets into a broader, single regional market for wholesale trading
has not yet been reached, but progress is being made in the sense that simultaneous allocation of
all cross-border transmission capacity in the region is being tested.
Although progress has been made to integrate SEE into a single regional market, much work
remains. Current plans are focused on continued progress toward achieving the goals stated in
the EU Directives, including market opening (all consumers must have a choice of supplier),
transparency, nondiscriminatory pricing, and development of the following:
        A coordinated transmission plan
        Competitive cross-border trading arrangements to replace bilateral deals between the
         incumbent utilities, which limit competitive access to consumers
        Regional balancing capability
        A day-ahead regional power exchange
        An integrated cross-border congestion management system to determine congestion costs
         and maximize cross-border transfers
3.2.3 PJM


                                                         89
The Pennsylvania-Jersey-Maryland (PJM) interconnection started as a fully regulated power pool
in 1927. The objective was for the member utilities in the states of Pennsylvania, New Jersey,
and Maryland (which joined in 1956) to share generation resources to improve efficiency and
minimize investment in generation and transmission capacity. While the utilities in the three
states were the beneficiaries of the power pool, the benefits were ultimately extended to
consumers and shareholders. Over time, the power pool was expanded to utilities in other states
in the Mid-Atlantic region.
The 1973 energy crisis caused the federal government to rethink energy policy, resulting in
establishment of the Federal Energy Regulatory Commission (FERC) to act as the regulator of
interstate energy commerce. Open access was subsequently introduced, leading to the advent of
independent power producers (IPPs), which increased demands on the PJM power pool.
Ultimately, the FERC introduced full wholesale competition and the concept of independent
system operators (ISOs, and subsequently, regional transmission organizations, or RTOs), and
forced utilities to transfer control, but not ownership, of the transmission system to the newly
created ISOs and RTOs. The PJM interconnection formally gained RTO status in 2002. It
extended its control over transmission to the west later, in 2002, and to the south and west in
2004. Expansion of the control area highlighted the importance of longer-distance transmission
development and the desire to increase economic gains by combining smaller markets into larger
regional markets with economic dispatch promoted through competitive bids across the entire
region.
The initial power-pool arrangement of this interconnection was sought to deliver least-cost
dispatch of the mix of generation owned by the utilities in the PJM. With expansion both
geographically and through the addition of IPPs, the PJM evolved to become independent of its
utility owners in 1993 and became a not-for-profit limited-liability company in 1997. The PJM’s
current management structure is a two-tier arrangement with a management board supervising
day-to-day operations and reporting to an elected Members Committee. The Members
Committee is arranged by constituency and includes representation from each member interest
group including generators, transmission owners, distributors, traders, and consumers.
The PJM board includes nine voting members and a president. The board is responsible for
maintaining system reliability and for ensuring that the markets are competitive. The board is
also responsible for operational matters. Members of the board must be independent of any party
that has signed the PJM operating agreement. The Members Committee elects board members
from candidates proposed by an independent consultant.
The PJM members can trade bilaterally or can self-supply. The PJM operates additional markets
for energy, capacity, and ancillary services. The markets are monitored by an independent
market-monitoring company that ensures effective competition and thus protects the interests of
all market participants. The primary markets operated by the PJM include:
      A day-ahead market in which hourly locational marginal prices (LMPs) are calculated for
       the next operating day based on generation offers and demand bids in a day-ahead
       auction. LMPs reflect the marginal cost of production at different nodes when constraints
       arise on the transmission system.
      A real-time energy market in which a spot market during the day determines LMPs
       separately from day-ahead LMPs.


                                              90
      A capacity market for capacity up to three years into the future, which secures capacity
       commitments from generators through competitive auctions.
      A financial transmission rights (FTRs) market where market participants can participate
       in an auction to secure payments to hedge their exposure to locational marginal pricing.
       FTRs pay out differences between the prices at the entry and exit nodes of specific
       transmission paths.
The PJM offers two types of transmission services: (i) network services allowing any market
participant full access to the transmission system for a monthly fee, charged according to usage,
and (ii) point-to-point firm and nonfirm services for specific bilateral contract routes from
generators to loads.
The PJM dispatches about 163,500 MW of generating capacity over 56,350 miles of
transmission. Since the opening of the regional wholesale market in 1997, the PJM has
administered more than $103 billion in energy transactions. The PJM delivers about 700
terrawatt-hours (TWh) of energy per year and serves utilities in 13 states and the District of
Columbia.
The PJM plans to expand its area of operation by cooperating with neighboring systems in New
York and the Midwest. Locational marginal pricing was initiated in 1998, providing price signals
for the location of generation and demand-side technologies, as well as for transmission
investment. In 2007 the PJM initiated operation of its reliability pricing model as an auction for
forward commitments to deliver new generation and transmission. It is modeled to reward
development in energy-deficit areas, signaling that LMP pricing, by itself, is not enough to
promote development of adequate generation and transmission to ensure reliable operation of the
system.
3.3    Evolution of the EU Electricity Market
The evolution of the EU electricity market also has valuable lessons to offer. Changes in the
European electricity industry have been imposed over the past 14 years through a number of
legislative directives with the objective of ensuring the security and economy of electricity
supply though the promotion of a functional and competitive integrated REM in Europe. The
focus of the directives has been on unbundling the monopoly elements, mainly the network
operation from the other functions, ensuring third-party transmission access, independent
regulation including oversight of cross-border exchanges and trade, and the opportunity for all
consumers to choose their supplier. A detailed summary of the EU legislation relating to gas and
electricity reform is provided in attachment 3.A, while an overview of the EU electricity market
design is provided in attachment 2.C. As experience in Europe suggests, gas sector deregulation
and reform is an important element of the electricity reform process: gas has become the fossil
fuel of choice for electricity generation, owing to its environmental benefits relative to other
fossil fuels.
The first package of directives included Electricity Directive 96/92/EC, issued in 1996. This
granted the largest consumers the right to choose suppliers and provided for open access to the
transmission grid, although without a regulated access framework. It required the unbundling of
the transmission-system operation function from the vertically integrated utilities through
accounting separation. It also introduced the concept of a single buyer as the sole supplier in a
specific domain.

                                               91
To accelerate reform and improve the provisions relating to access and regulation, a second
package of directives was issued in 2003. This included the Electricity Directive 2003/54/EC and
the Regulation Directive 2003/1228/EC. The former required a stepwise opening of the retail
market with a target for full market opening by July 2007, and made the unbundling provisions
stricter by requiring legal separation (establishing a separate company), or full ownership
unbundling of TSOs to ensure they operate independently from generation and supply interests
to enable fair and open access to the transmission grid. 52 In addition, establishing independent
regulators was made mandatory.
The regulation directive dealt with cross-border electricity trade, providing for:
        Market-based allocation of transmission capacity
        Collection of congestion rents from transmission-capacity auctions to be used to fund
         projects to eliminate bottlenecks in the grid
        Calculating in a transparent and nondiscriminatory manner the available transmission
         capacity based on real physical bottlenecks
Various subsequent reviews, however, found that electricity markets largely remained national in
scope and continued to have high levels of market concentration. The level of unbundling was
found to be inadequate and the limited cross-border transmission capacity constrained trade and
competition across borders. There was a lack of transparent and reliable market data and timely
price information to foster competition. The markets tended to favor the incumbents.
These reviews led to the third package of directives in June 2009. Full retail-market
liberalization had been achieved ahead of the target date of July 2007. The wholesale electricity
market evolved gradually, encouraged by progress in sector unbundling and increasing
transmission access. A review of the wholesale market prices (day-ahead spot prices) in select
exchanges (such as EMEL in Spain, APX in Great Britain, EEX in Germany, and so on) between
January 2005 and January 2008 showed some convergence of prices, but scope for improvement
remained. Market liquidity increased substantially, with traded electricity volumes in the United
Kingdom, Germany, the Netherlands, and the Nordic markets up to six times national
consumption levels.
Although full retail-market opening was achieved well before the target date of July 2007, only
three countries saw more than 5 percent of small consumers switch suppliers, with levels much
lower in other countries. Switching of suppliers for large consumers was much greater, with
more than 50 percent switching suppliers in 7 countries, and more than 15 percent switching
suppliers in another 16 countries.
This third package of directives seems to be having a positive impact on prices. Figure 3.2 shows
the daily arithmetic average spot prices in Euros/megawatt-hour (MWh) in the various European
power exchanges for the period December 26, 2009, to January 25, 2010. The degree of
convergence in prices among the various exchanges appears to have improved.



52
  More than half of the EU member states have chosen to fully unbundle T SOs through ownership separation. According to the
Commission, only 16 countries (including Norway) had unambiguously and effectively implemented unbundling requirements
for transmission system operation in 2005.



                                                            92
   Figure 3.2 Daily arithmetic average spot electricity prices in European power exchanges,
                          December 26, 2009, to January 25, 2010




Source: www.europex.org/default.asp?kaj=markets.

The European transmission network is highly meshed. Though developed with a national focus,
its interconnections allow robust system operation across the main synchronized blocks and
significant exchange of power across national borders. The network has long been facilitated by
international organizations, including the Association of European Transmission System
Operators (ETSO), which focused on facilitating an internal competitive European electricity
market and on the market rules and harmonization needed to make it work, and the Union for the
Coordination of Transmission of Electricity (UCTE), which coordinated the interconnected,
synchronized operation of 29 TSOs from 24 countries in Europe.
For over 40 years, compliance with the UCTE rules was voluntary, relying on the common
interests of all members in maintaining secure operations of the synchronized grid. But a
network failure in 2003 (when supply to Italy was temporarily lost) led to a realization that
system security had become more complex. By then, the UCTE had also grown geographically,
and members’ interests had become less homogenous. The UCTE produced an operational
handbook that codified all its regulations, and in 2005 each member country was required to sign
a multilateral agreement as a condition of membership. This agreement obliged each member to
adhere strictly to the operational handbook, especially in relation to frequency control,
scheduling and accounting, operational security, coordinated operational planning, emergency
procedures, communication protocols, data exchanges, and operational training. In 2007
compliance monitoring and enforcement processes (CMEP) came into operation. This enabled

                                                   93
the UCTE to gather all relevant information on compliance with the operational handbook and
impose penalties or remedial measures on transgressors. Enforcement was on a contractual rather
than statutory basis.
The third package of EU directives created the ENTSO-E, which came into existence in mid-
2009 and absorbed the UCTE, the ETSO, and similar organizations such as UKTSOA,
NORDEL, BALTSO, and ATSOI. 53 The ENTSO-E has a wider mandate than the UCTE,
including a specific legal role and powers.
The EU continues to modify and refine its electricity market model. The Commission has
proposed a Europe 2020 Strategy that includes promotion of a “resource -efficient Europe,”
which incorporates the 20-20-20 targets on greenhouse gas emissions, renewable energy, and
energy savings. It also requires completing the internal energy market and implementing the
European Strategic Energy Technology Plan (SET-Plan).
To summarize, the EU electricity market design has progressed over the past 14 years through
legislative directives designed to further market reform and improve competition. The market
will continue to develop in the future through additional proposals aimed at strengthening
competition. The EU electricity-market design is characterized by full retail competition (all
customers have the right to choose their supplier), legal unbundling of the transmission system
operator, freely negotiated bilateral contracts between buyers and sellers supported by a
competitive balancing market to settle differences, fair and open access to the transmission
network, and full compliance with the ENTSO-E standards and directives. While a fully
integrated regional market has not yet been attained, progress is being made through market-
based allocation of cross-border transmission capacity with the use of auctions to eliminate
bottlenecks and calculate available transmission capacity in a transparent and nondiscriminatory
manner.
3.4      Renewable Energy Development in the Arab Countries
3.4.1 Potential
There is huge potential for wind and solar energy development in the Arab countries, estimated
by the firm Frost and Sullivan to have a potential to generate 630,000,000 MW (630 TW) of
solar power and 75,000 MW of wind power. Unlike oil and gas, wind and solar energy are more
evenly spread across the countries; this presents a unique opportunity for further regional
integration as an instrument for enhancing economic growth and reducing poverty. For oil and
gas importers, renewable energy would provide energy security, whereas for oil and gas
exporters, it frees up fossil fuels for higher value-added usage and exports.
For example, Morocco has estimated the country’s wind potential at 25,000 MW (see figure 3.3)
with some sites such as Tarfaya having a load factor exceeding 40 percent, which is attractive to
private sector investors. Some of the world’s best wind power resources are in Egypt, in the area
of the Gulf of Suez, where at least 7,000 MW can be developed by the year 2020, and the East
and West banks of the Nile, where a further 3,000 MW can be developed. Solar power in the
United Arab Emirates (UAE) has the capability to outdo U.S. and European targets of producing


53
   T hese are organizations similar to the UCT E for the United Kingdom, Nordic countries, Baltic countries, and Ireland,
respectively.



                                                          94
20 to 30 percent of energy from renewable sources by 2020 (according to Suntech Power, the
largest manufacturer of solar panels in the world).
                              Figure 3.3 Morocco’s wind atlas




The prospect of exporting green energy to Europe at high prices further enhances the Arab
nations’ renewable energy potential. This is particularly relevant for the Maghreb region, which
is already synchronized with Europe —exports of green energy to Europe could become an
important and reliable source of revenues for these countries (see figure 3.4). This vision is in
tandem with the Desertec concept, which would provide Middle Eastern, North African, and
European countries with a sustainable supply of renewable energy by 2050. The Desertec
concept inspired the design of the Mediterranean Solar Plan, one of the six pillars of the Union
for the Mediterranean, which aims to develop 20 gigawatts (GW) of renewable energy (mainly
solar), with 5 GW to be exported to Europe.
                              Figure 3.4 Global solar potential




                                               95
                                                   Favorable for Concentrated Solar
                                                   Power (CSP)
                                                   Worth considering for CSP
3.4.2 Renewable Energy Projects and Initiatives in Arab Countries
Most Arab countries have only a modest share of renewable energy in their generation mixes.
Egypt, Morocco, and Syria have some renewable generation, but the share is less than 10 percent
and is composed mostly of hydropower. Sudan and Mauritania, with a 20– 25 percent share of
hydropower in their generation mixes, are exceptions, although their respective power systems
are small relative to other Arab power systems.
Nevertheless, some renewable projects (or projects with a renewable component) have emerged
recently in the region, paving the way for more diversified sources of renewable energy in the
future. Algeria, Egypt, and Morocco have developed integrated solar combined-cycle plants each
with a solar component (parabolic trough) ranging between 20 and 30 MW. These projects were
financed partially by the Global Environment Facility through a grant, and have either become
operational in the past year, or are expected to become operational shortly.
Several wind projects are also being developed in the Arab world:
      Egypt plans to develop 7,200 MW of wind capacity by 2022. A 3,000 MW wind project
       with associated transmission infrastructure was approved last year by the World Bank
       and endorsed by the Clean Technology Fund.
      Morocco has already installed 280 MW of wind turbines and has announced an integrated
       wind program that aims to increase wind capacity to 2,000 MW by 2020 by adding five
       new wind farms. This program is estimated to cost $3.5 billion and would generate about
       5 TWh per year.

                                              96
      Tunisia has installed 55 MW of wind turbine capacity.
      Algeria envisages development of 2,000 MW of wind power by 2030.
      There are other individual projects scattered across the Arab world as well.
Arguably the most prominent energy-relevant initiative in the Middle East and North Africa
(MENA) is the scale-up of concentrated solar power (CSP) throughout the region. On December
1, 2009, the Clean Technology Fund endorsed a $5.6 billion investment plan for this scale-up
with $750 million of concessional funding from the Clean Technology Fund. The investment
plan includes deployment of 1 GW of CSP in five countries in the region (Algeria, Egypt,
Jordan, Morocco, and Tunisia) and supports financing of two transmission lines —the ELMED
line between Tunisia and Italy and the reinforcement of the Jordan network on the east coast of
the Mediterranean. This initiative has a strong regional component:
      It is part of the Mediterranean Solar Plan.
      It supports associated transmission infrastructure in the Maghreb and Egypt, Iraq, Jordan,
       Libya, Lebanon, Palestine, Syria, and Turkey (EIJLLPST) for domestic supply and
       exports of green energy to Europe as a source of revenues.
      It supports development of local manufacturing of CSP components across the region,
       which would increase the industrial competitiveness of the region and derive economic
       benefits such as job creation.
      It has the potential to be replicated in Gulf countries.
Several individual projects are also in the works. Morocco plans to develop 2,000 MW of solar
energy. Tunisia plans to achieve 10 million tonnes of oil equivalent (Mtoe) of fuel savings over
the period 2005– 30, 80 percent from energy conservation and 20 percent from renewable energy.
Algeria aims at generating 20 percent of its electricity from renewable sources by 2030,
including 70 percent from CSP, 20 percent from photovoltaics (PV), and 10 percent from wind.
Egypt has committed to increasing its share of renewable energy to 20 percent by 2020 as a
means of meeting growing electricity demand and achieving the economic objective of utilizing
natural gas for higher-value purposes. Jordan, which has a keen interest in the development of
renewable generation capacity—considering that it is almost entirely dependent on fuel imports
for its energy requirements—adopted a new energy strategy in 2007 that emphasizes renewable
energy sources (RESs) and set a target of 10 percent by 2020. Syria is implementing an
ambitious wind power program and is considering development of both CSP and PV solar
projects.
Policies and reforms are necessary to spur the development of renewable generation. Laws
encouraging RESs and energy efficiency have begun to emerge in the Arab world, led by the
Maghreb region and Egypt. But one important hurdle for renewable development is the issue of
subsidized tariffs. Some Arab countries have recently made progress in this area, such as Egypt,
Jordan, and Morocco; however, larger and more consistent efforts are required to reach cost-
effective tariffs that would enable a more rational and sustainable use of energy, make renewable
technologies more competitive, and attract the private sector investment necessary to realize this
potential. The recent economic crisis has unfortunately slowed down these efforts.
3.4.3 Gulf Countries Enabling Research


                                                 97
New institutions established in the Gulf countries, in partnership with U.S. and European
institutions, have directed energy research on topics relevant to the region. A few examples are
listed here among the many projects within the Gulf Cooperation Council (GCC) countries:
      The Gulf Research Center (GRC) in the UAE, in association with the Institute of
       Communications and Computer Systems of the National Technical University of Athens
       (ICCS-NTUA), is working to establish a permanent network of institutions from the GCC
       and EU to act as catalysts to coordinate and develop cooperation on clean energy and
       related policy and technology needs among various stakeholders in the EU and GCC
       countries.
      Masdar Sustainable City is producing its electricity through solar-power complexes.
       Masdar Institute of Technology (in cooperation with the Massachusetts Institute of
       Technology) is pursuing advanced research in areas of energy efficiency and renewable
       energy, tackling hybrid solar thermoelectric and PV conversion at low cost and high
       efficiency, examining energy generation from waste, and improving the efficiency of
       building cooling systems.
      The UAE is now hosting the newly established International Renewable Energy Agency
       (IRENA), a step that may encourage other Arab countries to engage more fully in
       renewable energy generation.
      At King Abdulaziz City for Science and Technology (KACST) in Saudi Arabia, the
       Energy Research Institute has launched the Middle East Energy Efficiency Research
       Center, which aims to promote more efficient use of energy in technology devices
       through conducting and sharing research with leading universities across the Middle East.
      King Abdullah University of Science and Technology (KAUST) identifies energy
       research as one of its strategic research thrusts. It has established the Clean Combustion
       Research Center, the Solar and Alternative Energy Science and Engineering Research
       Center, and the Water Desalination Research Center.
      King Abdullah City for Atomic and Renewable Energy has been established to promote
       the application of renewable technologies (wind and solar) as part of the future
       generation mix in Saudi Arabia.
3.4.4 Regional Integration to Enable Greater Levels of RES Penetration
Scaling up variable renewable energy technologies at the utility level could pose short-term
operational challenges to transmission systems. Renewable power sources such as wind and solar
are inherently variable, and current technologies are less easily controlled than traditional power
sources. Given that power output from RESs varies “naturally” (that is, depending on sunlight or
wind conditions), these provide secure quantities when considered over long periods, but not
necessarily as and when needed.
Even though transmission companies and system operators have always dealt with uncertainty
and limitations in operating power systems, these new technologies have brought two new
dimensions to short-term power system operations. First, power output from RESs can change
drastically, within minutes, requiring scheduling functions to quickly respond by pooling other
generation sources and reserves to maintain the balance between supply and demand. As the
number of variable sources in the power system increases, the operational challenges multiply.

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Second, variable renewable generation technologies such as wind and solar do not have the same
voltage- and frequency-control capabilities as traditional power sources. To maintain the
performance of these technologies while maintaining system stability, special electrical-
interconnection norms have been developed and continue to evolve; these include upgrading
conductors on existing lines, installing reactive compensation devices to improve voltage
performance, phase-shifting transformers to control sharing of power among circuits, and so on.
In addition, any storage system (pumped storage, chemical storage, and so on) can work in
tandem with RESs since it allows storing the energy when an RES is at its highest levels of
output and delivering the energy to the system when demand is high.
Regional integration is a cost-effective approach to resolving intermittency issues. Enhanced
interconnection of electricity systems provides a larger, more diverse (and thus more reliable)
generation portfolio that utilities can tap to meet their demand, increase reliability, and obviate
the need for backup power. Not only does regional integration result in substantial economic
savings (operational and investment), but also enables the addition of a higher share of RESs to
the interconnected grid. Furthermore, scaling-up renewable energy technology manufacture on a
regional basis, rather than on a country-by-country basis, will allow economies of scale to be
realized.
3.5    Synchronization
Technical requirements relating to transmission infrastructure and synchronization necessary to
support regional integration of the Arab countries are being addressed in a parallel study being
undertaken by the League of Arab States (the feasibility study). For this reason, they are not
addressed in detail in this study, which concentrates on the institutional and regulatory
framework. But to complete the picture, a brief discussion of synchronization and its impact on
regional integration is warranted. This section of the report discusses synchronization at a very
high level, leaving the details to the feasibility study.
Currently among the Arab countries, only Morocco, Algeria, and Tunisia are synchronized with
Europe (ENTSO-E). Efforts are under way to synchronize Libya and Egypt with the Maghreb
countries, but a test conducted in 2010 failed, concluding that additional work was needed before
full synchronization could be achieved. The GCC countries are synchronized with one another,
but not with any power systems outside of the GCC owing to the absence of international
interconnections. In EIJLLPST, Libya, Egypt, Jordan, and Syria are synchronized with one
another, but not with the other EIJLLPST countries, and not with Turkey. As noted earlier,
Turkey expects to be fully synchronized with Europe in early 2012.
The interconnected systems of Maghreb, EIJLLPST, and the GCC must be synchronized if the
full benefits of electricity trade are to be realized. A synchronized power system consists of
multisystem operators synchronously interconnecting their power grids during normal
operations. Operators are obliged to maintain a common system frequency during steady-state
conditions. Operators are mutually dependent and coordinate with a central control center that
oversees system operation for the entire synchronized area. Normally, a common coordinating
body is created to assure adherence to agreed technical rules and standards. This body supports
close coordination between the operators to maintain system stability during normal and
abnormal operating conditions.
Synchronization can be a complex and lengthy process, requiring a high level of commitment to
manage costs and mitigate associated risks. The dominating risk is the likelihood of cascading

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failure due to an outage that leads to overloading on some part of the system and subsequent
failures expanding into other systems. Such failures can jeopardize the synchronized system, so
all system operators must explicitly commit to adherence to technical standards and procedures.
This is enforced through legally binding agreements among the system operators. Generally, the
rules of a synchronized power system cover energy-exchange codes such as system security
standards (voltage control, frequency control, and reserve/capacity requirement), procedures for
maintaining system stability, scheduling and settlement rules, and rules for coordination of
planning.
The objectives of synchronization often evolve over time and therefore require consistent
cooperation and flexibility among the participants. A relevant example to this study is the UCTE
(since replaced by the ENTSO-E) in continental Europe. The UCTE was established in 1951 to
coordinate the operation and development of transmission networks and generation. In 1999 the
UCTE was redefined with a primary objective of committing to technical and operation
coordination of a synchronous system to ensure reliable electricity supply across continental
Europe. The ETSO was created in the same year to concentrate on market-related issues within
the synchronous system. A major network failure in 2003 that started in Italy highlighted
deficiencies in TSO coordination leading to a need for better-quality harmonization of
operational practices within the UCTE. Thus in 2005 technical standards were enforced through
an operational handbook and became legally binding through a multilateral agreement between
its members. The UCTE synchronous area comprised 29 TSOs operating across 24 member
countries in addition to other nonmember countries that were synchronized with the UCTE
region. In response to the complexity of coordinating numerous electricity bodies, the European
Commission adopted in 2007 the so-called Third Legislative Package, which included a proposal
for establishing a new European Network for Transmission System Operators for Electricity
(ENTSO-E), and another proposal for establishing the Agency for the Cooperation of Energy
Regulators (ACER). The ENTSO-E became operational in 2009 through 42 European member
TSOs in 34 countries. It replaced all formerly existing TSO associations including the ATSOI,
BALTSO, NORDEL, UCTE, ETSO, and UKTSOA. The ACER will be operational in 2011.
The Third Legislative Package also requires the ENTSO-E to develop new network codes that
overcome the limitations of the Operation Handbook (a complete discussion of EU legislation
relating to electricity sector reform is provided in attachment 3.A). These limitations are relevant
to the inability to establish binding rules (for example, network access and economic rules) for
grid users at the national level such as power plants, consumers, and distribution that could be
potentially affected by grid operations. Such limitations can be addressed at the national level
(for example, grid codes, laws) as the scope of the Operation Handbook is only binding on
TSOs. Thus, Article 8 (6) of Regulation (EC) 714/2009 binds the ENTSO-E’s network codes on
all those affected by the grid to ensure secure system operations in the synchronous areas and
efficient market integration toward a successful internal electricity market.
Experience demonstrates the benefits and challenges of synchronization. Synchronization
requires the willingness of system operators (and governments) to support the synchronization
process by taking the necessary actions to develop their network and generation capacity,
develop markets in a transparent manner, enhance their institutional framework, and advocate
electricity trade. Benefits of synchronization include:
      Cooperation in investment planning . Investment planning can be coordinated at the
synchronized-system level (with sufficient national collaboration) to justify the elimination (or

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deferring) of investments in generation or transmission. The common coordinating body is
authorized to oversee development and expansion in the synchronized area. This requires a very
high level of cooperation between the system operators. But in regionally synchronized systems
such as the ENTSO-E, the full delegation of powers to enforce regional investment plans has
been a complex task that has not yet been fully achieved because of the superseding impact on
national plans.
       More efficient operational planning. Key operational tasks can be jointly managed
between the operators of the synchronized system to achieve mutually desired system reliability
levels (adequacy of supply to meet demand and system security) and quality of supply. These
tasks include maintenance planning, capacity and energy balancing arrangements, frequency and
voltage control, reserve provisions, congestion management, and management of system
operating conditions.
       Cost reduction. An overall cost reduction can be achieved through the utilization of low-
cost generation sources to meet demand (through economic dispatch), and joint contribution of
reserves by system operators. Synchronization alone will not accomplish these cost reductions as
witnessed by the fact that Egypt, Jordan, and Syria are synchronized yet use of the
interconnections between the countries is far from optimal.
       Trade facilitation. The autonomous operation of the synchronized system, which is
carefully coordinated between system operators, facilitates electricity trade (capacity, energy,
and ancillary services) through several market mechanisms such as the spot market, day-ahead
market, and auctions. These mechanisms enable competition in cross-border trade and can enable
energy swaps between system operators or beyond. Realizing these benefits requires a high level
of trade volume, which entails complex transactions and settlement arrangements. Therefore,
close coordination and transparent data and information are critical to the success of the market.
       Harmonization. In a synchronized system, harmonization of technical standards is
required to maintain system reliability and efficient market operations. Harmonization
contributes significantly to facilitating competitive cross-border trade in a synchronized system
and in streamlining the flow of private sector investments in national and regional projects. The
most relevant areas of harmonization that need to be realized through the synchronization-
development process are technical standards, operational procedures (including grid access),
pricing and balancing arrangements, and legal procedures.
High voltage direct current (HVDC) offers a potential solution for synchronizing the Arab
countries with the ENTSO-E as it has a number of advantages over high voltage alternating
current (HVAC) solutions as it:
      Minimizes measures for addressing stability issues (frequency, voltage, and dynamic).
      Boosts the net transfer capacity and energy trade.
      Strengthens weaknesses in the transmission networks.
      Brings more certainty to interconnecting with the ENTSO-E.
      Overcomes the condition that grids of neighboring countries must be permanently
       isolated.
      Allows greater control over cross-border flows.

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          Enables interconnecting synchronous areas with different operating rules.
HVDC provides safeguards while enabling most of the benefits from AC synchronization to be
met. In any regard, HVDC, HVAC, and hybrid solutions including both HVAC and HVDC
should be considered in the feasibility study being conducted by the League of Arab States.
A complete discussion of synchronization of EIJLLPST with the ENTSO-E is provided in
attachment 3.B.
3.6        Assessment of Arab Regional Electricity Markets
The achievements and open issues of the Maghreb, EIJLLPST, and GCC regional markets are
summarized in table 3.3. In the case of EIJLLPST, with the exception of Jordan, none of the
countries have made power sector reform and regional-market development a high priority. In
the case of the GCC, it is important to note that the GCC Interconnection and the Power
Exchange and Trading Agreement (PETA) has recently been commissioned and put into
operation, so there has only recently been a physical means for trade. The fact that the GCC
countries were able to cooperate on a project as grand as the GCC Interconnection shows
promise for further regional integration and cooperation.
The main conclusion that can be drawn is that although interconnected, the regional markets
have very little trade. By interconnecting they have realized the substantial benefits associated
with reserve sharing, but have not taken advantage of energy-trade opportunities that arise when
there are differences in production costs between the national electricity markets. There has been
limited effort expended to put in place a mechanism that promotes economic dispatch from a
regional perspective, so the value of existing interconnections is far from optimal, and resources
(that is, fuel) are not being used in a sustainable manner.
                             Table 3.3 Summary of achievements and open issues
Maghreb                                         EIJLLPST                                       GCC
Achievements            Open issues             Achievements           Open issues             Achievements           Open issues
Synchronized to the     Although physically     Reasonably strong      Libya, Egypt,           Synchronized with      The GCC
EU.                     interconnected with     international          Jordan, and Syria are   strong international   connections strong,
                        the EU, trade with      connections.           synchronized.           connections within     but not with other
                        the EU limited to                              Considering further     the GCC.               regions. Connection
                        Morocco’s                                      cross-border                                   with Egypt would
                        purchases from                                 connections and                                provide gateway to
                        Spain.                                         upgrades to national                           EIJLLPST and the
                                                                       transmission                                   EU, significantly
                                                                       networks to enable                             increasing trade
                                                                       synchronization                                opportunities and
                                                                       within EIJLLPST                                potential for the Pan-
                                                                       and ultimately with                            Arab regional
                                                                       Turkey and the EU.                             market.

Reasonably strong       Considering further     Some reserves and      Mostly limited to       Progress on            Scheduled trades
international           connections with        energy sharing at      Egypt and Jordan,       commitment to          remain limited.
connections.            Europe.                 regional market        and to a lesser         regional market with   Subsidized fuel
                                                level.                 extent, Syria and       extensive              prices remain a
                                                                       Lebanon. There is       governance             deterrent.
                                                                       still no third-party    documentation.
                                                                       access or published
                                                                       tariffs for using
                                                                       transmission.

Some progress on        Progress has stalled,   Some limited           Limited primarily to    Some progress on       Progress limited, but
commitment to           although ministers      progress on market     Jordan. Independent     market reform such     still early. Abu
regional market; that   indicated their         reform such as         regulation remains      as unbundling.         Dhabi has taken
is, 2003 Protocol and   commitment to the       unbundling.            an issue. Retail                               significant steps and
2010 Algiers            regional market in                             tariffs remain                                 Saudi Arabia, Abu


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Maghreb                                         EIJLLPST                                           GCC
Achievements            Open issues             Achievements              Open issues              Achievements            Open issues
Declaration.            June 2010. There are                              heavily subsidized in                            Dhabi and Yemen
                        still no regional                                 all countries but                                all have independent
                        governance                                        Jordan.                                          regulation. Retail
                        documents or                                                                                       tariffs remain well
                        published tariffs for                                                                              below the economic
                        using                                                                                              cost of supply in all
                        interconnections.                                                                                  the GCC countries.

Some progress on        Progress has stalled.   Some regional             Jordan relies on its     Progress on regional    The GCC
market reform such      Independent             planning.                 interconnections for     market institutions.    Interconnection
as unbundling.          regulation remains                                reserves, but no                                 Authority is
                        an issue. Retail                                  planning is done                                 functioning in
                        tariffs remain below                              from the perspective                             Dammam, but acts
                        the economic cost of                              of EIJLLPST in part                              as transmission
                        supply in all                                     owing to national                                provider with limited
                        countries.                                        transmission                                     authority to promote
                                                                          network limitations.                             trade.

                                                                                                   S


Some regional           These institutions      Regional                  Although regular         ome success in          Private sector
market institutions.    appear to have little   documentation             meetings are held,       attracting private      involvement limited
                        authority, limiting     governing trade           regional institutions    sector capital to the   primarily to IPPs
                        their effectiveness.    exists in the form of     appear to have           power sector.           and IWPPs.
                                                the Interconnection       limited functionality.
                                                Agreement with
                                                regional steering,
                                                operating, and
                                                planning
                                                committees.

Some success in         Private sector          Some success in           Private sector
attracting private      involvement limited     attracting private        involvement limited
sector capital to the   primarily to IPPs.      sector capital to the     primarily to IPPs
power sector.                                   power sector.             with some private
                                                                          sector involvement
                                                                          in distribution in
                                                                          Jordan.
Note: GCC = Gulf Cooperation Council; EIJLLPST = Eight -country interconnection (Egypt, Iraq, Jordan, Libya, Lebanon,
Palestine, Syria, and T urkey); EU = European Union; IPP = independent power producer; IWPP = independent water and power
producer.

To gain an understanding of how far the Arab countries have to go to establish a REM, a number
of benchmarks relating to regional market integration are identified. These benchmarks are based
on the authors’ experience and a desk review of existing literature on international experience in
cross-border electricity trade. The benchmarks enable countries to monitor progress toward the
creation of a regional power market among the Arab countries. Progress toward meeting each
benchmark can be rated on a scale of 1 to 10, or alternatively as high, medium, or low as defined
below.
Access to markets
           Existence of spot or day-ahead market power exchange(s) open to all market participants:
            “High” if such markets exist.
Access to customers
           Actual market opening: Percentage of customers with choice of supplier: “High” if
            greater than 80 percent of customers have choice; “Medium” if between 20 and 80
            percent have choice; and “Low” if less than 20 percent have choice.

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Allocation of cross-border interconnection capacity
           Transparent process for fair and open access to cross-border transmission capacity:
            “High” if documented process exists; “Low” if no documented process in place.
           Price differentiation for use of cross-border capacity under constrained conditions:
            “High” if price differential exists determined through market-based solution; “Low” if no
            transparent price differentiation process exists.
Network tariffs and grid access
           Regulated (nondiscriminatory) third-party access to grids established: “High” if
            documented and functioning third-party access exists.
Technical
           Adequacy of interconnection capacity with other countries: “High” if strongly
            interconnected and synchronized with other countries; “Medium” if interconnections
            exist but not synchronized; and “Low” if not strongly inte rconnected.
           Meeting minimum technical standards: “High” if meeting minimum technical standards,
            that is, EU Operational Handbook; “Low” if not meeting minimum international
            technical standards.
Prices: transparency and subsidization
           Price transparency—existence of daily published market prices: “High” if market prices
            are published daily.
           Existence of regulated (energy) prices: “High” if energy prices are not regulated;
            “Medium” if regulated prices reflect cost of supply; and “Low” if regulated prices are far
            below the cost of supply.
Market structure and competition
           Market share: “High” if no generator has greater than 30 percent of market share in
            country.
           Vertical unbundling and independent TSO 54 : High if full legal unbundling.
           Explicit entity with market monitoring responsibility: “High” if such an entity exists and
            is functional, and “Low” if no such entity exists.
Balance responsibilities and balancing markets
           Balancing market established: “High” if liquid balancing market exists at national and
            regional level; “Medium” if liquid balancing market exists at national level only; and
            “Low” if no balancing market at either national or regional level.
Independent regulators, harmonization of regulations, and regional market entities
           Independent and informed regulator exists: “High” if exists with financial independence
            and reports regionally; “Low” if does not exist.

54
     Measurements should be based on legal requirements that are enforced.



                                                              104
        Harmonized licensing framework—Licensing framework meeting the basic requirements
         of the market design: “High” if exists at national and regional level; “Medium” if exists
         at national level; and “Low” if does not exist.
        Existence of regional market entities: “High” if such bodies exist and are functional;
         “Low” if they do not exist.
Using the above benchmarks one can easily observe that Arab countries have not made
electricity market reform a priority. Indeed, Arab countries have a long way to go if they are to
form a fully integrated and functional REM.
3.7      Requirements for Regional Integration and Trade
A review of global experience indicates that: (i) regional integration has taken a high profile
because of the widespread recognition of the positive outcomes for all the participating
countries; (ii) there is no evidence to suggest that any of the existing or developing schemes got
the model right at the initial stage of integration; (iii) the more successful schemes are the ones
that pursued an adaptive approach and adjusted the course when needed, and the ones that
remained persistent in dealing with foreseen and unforeseen challenges; (iv) this requirement
translates into the features of the implementation plan that needs to be developed as clearly as
possible; and (v) the establishment of powerful political support, and a strong monitoring
mechanism that can quickly bring to the attention of the decision makers the obstacles and
challenges as they emerge.
For a REM to be successful, the governance documents at the national level must allow all
market participants, regardless of origin,55 fair and open access to the transmission system. This
includes not only the transmission facilities interconnecting the national markets, but also the
transmission facilities forming the national transmission network. It requires that there be
reciprocity and a level playing field. For example, it would be unfair for one country to incur the
costs of adhering to a strict greenhouse gas emissions policy while another country bears no such
costs. There is also a need for formation of high-level institutions with the expertise and
authority to guide, and if necessary, enforce a level of consistency across the region. For
example, the ENTSO-E and ACER are institutions in Europe with the authority and expertise to
guide development of the EU electricity market.
The basic requirements for a successful REM include:
        The necessary physical infrastructure (that is, high-voltage transmission lines) must be
         available for cross-border trade.
        Harmonized technical rules for the operation of the interconnected systems and
         appropriate cooperation mechanisms among TSOs must be in place to ensure minimum
         levels of supply quality and reliability are maintained.
        There must be fair and nondiscriminatory access to the physical infrastructure, including
         transparent pricing mechanisms for use of such infrastructure.



55
   Provided the market participant can show it has the necessary expertise and financial resources to conduct the roles and
responsibilities in a manner consistent with those spelled out for the type of market participant in the governance documents.



                                                            105
      At least wholesale market rules must be harmonized (deeper integration also requires
       harmonization of rules governing retail markets).
      Suitable mechanisms for regional regulation and market supervision must be
       implemented, including enforcement procedures and dispute-settlement schemes.
      A certain degree of harmonization concerning energy taxation, as well as energy
       subsidies and incentives, must be achieved.
There is considerable potential for increased electricity trade among Arab countries, and there
are many factors that are positive for increased trade opportunities:
      High-voltage interconnecting transmission lines exist. While there are limitations —for
       example, not all Arab countries are interconnected and not all systems are
       synchronized—the interconnecting transmission lines that exist are underutilized and
       have capacity available to support increased trade.
      The power systems in Arab countries are generally small, so regional integration has
       significant value in terms of improved reliability and system security, economies of scale,
       improved opportunities for financing, increased production and delivery efficiency, long-
       and short-term reserve sharing, and overall reduced cost of supply.
      There are a number of regional integration initiatives already in place which can be
       utilized to expand trade, including the GCC, Maghreb, and EIJLLPST interconnections;
       the Nile Basin Initiative; and the joint ownership and sharing of hydroelectric generation
       and transmission capacity among Mauritania, Senegal, Mali, and Guinea.
      Some regional organizations exist, such as the GCC Interconnection Authority; the
       various regional organizations in Maghreb; the Steering, Planning and Operating
       Committees in EIJLLPST; and the Mauritania/Mali/Senegal/Guinea regional
       organizations including SOGEM, the Manantali asset holding company, and EEM, the
       entity responsible for the operation and maintenance of the power station and the grid, the
       commercial aspects of sale of power to the three systems, and collection of dues.
      Some countries have shown an interest in electricity market reform at the national level.
       For example, Saudi Arabia, Algeria, and Oman all have laws in place that will open their
       electricity markets up to competition over time.
      Part of the Arab grid, including the Maghreb region, is synchronized to the EU. Turkey
       expects to be fully synchronized with the EU in early 2012, paving the way for many of
       the other Arab countries to synchronize with Europe. A key component of this initiative
       is the potential transmission link between Saudi Arabia and Egypt.
      There is significant diversity of demand affording short-term trade. For example, Syria is
       winter peaking, while Egypt and Jordan are summer peaking. Further, there is diversity of
       demand over the day. For example, Egypt peaks during the late evening, while Saudi
       Arabia peaks in the afternoon. Trade taking advantage of demand diversity is further
       supported by a broad range of generation technologies and fuels among Arab countries
       with vastly different production costs. Therefore, there are numerous opportunities to




                                              106
          improve production efficiency and reduce the cost and improve the sustainability of fuel
          supply across the Arab power systems. 56
         With many Arab countries facing generation capacity and fuel supply shortages, and
          availability of financing limited, there is a strong incentive to expand trade and capture
          the huge benefits associated with regional integration.
While there are opportunities to increase electricity trade among Arab countries, there are also
many physical, structural/institutional, and regulatory challenges, as outlined below.
Physical challenges
         While high-voltage interconnecting transmission lines exist, there are limitations in the
          sense that not all Arab countries are interconnected and not all systems are synchronized.
          While there is interconnection capacity available to increase trade, the capacity is
          somewhat limited.
         The electricity systems of many of the Arab countries have not been designed to meet
          minimum standards, meaning there may be reliability and security risks associated with
          expanding interconnection capacity in the region. Only three countries —Algeria,
          Morocco, and Tunisia —are currently synchronized with the EU grid.
         As demonstrated in chapter 2, there is a limited amount of surplus power available in the
          Arab countries to support long-term trades that require delivery during both peak and off-
          peak periods.
Structural/institutional challenges
         There is minimal coordinated control over many national networks, making it very
          difficult to determine and verify if international trade transactions are feasible. There are
          no coordinated control centers responsible for generation and transmission dispatch for
          each region (although the Gulf Cooperation Council Interconnection Authority [GCCIA]
          has limited control over international transactions in the GCC). Further, there is not an
          agreed dispatch algorithm and software with a consistent set of data for multiple national
          systems to enable verification of the feasibility of trade transactions by different national
          control centers (again, the GCCIA may soon have this capacity).
         There are limited overarching documents representing a commitment by Arab countries
          to pursue power market reform and increased regional integration and trade. For example,
          there are few treaties or protocols (that is, the Energy Community Treaty) committing the
          Arab countries to the pursuit of greater regional integration and trade.
         The electricity markets in most Arab countries remain vertically integrated, state-owned
          monopolies. There are no “eligible customers” with the opportunity to choose their
          supplier. As a result, international transactions take a long time to negotiate, are
          cumbersome in the sense that they are unable to respond to short-term opportunities (such

56
  Studies carried out by regional transmission organizations (RT Os) in the United States compare centralized dispatch of a large
portfolio of generating units aggregated over multiple control areas to the current practice of simultaneous, independent dispatch
of subsets of this portfolio by individual control areas. RT O studies have found economic -dispatch benefits ranging from $80
million to over $40 billion, depending on the region and length of time studied. Normalized, these benefits range from 1 to 5
percent of total wholesale electricity costs.



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      as sudden changes in generation availability), are not transparent, and are often conducted
      by individuals who do not have a direct stake in the outcome; that is, a government
      official conducts negotiations rather than an industrial customer whose profitability is
      impacted by the outcome. Markets that are not liquid (meaning the number of
      transactions is limited), that are not transparent, and have the majority of trades
      conducted by government officials, tend to further exacerbate the problem of market
      liquidity as potential market participants are not trusting that the market price is truly
      “fair” and governed by market forces. As a result, these potential market participants
      refuse to participate.
     While there are some regional integration organizations in place, they are few, covering
      too few countries, and have limited duties and power to enforce their decisions. Regional
      committees could significantly increase trade among Arab countries. Committees formed
      with participants from all countries involved in the regional trade initiative could cover
      such areas as regulation, technical rules, and operating and planning standards such as
      those covered by a grid code, tariffs, expansion planning, trade, settlement, dispute
      resolution, and so on. Committees with the relevant expertise and formed with
      representatives from each involved country would afford greater acceptance and
      commitment on the important issues. The ENTSO-E provides an excellent example of
      such an organization.
     Only a limited number of Arab countries have shown an interest in electricity market
      reform at the national level. As competition is limited, market monitoring and
      surveillance guidelines have not been established.
     Private sector participation in electricity markets is generally limited to IPPs and
      independent water and power producers (IWPPs) in Arab countries. While privatization
      in itself is not necessarily a requirement, it can be a significant contributor to successful
      regional integration. The private sector can help mobilize the huge amounts of capital
      necessary to fund projects needed to meet increasing electricity demand. Further, private
      sector management expertise can significantly improve the operational efficiency of an
      electricity market.
     A number of Arab countries have high technical and commercial losses and poor
      collection rates, adding to the financial woes and creditworthiness of the power
      companies.
Regulatory challenges
     There is minimal harmonization of legislation among the Arab countries with respect to
      energy, environment, and safety.
     Few Arab countries have what could be considered “independent and informed”
      regulatory agencies. Independence refers to the ability to make decisions in the absence
      of political interference. Informed means that the members of the regulatory agency have
      the background, expertise, and skills to make decisions on behalf of all participants in the
      power sector. Regulation should be the primary job of the staff of the regulatory agencies,
      which is often not the case in Arab countries.
     There is significant subsidization and cross-subsidization of pricing in the power sectors
      of the Arab countries. Retail tariffs are generally well below the cost of supply and there
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       is often cross-subsidization of tariffs by larger industrial customers on behalf of smaller
       households. It is difficult to find a creditworthy off-taker since many power companies
       are at or near bankruptcy. It also makes it difficult to find a buyer since potential
       customers are paying prices for power that are well below cost (that is, a potential
       customer is unlikely to buy power at international prices when it can purchase power in
       the domestic market at subsidized prices).
      Gas markets in Arab countries have generally not been deregulated. This poses a
       significant challenge to sustainability/environmental objectives and the promotion of
       competition. Internationally, gas markets are often liberalized in tandem with electricity
       markets. The environmental advantages of gas make it the fossil fuel of choice for
       electricity generation. In the Arab countries both oil and gas prices used for electricity
       generation are often subsidized at levels well below international prices. As a result, fuel
       is being used inefficiently in the production process, and consumption is inefficient
       because retail electricity prices are well below the opportunity cost of supply. Further,
       subsidized fuel prices complicate electricity pricing, as it is difficult to determine a fair
       price for both long- and short-term trades.
      Most Arab countries do not allow access to their transmission networks under published
       terms, conditions, and prices—meaning access cannot be considered fair and
       nondiscriminatory.
      There is very little published information concerning market prices and transmission
       availability.
      There is excessive diversity of accounting practices and an absence of secure and stable
       legal framework among Arab countries.
These challenges provide significant obstacles to increased electricity trade, but numerous other
jurisdictions have overcome such obstacles. The key to increasing opportunities for trade is to
implement a plan that accommodates the challenges by providing the flexibility and time needed
to gradually address the challenges and mitigate the risks.




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4      The “Ultimate” Regional Market Design
This chapter sets out the concept and main design components of the ultimate regional electricity
market (REM) design that will serve as a “target” to be met over the long term by the Arab
countries. First, the need for an ultimate market design is explained along with the approach used
to develop the proposed design. Then an ultimate REM design is proposed for the Arab countries
including a description of the market, the roles and responsibilities of market participants, and
recommended regional entities and documentation to provide market oversight and governance.
4.1    Purpose and Approach to Development of the “Ultimate” Regional Market Design
The electricity sectors in the Arab countries are at much different stages of development, and the
reform effort and commitment to furthering regional trade varies by nation. Therefore, any plan
to integrate regional markets and increase the opportunity for trade among the Arab countries
must be flexible, allowing each country to proceed at its own pace with implementation of the
necessary reforms in its national power market.
It would be unfortunate if each country were to proceed down its own path to reform and
develop its own market design without regard to what neighboring countries are doing. This
would complicate and reduce understanding of trade between countries, hinder development of
trade, and reduce the confidence, transparency, and liquidity of a regional market. A REM will
only be successful if there is reciprocity. Establishing an ultimate REM design to serve as a
common goal to reach in the future will help to harmonize development of the national and
subregional markets in the Arab countries during the transition period, which is expected to take
many years. This approach to market development has served Western Europe well, and
continues to serve countries not yet fully enshrined in the European electricity market.
There are two primary considerations in developing an ultimate regional market design for the
Arab countries:
     What market designs have potential/desirable trading partners implemented or begun to
implement, and what requirements have they imposed on potential trading partners?
      What are the generally accepted best practices in the various components of market
design based on experience and lessons learned?
Owing to geographic proximity and potential benefits, a market design that meets the
requirements of the European Union (EU) warrants serious consideration as the ultimate regional
electricity market design for Arab countries.
4.2    Proposed Ultimate Regional Market Design for Arab Countries
4.2.1 High-Level Description
Table 4.1 outlines a high-level, ultimate regional electricity market design to serve as the long-
term target for Arab countries, and figure 4.1 provides a schematic of the design. This ultimate
REM design is proposed in an effort to harmonize legislation and electricity market governance
documentation over the long term, thus avoiding unnecessary delays and costs. It is proposed as
a target for each country in the Arab world wishing to partake in the benefits afforded a REM.
The proposed design is what is commonly referred to as a bilateral contracts market. It has a
great deal of flexibility, enabling trade with countries in Europe, Asia, and Africa because:


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       It is a simple matter to negotiate a bilateral contract with an entity in a neighboring
country, particularly once all countries adopt minimum technical standards and open access to
transmission networks. It is not a simple matter in pool-type markets (that is, Pennsylvania-
Jersey-Maryland [PJM], New England and New York, Eastern Australia, and Singapore) where
all generators are required to bid their capacity into the pool.
      The bilateral contracts market model is generally considered best practice, so countries in
surrounding regions are likely to adopt this market model in the future. A bilateral contracts-type
market is also a requirement if a country wishes to trade with Europe.
The proposed design is robust, allowing the national markets in the Arab countries to incorporate
their own nuances and circumstances. It is anticipated that the ultimate market design adopted by
the Arab countries will be modified in future years to remain consistent with market design
changes in the surrounding region. As proven over the past 14 years in Europe, market reform is
an ongoing process.

         Table 4.1 High-level description of proposed ultimate regional market design
      Unbundled generation, transmission, and distribution/supply functions with legal unbundling of
       the transmission-operator function.
      Fair, open, and nondiscriminatory access to the transmission network with published terms,
       conditions, and prices; transmission service harmonized regionwide.
      Independent and informed regulation in each country with reporting at regional level.
      Bilateral contracts with terms, conditions, and prices freely negotiated by the parties to the
       contract.
      Bilateral contracts supported by balancing market with market-based prices; balancing-market
       pricing and settlement harmonized region-wide.
      Self-scheduling of generation, that is, the generators/suppliers submit their supply/demand
       schedules to the transmission system operators (TSOs).
      A power exchange offering services as needed by the regional market, such as a competitively bid
       day-ahead market, intraday market, emissions contracts, and so on.
      Market-based allocation of cross-border transmission capacity with use of auctions to eliminate
       bottlenecks; calculation of available transmission capacity in a transparent and nondiscriminatory
       manner based on real physical bottlenecks.
      Full compliance across the region with developed and agreed-upon standards.
      Separate regional entities relating to financial operations (a regional power exchange), technical
       operations (a regional TSO), regulation (a regional regulatory entity), and general market
       oversight.




                                                  111
           Figure 4.1 Schematic of transactions in proposed ultimate market design




4.2.2 Salient Features of Proposed Ultimate Regional Market Design
Further details of the proposed ultimate REM design for Arab countries are provided below.
Grid access
All market participants will have transparent, fair, and nondiscriminatory access to the grid,
meaning there should be no legal, administrative, or discriminatory barriers to the networks.
There will be a nondiscriminatory and transparent licensing process, and no barriers to
connection.
There will be clear and readily accessible governance documentation, that is, a commercial code,
a grid code, and so on. There will also be timely and nondiscriminatory access to information
related to the market (that is, system constraints) so that market participants can make informed
choices. Network tariffs will reflect costs and will be harmonized among Arab countries. Costs
of current and future investments will be included in the tariffs, as will costs of operation,
maintenance, and losses.
Cross-border transmission capacity will be allocated based on market-based principles such as
capacity auctions. Collection of congestion rents (that is, from transmission capacity auctions)
will be used to fund projects to eliminate bottlenecks in the grid. Available transmission capacity


                                               112
will be calculated in a transparent and nondiscriminatory manner based on real physical
bottlenecks.
Balancing market
Market participants will be required to enter into balancing supply agreements to cover the
imbalances they cause on the system. The balancing market will be utilized to settle differences
between quantities specified in bilateral contracts and actual quantities of energy consumed and
produced. The balancing market will be bid based and settled regionwide, and will be used for
ancillary services such as reserves. Balancing supply agreements can be established with other
market participants or with TSOs. Each TSO will be responsible for balancing its national
market including imports from and exports to other countries.
Power exchange
The power exchange will provide a transparent regional market reference price for all market
participants. The exchange will not be compulsory; market participants will freely choose
whether or not to bid. There may be more than one bidding area depending on how congestion
develops. The power exchange will be fully transparent. 57 It will offer standardized contracts (for
example, hourly bids, block bids, linked block bids, and so on), and participants will comply
with a number of administrative requirements such as establishment of accounts, waiver of
confidentiality, agreement on balancing responsibility, reporting obligations, and audit.
Market access
Market participants will be qualified, authorized, and registered to participate in the market.
Market participants will agree to abide by their license agreements and the responsibilities
specified in market-governance documents. Participants must also provide any credit guarantees
as defined in governance documentation.
Market surveillance
Market surveillance will be the responsibility of all parties, including the TSOs, the power
exchange, regulators, market participants, and commissions responsible for stock exchanges
when financial products are at issue. A market-surveillance unit will reside within the market
operator and will monitor trading activities to determine if a market participant is behaving in a
manner that has a substantial and ongoing impact on prices without a response from the market.
The market surveillance unit will identify the need for investigations when it believes a breach of
the rules and regulations has occurred. All information acquired during investigations will be
treated as strictly confidential.
4.2.3 Roles and Responsibilities of Market Participants
Each market participant has its own role and set of responsibilities to fulfill in the regional
market. Roles and responsibilities of the various market participants follow. A summary is
provided in table 4.2.




57
     ERGEG North European Electricity Regional Initiative provides a good reference.



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                        Table 4.2 Summary of Market Participant Responsibilities

       Market participant                                 Role                        Primary responsibility

Market operator                           Manage power exchange.                 Establish market price, coordinate
                                                                                 billing and settlement.

TSOs                                      Transmit electricity and ensure        Balance the national power system.
                                          third-party access.

DSOs                                      Distribute electricity.                Deliver electricity from transmission
                                                                                 network to customers.

Producers                                 Generate electricity.                  Deliver electricity according to bids
                                                                                 and contracts.

Suppliers                                 Arrange for electricity supply to      Secure demand and supply portfolio
                                          customers.                             and manage procurement risk.

Traders                                   Offer electricity market services.     Secure demand and supply portfolio
                                                                                 and manage risk.

Brokers                                   Match buyers and sellers of market     None.
                                          products.

Regulator                                 Regulate proper functioning of         Monitor market and take action
                                          market.                                when market participants are not in
                                                                                 compliance with governance
                                                                                 documentation.
Note: DSO = distribution system operator; T SO = transmission system operator.

Market operator
The market operator will be a regional entity that is regulated to ensure its transparency,
nondiscriminatory nature, and independence. It will coordinate closely with the national TSOs.
Owing to this close relationship, there must be clear interfaces between the market operator and
the TSOs, particularly with regard to available transmission capacity.
The market operator’s primary responsibilities will include:
         Registration of participants in the power exchange.
         Bid analysis and settlement.
         Publication of market prices subject to confidentiality considerations.
The market operator is not responsible for balancing—this is the responsibility of the TSOs.
Transmission system operators (TSOs)
The TSOs will be national entities retaining full control and responsibility for the operation and
planning of the national transmission networks. They will be regulated entities providing third-
party access to the transmission grid on a nondiscriminatory basis. Although operating at a


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national level, they will coordinate activities with neighboring countries and the regional
organization for TSOs. The TSOs are vital to the operation of the integrated REM.
TSOs will be responsible for balancing their national systems and providing ancillary services to
all network users in their country. They will be responsible for settlement of financial
transactions at the national level, but will collaborate with other TSOs on the settlement of
imbalances, and may enter into contracts for the purpose of balancing and ancillary services with
producers or traders throughout the Arab REM (and neighboring markets once included).
Each TSO will be responsible for:
           Ensuring adequate transmission capacity is available to meet the short- and long-term
            demands for transmission service in a reliable and secure manner.
           Balancing the system on a moment-to-moment basis, taking into account exchanges with
            other countries, and including the provision of ancillary services.
           Exchanging information with TSOs of other interconnected systems necessary to ensure
            secure and efficient operation, and the coordinated development and interoperability of
            the interconnected system.
           Ensuring nondiscriminatory transmission service for system users.
           Publishing information needed by users in a timely and nondiscriminatory manner
            including such things as tariffs and connection rules.
           Coordinating regularly and in a timely manner with the market operator on available
            transmission capacity including capacity on the international interconnections.
The TSO will be legally unbundled, meaning that it should have no interests or activities in the
electricity market other than operating the transmission system. 58 Transmission tariffs will be
cost reflective and will not be subsidized by any other activity.
The TSO will preserve the confidentiality of commercially sensitive information, and will take
actions necessary to promote greater efficiency in the electricity market.
Distribution system operators (DSOs):
The DSOs will be responsible for delivering electricity to consumers through the low-voltage
distribution networks. They are responsible for maintaining a secure, reliable, and efficient
electricity-distribution network and will be required to procure energy to cover losses and
reserve capacity to meet the needs of their distribution system according to transparent,
nondiscriminatory, and market-based procedures. The DSOs will be responsible for planning the
development of their distribution networks taking into consideration all available options for
network expansion or upgrade, including measures that might defer these actions such as energy
efficiency, demand-side management, and distributed generation.
The DSOs will be independent to ensure their decision making is not influenced by activities that
are not related to distribution.
Producers

58
     T he provisions of the European Electricity Directive (Directive 2003/54/EC, art. 10) provide a good reference.



                                                               115
Producers, which generate the electricity, will have the right to:
      Enter into bilateral contracts to sell electricity to wholesale customers or suppliers.
      Enter into bilateral contracts with TSOs to provide ancillary services.
      Export electricity to other Arab and non-Arab countries.
A producer provides information on how much it will produce and when, depending on current
and forecast market prices.
Suppliers
Suppliers are load-serving entities responsible for supplying customers in the Arab countries and
importing and exporting electricity from and to non-Arab countries. They will have the right to
enter into bilateral contracts with producers or other suppliers and to purchase energy in the
power exchange. Suppliers will also have the right to buy electricity from traders or through
brokers.
Suppliers will ensure that the electricity consumed by their customers is physically produced to
support bilateral contracts. A supplier procures the least-expensive energy available consistent
with the level of risk it is willing to take.
Traders
Traders will have the right to offer physical and financial portfolio-management services,
meaning they will optimize the portfolios of producers and suppliers and manage their risk.
Traders will have the right to buy and sell energy to support their services.
A trader makes arbitrage profits on differences between buy and sell prices. A trader may
provide other products besides electricity, such as fuel-supply optimization, carbon-credit
management, or other environmental products such as green certificates.
Brokers
Brokers bring together sellers and buyers of electricity or other products such as fuel and carbon
credits. The broker participates in the wholesale market, matching buyers and sellers wishing to
buy a particular product. Brokers act independently and are not balancing responsible parties.
Regulator
Each country will have a regulatory authority to ensure effective and efficient competition and
that wholesale customers and suppliers are treated in a fair and nondiscriminatory manner. The
regulator will monitor the electricity sector to ensure compliance with technical standards and
performance benchmarks. The regulator will be independent of interests in the electricity
industry.
The regulator will monitor and report on:
      The management and allocation of interconnection capacity by the TSOs of the
       interconnected countries.
      Mechanisms that deal with transmission congestion within the national electricity system.
      Performance of the transmission and distribution entities.
      Interconnections, grid use, and capacity allocation provided by TSOs.

                                                 116
        Unbundling of market participants to ensure against cross-subsidies between market
         activities.
        The terms, conditions, and tariffs for connecting new users to the networks.
        The extent to which TSOs and DSOs complete their tasks.
        The level of transparency and competition in the market.
        TSO compliance with rules relating to third-party access, balancing, congestion, and
         interconnection management.
        TSO investment plans and their consistency with regionwide investment plans.
        Network security and reliability.
        Network security and reliability rules.
        Transparency.
        The level of market opening and competition.
        Effectiveness of consumer-protection measures.
The national regulators will cooperate at the regional level with the regional regulatory authority
to ensure competitive, secure, and environmentally sustainable electricity markets both
nationally and regionally in the Arab countries.
4.2.4 Regional Institutions
Formation of supranational organizations will improve the prospects for electricity trade among
the Arab countries. Europe has formed the ENTSO-E and ACER in hopes of furthering the
development of its internal REM; the Arab countries would do well to take advantage of the
lessons learned in Europe by establishing the following regional organizations:
        Regional market operator
        Regional TSO
        Regional regulatory agency
These institutions would be responsible for all Arab countries that choose to participate in the
regional market. In the long term, when the ultimate market design is fully implemented, it is
anticipated that the three current subregional markets, and Arab countries not currently
connected to any of the three subregional markets, will be fully interconnected, synchronized,
and operating as a single regional market. Any existing institutions at the subregional-market
level will be dissolved, and replaced with the regional institutions with the roles and
responsibilities described in table 4.3.
                    Table 4.3 Regional institutions for ultimate regional market
      Institution                                                 Responsibilities

Regional market operator   - Manage regional market power exchange.
                           - Monitor market -participant behavior and proper functioning of market.
                           - Provide oversight on technical aspects of regional market.
Regional T SO              - Ensure fair and nondiscriminatory access to grid and international interconnections.
                           - Coordinate actions of national T SOs.



                                                            117
                            - Review, approve, and ensure compliance with regional market governance documents.
                            - Review, approve, and ensure fair application of national transmission tariffs.
Regional regulatory         - Provide market surveillance.
authority                   - Provide dispute resolution.
                            - Report on various aspects of the market.
                            - Coordinate actions of national regulators.
Note: T SO = transmission system operator.


4.2.5 Governance Documentation
Ensuring the basic tenets of fairness, nondiscrimination, and reciprocity in the regional market
will require a number of governance documents. These documents establish the minimum
standards for the region as a whole; however, each country may issue its own documentation, in
particular a grid code, to accommodate its peculiarities, and in some cases, its desire for stricter
requirements than those set out in the regional documents. The national documents will be
reviewed by the regional-market organizations to ensure harmonization and consistency with
regional-market documents and the regional market’s objectives of fairness, nondiscrimination,
and reciprocity.
Table 4.4 sets out the necessary documents for the ultimate regional market.

       Table 4.4 Regional market governance documentation for ultimate regional market
           Document                                                      Primary content
Memorandum of                       -   Commitment of Arab countries to REM integration.
understanding/general agreement     -   Legal basis for regional market and subsequent reforms.
                                    -   Legal basis for regional market institutions.
                                    -   Objectives of REM.
                                    -   Guiding principles for development of market.
                                    -   Formation of, and roles and responsibilities of regional institutions.
                                    -   Overview of market design and transition path.

General market rules                -   Specifies commercial aspects of regional market, including operation, participation,
                                        and administration.
                                    -   Roles and responsibilities.
                                    -   Metering, billing, and settlement.
Regional grid code                  -   Specifies minimum technical requirements for operation and planning national
                                        transmission networks and international interconnections.
                                    -   Roles and responsibilities.
                                    -   Reporting requirements.


Note: REM = regional electricity market.

While these documents are essential for the ultimate regional market, they are even more
important during the market’s transitional period, acting as the primary means for implementing
reform. Therefore, a detailed discussion of the content of these documents is left until the next
chapter, which focuses on the transitional regional electricity market design.

4.3 Summary
This chapter has proposed an ultimate regional electricity market design for the Arab countries.
The design presents a target for development of the national and subregional markets in the Arab
countries during the transition period, which is expected to last many years. The proposed


                                                            118
ultimate regional market design takes into consideration international practices and experience,
and will enable trade with countries in Europe, Asia, and Africa.

In the next chapter, we discuss a transitional market design that will set the Arab countries on a
path toward increased international trade, more optimal use of international interconnections,
and, in the longer term, full implementation of the ultimate REM design.




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5       Proposed Transitional Regional Electricity Market Design
While the ultimate regional electricity market (REM) design is expected to deliver the greatest
benefits to the Arab countries and maximize the value of the interconnections, proceeding with
implementation of such a complex market design in the near or even the medium term would not
be possible. Numerous constraints and risks outlined in chapter 3 must be mitigated before the
ultimate regional market design can be successfully implemented. Therefore, consistent with
experience elsewhere in the world, a phased approach to regional-market integration is proposed
that will increase regional trade while allowing time for the Arab countries to address obstacles
and mitigate risks. It is anticipated that the phased approach will include multiple steps, with
each step moving the regional market toward the ultimate regional market design described in
chapter 4.

This chapter discusses the objectives and guiding principles used in the development of the
transitional regional electricity market design, identifies an approach to increase regional
integration, proposes a path to regional integration, and proposes a transitional regional
electricity market design. The transitional market design includes an overview of the design,
salient features of the market design, a description of the roles and responsibilities of regional-
market participants, recommended regional-market institutions and their roles and
responsibilities, and a high-level description of the regional-market governance documents.

5.1     Objective and Guiding Principles
The objective of the transitional design is to expand regional electricity trade, which will
maximize the value of international interconnections and national electricity system
infrastructure. This benefits the interconnected nations by improving:

         Reliability and security of supply.

         Sustainability, as it relates to use of natural resources and their impact on the
          environment.

         Competition in electricity production and delivery.

The objective, similar to that of the European Union (EU),59 is shown schematically in figure
5.1.




59
   T he EU has established targets relating to energy production from renewable sources, greenhouse gas emissions, and energy
efficiency gains (the 20-20-20 target criteria to be reached by 2020) against a background of increasing international competition
for the world’s resources. Adequate, integrated, and reliable energy networks are judged to be a crucial prerequisite for EU
energy-policy goals.



                                                              120
              Figure Figure 6-1: Objective
                     5.1 Objectives        of Regional
                                       of regional                Market Integration
                                                       Electricitymarket
                                                    electricity          integration

                                        Competition




             Sustainability                                        Reliability / Security




Guiding principles
The guiding principles used in the development of the transitional REM design include:
      As a first step, considering easily implementable design concepts that promote increased
       regional integration and trade while making progress on removal of existing barriers to
       trade.
      Recognizing that market pricing and competition in fuels and electricity markets is a
       relatively new concept in the Arab countries, and that the Arab countries are at different
       stages of market reform with different levels of commitment to reform. The transition
       plan must be flexible and allow adequate time for addressing obstacles and mitigating
       risks.
      Incorporating lessons learned and experienced elsewhere to the maximum extent
       possible.
      Building on the existing REM integration framework and regional market institutions.
      Maintaining consistency with the ultimate regional electricity market design described in
       chapter 4.
      Maintaining consistency with the electricity market reform objectives among Arab
       countries while allowing each country to proceed with reform at its own pace (at least
       initially).
      Establishing regional institutions, regional market participants, and regional governance
       documentation that provide:
                     The responsibility and authority to promote regional integration and trade.
                     The incentives to participate in the regional market and maximize value.
                     The training and capacity building necessary for the regional-market
                      institutions and participants to properly carry out their roles and
                      responsibilities.

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5.2    Approach to Regional Electricity Market Integration
International trade has traditionally started with an interconnection project linking the power
networks of two adjoining countries. Such interconnections are accompanied by documentation
(that is, a general interconnection agreement) that sets out the goals and objectives of the
interconnection; operation, planning, and services to be traded over the interconnection; and the
commitments of each party to complete its portion of the interconnection project in a timely
manner. This document is often a political document signed by government officials, such as the
ministers responsible for electricity. Following completion of the interconnection project, the
general interconnection agreement is normally superseded by a more complex interconnection
operation-and-planning agreement that is consistent with the general interconnection agreement,
but provides greater detail relating to planning and operation of the interconnected power
systems. This document is normally signed by high-level utility personnel. The Gulf Cooperation
Council (GCC) and Egypt, Iraq, Jordan, Libya, Lebanon, Palestine, Syria, and Turkey
(EIJLLPST) interconnection are good examples of this process, although they apply to multiple
countries rather than only two countries.
This stage of market integration might be followed up by market reforms that increase the level
of integration at the operating level, for example, through centralized economic dispatch of the
combined power systems. Likewise, planning might be done on the basis of least cost from the
perspective of the combined power systems, rather than each country in isolation. Moving to
combined-system operation will result in improved asset utilization and generation production
(that is, fuel) efficiency. As the power systems of additional countries are integrated into the
regional market, the asset utilization and production efficiency will improve even further.
Generally, it has been necessary to install a legal arrangement with some level of centralized
oversight over bilateral or regional integration efforts. Decentralized arrangements, with each
power system operating fully independently, have had limited success. International experience
has shown that centralized operation and control has delivered benefits as long as the centralized
entity placed in control has the necessary expertise and independence from the market
participants.
Centralized operation and planning can be accomplished between multiple countries in a fully
regulated manner. But in recent years integration efforts have relied on the introduction of
competition in the production and supply components of the electricity sector, while delivery at
the transmission and distribution levels has remained a monopoly service. The goal of
competition is to provide continued pressure on producers and suppliers to improve efficiency,
performance, and customer service, and to provide a better allocation of risk between suppliers
and customers. A market-based, rather than command-and-control-based, approach is utilized to
promote an economic-dispatch outcome. Competition is enhanced by international
interconnections, which enable entities outside a country to compete with incumbent utilities that
have traditionally held monopoly positions within their country. As has been discussed
previously in this report, international competition ultimately requires that there be open access
to the national transmission networks, and that there be consistency in market reform, regulation
(technical, economic, and environmental), and governance documentation (market rules, grid
codes, and so on) at the national level. This is necessary to level the playing field and promote
competition.



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Economic dispatch can be achieved in a variety of ways. In a regulated environment, economic
dispatch can be promoted by paying each generator for each kilowatt-hour (kWh) dispatched on
the basis of an audited production cost. The centralized dispatcher would construct the dispatch
schedule on the basis of lowest production cost to reliably meet the forecast demand while taking
into consideration technical constraints such as generator limitations, fuel limitations,
transmission limitations, and so on. The generators would collect their fixed costs on the basis of
a regulated payment, possibly tied to availability. In a competitive environment, economic
dispatch can be promoted through a mandatory pool concept, where generators are dispatched on
the basis of lowest cost in a cost-based pool, or lowest price in a price-based pool. Generators
receive the market price for each kWh delivered to the grid. The market price is the production
cost of the highest-cost generator dispatched during the hour (ignoring transmission constraints).
The portion of the market price that a generator receives in excess of its production cost
represents the contribution to its fixed cost. Cost-based pools are the predominant market
mechanism used in South and Central America, while price-based pools are the predominant
market mechanism used in the northeastern United States (Pennsylvania-Jersey-Maryland [PJM],
New York, and New England), eastern Australia, and Singapore. Alternatively, economic
dispatch can be promoted through a bilateral-contracts market mechanism where generators and
wholesale buyers freely negotiate the terms and conditions of their contracts. The negotiated
price compensates the generator for its fixed and variable production costs. The addition of a
balancing market and a day-ahead market enhance the prospects for economic dispatch and
promote price discovery and transparency. A bilateral contracts market is the predominant
market mechanism used in Europe, and the mid-western United States (for example, Midwest
ISO and Texas).
Both pool and bilateral-contract market mechanisms are enhanced through the addition of other
markets to increase efficiency and price discovery. Pool markets often include financial bilateral
contracts to hedge fluctuations in market prices. They might also include an intraday market or a
capacity market. Bilateral-contract markets are normally accompanied by balancing markets and
day-ahead markets, and might include intraday markets as well. Balancing markets are used to
assign costs to the parties of bilateral contracts when production and consumption vary from
amounts declared in bilateral contracts.
Because the ultimate regional electricity market design proposed in chapter 4 uses a bilateral-
contracts market mechanism, the transitional market design should use one as well.
Implementing a pool market mechanism as an interim measure before proceeding to a bilateral-
contract mechanism would result in significant, and unnecessary, implementation costs and
delays.
5.3    Proposed Path to Regional Electricity Market Integration
Figure 5.2 shows a schematic of the proposed path to regional electricity market integration.
Each step is discussed briefly below.




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                        Figure 5.2 Stages of regional electricity market integration

                               Stage 1                     Stage 2                    Stage 3                      Stage 4
                                                                                                               Fully-
                                                       Expand                      Ultimate
                                                                                                               integrated
                                                       Regional                    Regional
Existing                   Transitional                                                                        Arab Regional
                                                       Market                      Market
Regional                   Market                                                                              Market
                                                       Function
Markets
                                                                                   Focus:
                           Focus: Identify                                                                     Focus:
                                                       Focus:                      Full wholesale
Focus: GCC,                and expand                                                                          Fully
                                                       Unbundle TSOs               competition
EIJLLPST and               trade                                                                               interconnected
                                                       and introduce               supported by
Maghreb                    opportunities                                                                       and
                                                       wholesale                   multiple
                                                       competition                 markets                     synchronized
                                                                                                               Arab electricity
                                                                                                               network



 Existing regional markets
 In the first stage, regional integration is focused on the three existing REMs —the GCC,
 EIJLLPST, and Maghreb. These three markets are described in detail in chapter 2.
 Stage 1 —Transitional market focused on identifying and expanding trade opportunities .
 Looking to build on existing infrastructure, governance documentation, and regional institutions,
 this market phase will emphasize strengthening and improving the efficiency of existing and
 planned interconnections, improving reliability, and eventually increasing opportunities for trade
 in the three existing subregional markets. It will require modifications to governance
 documentation and regional institutions, but will not require reform of the national power
 sectors.60 It will result in improved reliability by bringing national power markets up to a
 minimum reliability standard through the introduction of a standardized grid code, and will result
 in improved sustainability by identifying and promoting regional trade opportunities that will
 result in increased operation of the most-efficient power plants in the region. It will assign
 responsibility and authority for increasing regional trade, provide incentives for increasing
 regional trade, and establish capacity-building programs to train stakeholders on increasing the
 value of national and international power-system assets. More specifically, during this phase
 trade volume is expected to expand through an increase in the number of transactions between
 contiguous countries as well as among noncontiguous countries. Trade will take place through
 direct utility-to-utility bilateral contracts while intermediate countries provide transit service.
 Infrastructure will be improved and expanded to increase capacity and synchronization to
 enhance trade opportunities. Part of this stage’s infrastructure improvement will be focused on
 reinforcing existing cross-border interconnections for bulk electricity trade (for example, Iraq–
 Syria, Jordan– Egypt, Egypt– Libya, Libya– Tunisia, Algeria – Morocco), and upgrading national
 transmission networks. Another component of the infrastructure improvement will involve
 construction of new interconnections, for example, Egypt– Saudi Arabia, Egypt– Sudan,
 Mauritania– Morocco, and Saudi Arabia – Yemen. In this stage, regional-market institutions will
 be formed to cover all Arab countries, including a secretariat, a regional advisory and regulatory
 committee, and a regional Arab TSOs committee including the national TSOs and three

 60
   Although doing so would improve the functionality of the transitional market and set the stage for subsequent steps in the
 regional-market reform process.



                                                            124
subregional TSOs/market facilitators, one for each of Maghreb, EIJLLPST, and the GCC.
Further, regional-market governance documentation covering all Arab countries will be drafted
including a regional grid code and a general regional electricity market agreement defining the
commercial or market rules. Regional-market governance documents will be consistent with a
memorandum of understanding (MOU) and general agreement signed by participating Arab
countries prior to implementation of this stage of the market integration scheme. The MOU
establishes the commitment to market integration, an intergovernmental framework, and a legal
basis for the regional market and its supporting institutional infrastructure. The general
agreement defines the roles and responsibilities of the regional market institutions, sets out
objectives and principles of the market, and provides an overview of the market design and
transitional steps for market reform. By the end of this stage, cross-border electricity trade will
cover the cost of supply, and coupled with the expected increase in trade volume, will trigger
incentives for expanding generation capacity in certain countries for export to other market
destinations.
Stage 2 —Expanded transitional regional market. This represents the initial stage of subregional
markets opening. Access to the markets and competition are introduced at the wholesale level for
third-party suppliers and large consumers, generally those directly connected to the transmission
system. This step requires reform at the national level, including unbundling of the TSOs,
establishment of an independent regulatory entity, and development and implementation of
market (or commercial) rules for both the regulated and competitive components of the market.
Expanding access to the REMs is expected to result in higher levels of regional electricity trade
and further improvements in the sustainability and security of supply objectives. Wholesale
tariffs for the large customers in this stage will reflect the opportunity cost of supply. Trade will
be facilitated by further improvements in transmission capacity and synchronization at the
regional and national levels. A regional regulatory entity will be formed with initial
responsibilities relating to dispute resolution and reporting at the regional market level. The
regional Arab TSOs committee instituted in the previous stage will be replaced by a regional
TSO entity with a board of directors and full complement of regular staff. The roles and
responsibilities of the secretariat and the regional advisory and regulatory committee will be
modified to be consistent with the roles and responsibilities of the new regional TSO and
regulatory entities. The role of the subregional TSOs/market facilitators will be expanded to take
on more of the responsibilities of a regional-market operator consistent with regulated and
competitive market components. The regional grid code will be modified as necessary, and the
general regional electricity market agreement will require significant revision to accommodate
competitive trade at the wholesale level.
Stage 3 —Ultimate REM with full wholesale competition supported by multiple financial
markets. This stage will improve the efficiency, economy, and transparency of the REMs in the
three subregions with the introduction of full wholesale competition—distributors, suppliers, and
large customers directly connected to the transmission system will have a choice of supplier
consistent with the ultimate regional electricity market design documented in chapter 4. As
suppliers will be responsible for procuring the power requirements of their retail customers in the
competitive market, retail tariffs will be raised to levels reflecting the full cost of power, and if
social subsidies are to remain, they will be funded directly by government with full transparency
and in a manner that least impacts market prices. Additional markets that support bilateral trade
and improve liquidity and price transparency and discovery will be opened, such as a
competitively bid balancing market, a bid-based day-ahead market and, potentially, intraday

                                                125
market, environmental-emissions-trading markets, and a capacity market. The extent of the
markets to be added will be determined by the demand for such markets by regional market
participants. The regional market operators will have fully replaced the market-facilitation
function of the subregional TSOs/market facilitators and will operate the supporting markets as
demand warrants, filling the void when private sector interests do not come forward to
implement and operate such markets. The combination of markets will result in a robust, liquid,
and transparent REM that promotes an economic-dispatch outcome consistent with the
objectives of competition, sustainability, and reliability of supply. At this stage, the secretariat
function will be disbanded, and the regional market operator, the regional TSO entity, and the
regional regulatory entity will take on full regional-market oversight responsibilities under the
guidance of the Arab Ministerial Council for Electricity and the Executive Bureau. Governance
documentation will be modified as necessary and further improvements in transmission capacity
and synchronization at the regional and national levels will be implemented as necessary to
support trade. The three subregional markets —the GCC, EIJLLPST, and Maghreb—might be
collapsed into one or two markets depending on progress made on transmission capacity and
synchronization.
Stage 4 —Fully integrated and synchronized Pan-Arab electricity market. This stage represents
the final step in the journey to a fully integrated Pan-Arab REM. The REM will have wholesale
competition with functional regional market institutions and governance documentation. The
only thing that remains to achieve full regional market integration is to complete
interconnections and synchronization between the three subregional markets of Maghreb,
EIJLLPST, and GCC, within the three subregional markets (both nationally and internationally)
and with Arab countries that are still not interconnected or synchronized with any of the three
subregional markets. Before any new countries are allowed to connect with the Pan-Arab market,
they will need to bring their power systems up to the full requirements of the regional grid code
and abide by regional-market governance documentation. Note that interconnection and
synchronization to support trade will be ongoing at each stage of regional-market integration.
Regional-market institutions and participants will determine the ordering and prioritization of
each enhancement.61
The above four-stage market development approach portrays a vision of the path toward regional
integration. To translate this vision into practice, one would need to devise a clear and consistent
long-term strategy that identifies specific policy actions to be undertaken during each stage of
market development. Table 5.1 sets out our proposed strategy, which is focused on the policy
decisions pertaining to building institutions and a legal and regulatory framework. The strategy
recognizes that the three subregions are at different stages of market development; however,
institution building for the entire Pan-Arab network would assist transfer of knowledge, skills,
and information among the three subregions and from the neighboring countries. Institution
building during each stage is devised to meet the requirements of that stage and to prepare for
moving to the next stage.




61
   T he League of Arab States (LAS) is carrying out a companion study that will address the technical feasibility of electrical
interconnection and trade among Arab countries.



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                                     Table 5.1 Proposed long-term strategy
    Stage of       Expansion of infrastructure and electricity           Institution building/legal framework and policy
 development                              trade                                                  decisions
Stage 1:           Subregional T SOs/market facilitators identify       Establish a secretariat.
Transitional       trade opportunities based on international fuel      Establish a regional advisory and regulatory committee.
market focused     prices.                                              Establish regional Arab T SOs committee.
on identifying     Additional trade volume expected among the           Establish a subregional T SO/market facilitator for each
and expanding      GCC, EIJLLPST , and Maghreb countries.               subregion. 62
trade              T rade takes place according to direct utility-to-   Develop and sign:
opportunities      utility bilateral contracts between contiguous           A memorandum of understanding and general
                   and noncontiguous countries.                              agreement on Pan-Arab regional electricity market
                   Some countries provide transit/wheeling service.          integration.
                   Reinforce infrastructure by:                             A general regional electricity market agreement.
                      Expanding generation to meet national                A regional grid code.
                         requirements and exports.                      Harmonize technical and reliability standards.
                      Utilizing generation to meet seasonal and        Expand the Pan-Arab electricity database to include
                        daily demand differences beyond domestic        comprehensive and up-to-date information on each
                        market.                                         country’s expansion plan, investment program, and
                      Reinforcing existing cross-border                regulatory changes.
                        interconnections for bulk electricity trade     Prepare transmission tariffs and cross-border
                        (for example, Iraq– Syria, Jordan – Egypt,      transmission-capacity auction process.
                        Egypt – Libya, Libya– T unisia, Algeria–
                        Morocco).
                      Upgrading national transmission networks.
                   Additional international interconnections:
                      Egypt – Saudi Arabia
                      Egypt – Sudan
                      Mauritania– Morocco
                      Saudi Arabia– Yemen
Stage 2:           Introduce competition to large consumers             Agree to open up high-voltage supply to competition and
Expanded           directly connected to the transmission network.      allow tariffs for large customers to be set by competitive
transitional       Further improve sustainability and security of       market.
regional market    supply objectives.                                   Separate T SOs through unbundling of the national
focusing on        Facilitate trade through further strengthening of    markets and establish national independent and informed
unbundling         transmission networks and synchronization.           regulatory entities.
TSO s and          Systems are synchronized at the level of each        Establish a regional regulator (will start with a reporting,
introducing        subregion (GCC and Maghreb already                   coordinating, and dispute-resolution role before moving
wholesale          synchronized; synchronize all EIJLLPST               to a full-fledged regional regulator).
competition        countries).                                          Replace regional Arab T SOs committee with regional
                   Coordinate investments in transmission               Pan-Arab T SO entity with board of directors and full
                   infrastructure.                                      complement of regular staff.
                                                                        Revise roles of secretariat and regional advisory and
                                                                        regulatory committee to reflect roles of new regional
                                                                        T SOs and regulatory entities.
                                                                        Amend role of subregional T SOs/market facilitators to
                                                                        take on more responsibilities relating to market operator
                                                                        function.
                                                                        Revise regional grid code as necessary and make
                                                                        extensive revisions to general regional electricity market
                                                                        agreement to accommodate competitive trade at
                                                                        wholesale level.




62
   T he Gulf Cooperation Council Interconnection Authority (GCCIA) has many of the re sponsibilities proposed for the
subregional T SO/market facilitator, but not all (for example, the GCCIA does not publish market prices); therefore, some
modifications in its responsibilities would be necessary for it to take on this role.



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    Stage of         Expansion of infrastructure and electricity             Institution building/legal framework and policy
  development                               trade                                                    decisions
Stage 3:             Full wholesale competition with all large              Agree to open up market to full wholesale competition.
Ultimate             customers and distribution/supply entities             Put into operation additional financial markets (for
regional market      allowed choice of supplier.                            example, day-ahead market) as required by regional
focusing on full     Introduce new financial markets as needed by           market participants.
wholesale            regional market participants such as bid-based         Replace subregional T SOs/market facilitators with
competition          balancing market, day-ahead market, intraday           regional market operator with responsibility for all
supported by         market, emissions trading market, and so on.           functional regional financial markets that are not
multiple             Promote an economic-dispatch outcome                   implemented and operated by private sector entities.
financial            consistent with objectives of competition,             Disband secretariat and give full regional market
markets              sustainability, and reliability/security of supply.    oversight responsibility to regional market operator,
                     Consistent with needs of regional market,              regional T SO, and regional regulator, with oversight by
                     further improve transmission capacity and              Arab Ministerial Council for Electricity.
                     synchronization at national and international          Modify regional market governance documents as
                     levels.                                                necessary to incorporate full wholesale competition and
                                                                            newly formed financial markets.
                                                                            Ensure regional market institutions have full
                                                                            responsibility to establish transmission tariffs and
                                                                            enforce uniform t echnical and financial rules across
                                                                            regional market.
Stage 4:             T he three subregions are interconnected and           Prepare and implement a unified Pan-Arab power
Fully integrated     synchronized (or asynchronized) including              development plan (could include three binding
Arab regional        countries not currently interconnected with any        subregional development plans that align with national
market focusing      of the subregions.                                     plans and cover both conventional and renewable
on fully             T he region is also synchronized with the              generation and transmission).
interconnected       ENT SO-E and other markets in the surrounding          Develop a plan for synchronization (or asynchronization)
and                  area.                                                  of the three subregions, and synchronization (or
synchronized         T here is open access to all transmission and full     asynchronization) with the ENT SO-E and other REMs in
Arab electricity     wholesale competition with fully functional            the surrounding region.
network              regional market institutions and governance
                     documentation.
Note: TSO = transmission system operator; GCC = Gulf Cooperation Council; EIJLLPST = Eight-country Interconnection (Egypt, Iraq, Jordan,
Libya, Lebanon, Palestine, Syria, and Turkey); ENTSO-E = European Network for Transmission System Operators - Electricity; REM = regional
electricity market.

As mentioned earlier, the above four stages of market development depict a long-term path
toward achieving an integrated Pan-Arab electricity market. Although the four-stage strategy
should provide the framework for institution building and policy decisions, the main emphasis
here is on articulating the details of what needs to be achieved during stage 1. Accordingly, the
remainder of this chapter presents a regional-market design for stage 1, developing detailed
recommendations about the institutional and policy decisions to be taken during this stage.
5.4       Transitional Regional Electricity Market Design: Stage 1
5.4.1 Market Design
Currently, a number of Arab countries are not physically interconnected; furthermore, many of
the Arab countries are not synchronized with one another, and do not meet what might be judged
to be the minimum technical requirements for the design and operation of their power systems. A
country is not likely to trade with another country if by doing so it is placing its own customers
at risk of reduced reliability. Therefore, it is proposed that the transitional REM design be
implemented in each of the existing REMs:
GCC, including Saudi Arabia, Bahrain, Kuwait, Qatar, the UAE, and Oman.
EIJLLPST, including Egypt, Iraq, Jordan, Libya, Lebanon, Palestine, and Syria.
Maghreb, including Morocco, Algeria, and Tunisia.

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The GCC, EIJLLPST, and Maghreb are at different stages of development and the countries
within these regional markets have different levels of commitment to reform. Therefore, it is
proposed that each country commit to implementation of the proposed transitional regional
market design, but each subregional electricity market would proceed with implementation of the
transitional market at its own pace, consistent with direction given by the regional market
institutions.
Currently, the three subregional markets of the GCC, EIJLLPST, and Maghreb must operate
independently because they are either not interconnected or not synchronized. But this may
change in the future. For example, an interconnection is planned for construction between Saudi
Arabia and Egypt. Once completed, consideration might be given to merging the GCC and
EIJLLPST regional markets into a single REM during Stage 1, or possibly during subsequent
stages of the proposed regional-market development plan. Ultimately, it is anticipated that the
three Arab subregional markets will merge into one, and might subsequently be merged with
markets outside the Arab countries such as the EU, markets east in Asia, and/or markets south in
Africa.
Other Arab countries that are not currently interconnected with any of the three subregional
markets (Mauritania, Sudan, Yemen, Somalia, Djibouti, and Comoros) would be allowed to
petition to join any of the three subregional markets if they so desire once they are physically
interconnected and synchronized, and meet minimum design and operating requirements to
ensure reliability. The merits of the petition would be determined by regional institutions that
have been delegated the authority to make such decisions. The goal would be for these countries
to be willingly accepted into the subregional markets once they meet minimum reliability
requirements and agree to follow the market governance documentation.
5.4.2 Salient Features of Proposed Transitional Regional Electricity Market Design:
Stage 1
As outlined above, the first stage of the proposed transitional-regional-market design requires
progress in a variety of areas, including grid access, reliability, market transparency, bilateral
contracts, market access, and market surveillance.
Grid access
Regional-market participants approved in market-governance documents will have transparent,
fair, and nondiscriminatory access to the national grids and international interconnections,
meaning there will be no legal, administrative, or discriminatory barriers to the transmission
networks.
Transmission tariffs will reflect costs and will be harmonized among the countries in the
subregional markets. Costs of current and future investments will be included in the tariffs as
will costs of operation, maintenance, losses, and ancillary services such as the balancing
necessary to support trade.
Cross-border transmission capacity will be allocated based on transparent capacity auctions.
Available transmission capacity will be calculated in a transparent and nondiscriminatory
manner based on real physical bottlenecks.
Reliability



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There will be a clear and readily accessible regional grid code that will govern all national
electricity markets. The national electricity markets must prove to the regional advisory and
regulatory committee that they meet the minimum requirements set out in the regional grid code,
or otherwise have acceptable plans in place to meet such minimum requirements in a timely
manner.
Market transparency
There will be timely and nondiscriminatory access to information related to market prices in each
national electricity market to promote transparency and enable regional-market participants to
make informed choices when negotiating bilateral contracts. Market prices will not be
compulsory, meaning regional-market participants will freely negotiate prices and terms in
bilateral contracts. The subregional TSOs/market facilitators will publish standardized contracts
to assist regional-market participants with bilateral trade.
Bilateral contracts verification process
The parties to a bilateral contract will file their bilateral contracts with their respective
subregional TSO/market facilitator who will in turn inform each impacted national TSO of the
proposed trade. The subregional TSO/market facilitator will verify in a timely manner if the
transaction is technically feasible, and if not, will publish the reasons why. Discrepancies
between the subregional TSO/market facilitator and national TSOs will be settled by the regional
advisory and regulatory committee when the parties are unable to resolve the issue themselves.
Market access
Regional-market participants will be qualified and authorized/registered to participate in the
regional market. They will agree to abide by requirements set out in regional-market
documentation including provisions of any credit guarantees.
Market surveillance
Market surveillance will be the responsibility of all parties including the national TSOs, the
national regulators, and the subregional TSOs/market facilitators. Each subregional TSO/market
facilitator will be responsible for monitoring trading activities to determine if regional-market
participants and the regional market are behaving in a manner consistent with the spirit and
intent of the market-governance documentation. The regional advisory and regulatory committee
will conduct investigations when it believes a breach of the rules and regulations has occurred.
All information acquired during investigations will be treated as confidential.
5.4.3 Regional Market Participants and Their Roles in Stage 1
The preceding sections have mentioned a variety of participants in the proposed regional market,
each with its own responsibilities. Each of the subregional markets including the GCC,
EIJLLPST, and Maghreb will have its own set of market participants as summarized in table 5.2.
                Table 5.2 Summary of regional market participant responsibilities
Regional market participant                                Role                           Primary responsibility
Sub-regional T SO/market facilitator   Publish market prices, verify technical    Facilitate trade in REM.
                                       feasibility of regional trade, conduct
                                       auctions for interconnection capacity,
                                       and coordinate billing and settlement of
                                       transmission service for international
                                       trades.


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National T SOs                      T ransmit electricity and ensure third-   Balance the national power systems.
                                    party access.
Regional market participants        T rade electricity services through       Provide and/or secure capacity and/or
                                    bilateral contracts.                      energy.
National regulators                 Regulate proper functioning of market.    Monitor market and take action when
                                                                              market participants are not in
                                                                              compliance with governance
                                                                              documentation.

The participants’ roles in Stage 1 of the transitional regional market are as follows.
Subregional transmission system operator (TSO)/market facilitator
The subregional TSOs/market facilitators will be subregional entities (that is, there will be one
for each of the GCC, EIJLLPST, and Maghreb) regulated by the regional advisory and regulatory
committee to ensure their transparency, nondiscrimination, and independence. They will
coordinate closely with the national TSOs, particularly with regard to available transmission
capacity. They will be responsible for facilitating and identifying trade opportunities and will
publish a report on regional trade, subject to confidentiality considerations, at least annually, and
more often as necessary. Their responsibilities will include:
        Determining and publishing nonbinding national market prices based on international
         fuel prices.
        Verifying the technical feasibility of bilateral-contract transactions.
        Auctioning interconnection capacity.
        Billing and settlement for transmission services for international transactions.
        Market surveillance.
National transmission system operator (TSO)
The national TSOs will retain control and responsibility for operating and planning the national
transmission networks. They will be regulated entities providing third-party access to the
transmission grid on a nondiscriminatory basis, meaning regional entities will have the same
rights to the transmission system as national entities. Although operating at a national level,
TSOs will coordinate activities with their respective subregional TSO/market facilitator and
TSOs in neighboring countries. The TSOs will be vital to the operation of the integrated REM.
TSOs will be responsible for balancing their national systems and providing ancillary services to
all network users in their country. Each TSO will be responsible for:
        Ensuring adequate transmission capacity is available to meet the short- and long-term
         demands for transmission service in a reliable and secure manner.
        Balancing the national power system on a moment-to-moment basis, including providing
         ancillary services, taking into account exchanges with other countries.
        Exchanging information with TSOs of other interconnected systems necessary to ensure
         secure and efficient operation and the coordinated development and interoperability of
         the interconnected system.
        Ensuring nondiscriminatory transmission service for regional-market participants and
         other TSOs.

                                                      131
      Publishing information needed by transmission users, such as tariffs, in a timely and
       nondiscriminatory manner.
      Coordinating timely and regularly with their respective subregional TSO/market
       facilitator on available transmission capacity including capacity on the international
       interconnections.
      Preserving the confidentiality of commercially sensitive information and promoting
       greater efficiency in the national and REMs.
Qualified regional-market participants
Qualified regional-market participants will have the right to offer and procure capacity and
energy through freely negotiated bilateral contracts with other qualified regional-market
participants and TSOs in the regional market. The subregional TSOs/market facilitators will
maintain a current list of qualified regional-market participants for their respective markets.
Regulators
Each country will have a regulatory authority to ensure effective and efficient operation of the
national and REMs and that regional-market participants, TSOs, and customers are treated in a
fair and nondiscriminatory manner. The regulator will monitor and report on the electricity sector
to ensure compliance with technical standards and performance benchmarks, including:
      The management and allocation of interconnection capacity.
      Mechanisms that deal with transmission congestion within the national electricity system.
      Performance of the transmission entities.
      Information relating to interconnections, grid use, and capacity allocation as provided by
       TSOs.
      Risk of cross-subsidization between transmission activities and other activities in the
       national electricity markets.
      The extent to which TSOs complete their tasks and are in compliance with rules relating
       to third-party access, congestion, and interconnection management.
      TSO investment plans, assessing consistency with regionwide investment plans.
      Network security and reliability.
      Network security and reliability rules.
      Transparency.
      Effectiveness of consumer-protection measures.
The national regulators will cooperate at the regional level with the regional advisory and
regulatory committee.
The high-level description of the proposed transitional regional market design is provided in
table 5.3. Figure 5.3 illustrates the relationships among these market participants.




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                   Table 5.3 High-level description of transitional REM design

   Each country required to meet minimum reliability criteria as documented in Regional Grid Code.

   Eligible regional market participants free to negotiate bilateral contracts for capacity or energy with any other eligible
    regional market participant in the relevant regional market.

   T he technical feasibility of bilateral contracts must be confirmed in advance by the subregional T SO/market facilitator
    who in turn informs each national T SO impacted by the transaction.
   Fair and open access to the transmission networks of each country at published terms, conditions, and prices.
    T ransmission service harmonized across each subregional market.
   T ransmission service tariff recovers cost of capital and operation and maintenance of transmission assets, losses, and
    other ancillary services necessary to support bilateral contracts transactions. T ariffs will also recover the cost of
    network expansion.
   Allocation of cross-border transmission capacity based on auctions to eliminate bottlenecks when they arise.
    Calculation of available transmission capacity in a transparent and nondiscriminatory manner based on real physical
    bottlenecks.
   T he role of the subregional T SO/market facilitator is to facilitate trade at the subregional level. T he subregional
    T SO/market facilitator will publish market prices for each country based on each country’s marginal production cost
    using international fuel prices as the basis. T he market prices will be non binding, intended to identify trade
    opportunities, and provide a reference price for use in freely negotiated bilateral contracts.
   When national T SOs claim that a bilateral contract cannot be physically transacted, the subregional T SO/market
    facilitator will verify such claims. T he subregional T SO/market facilitator’s verification will be nonbinding, but if
    differences arise between national T SOs and the subregional T SO/market facilitator, the regional advisory and
    regulatory committee will be called on to conduct a review and render a decision that is binding on the parties.

   T here will be three subregional T SOs/market facilitators, at least initially, one for each of the three subregional
    markets. T he subregional T SOs/market facilitators will be independent , and include a number of committees; i.e.,
    planning and operating committees).




                                                           133
                     Figure 5.3 Transactions in proposed transitional REM



                              Regional market participants—sellers




                           Subregional
                           TSO/market                     National TX
                            facilitator/                   networks
                             national
                              TSOs




                              Regional market participants —buyers




                Bilateral contracts                            Physical power flows

5.4.3 Regional Market Institutions
As mentioned above, the transitional regional market envisages the creation of three new
regional institutions—a regional Arab TSOs committee, a regional advisory and regulatory
committee, and a secretariat. These three regional institutions will provide oversight of the REM,
including all Arab countries whether or not they are currently interconnected with any of the
three subregional markets, to ensure consistency, fairness, and reciprocity.
Some regional groups with similar roles are already active among the Arab countries. Two such
groups, the Arab Union of Electricity (AUE) and the Arab Electricity Regulators’ Forum
(AERF), might be modified to become the necessary regional-market institutions. The AUE
comprises Algeria, Bahrain, Egypt, Iraq, Jordan, Lebanon, Libya, Mauritania, Morocco, Oman,
Palestine, Qatar, Saudi Arabia, Sudan, Syria, Tunisia, the UAE, and Yemen. Established in 1987
by a group of Arab electrical companies, the aim of this forum is to strengthen ties among
members to improve power manufacturing in the Arab world. The AERF, which comprises

                                               134
Algeria, Bahrain, Egypt, Jordan, Lebanon, Palestine, Oman, Qatar, Saudi Arabia, and the UAE,
is a consultative assembly of authorities for regulating and restructuring the electricity sectors in
their respective countries.
In the longer term, the regional Arab TSOs committee, the regional advisory and regulatory
committee and the secretariat should be performed by formal entities. However, in the interim
period these functions should be created in a manner that avoids additional financial
commitments from the member countries. To this end, the proposed functions should be
organized by drawing upon the existing entities. Therefore, it is proposed that:
      The regional advisory and regulatory function and the regional TSO function be formed
       by establishing two corresponding committees and inviting appropriate membership
       relevant to the function of each committee. In addition, relevant stakeholders such as the
       Arab Union for Electricity and the Arab Electricity Regulators Forum would be invited to
       participate in the relevant committees.
      The secretariat function would be taken up by the (Energy Department) LAS Secretariat.
Figure 5.4 illustrates how the three proposed new regional-market institutions fit into the
regulatory scheme. The responsibilities of each institution are summarized in table 5.4.
It may be desirable to combine the regional advisory and regulatory committee and the
secretariat into a single Arab regional-market entity (perhaps to be known as the Arab regional
advisory and regulatory committee).
                 Figure 5.4 Proposed regional market institutional structure




                                                 Arab Ministerial Council for
                                                        Electricity




                                                       Executive Bureau



                 Sub-regional TSOs
                                      Regional
                                     Arab TSOs         LAS Secretariat          Regional Advisory and
                                     Committee                                  Regulatory Committee
                 Member country
                     TSOs




      Table 5.4 Regional institutions for transitional regional electricity market: Stage 1


                                                 135
Institution                     Responsibilities
Regional advisory and           Review and advise on market governance documents, changes to Grid Code,
regulatory committee            transmission tariffs, generation reserve criteria, cross-border transmission
                                allocation, available transmission capacity, and so on.
                                Ensure compliance with governance documentation including
                                nondiscriminatory access
                                Market surveillance.
                                Dispute resolution.
Regional Arab TSOs              Coordinate and cooperate with national TSOs.
committee                       Play active role in rule-setting process.
                                Promote market integration, reliability, and security of supply.
                                Research and development, promote public acceptability.
                                Participate in energy policy.
Secretariat                     Provide administrative support to regional market entities.
                                Ensure parties carry out their obligations.
                                Maintain comprehensive information systems.
                                Carry out other tasks as assigned.
Note: TSO = transmission system operator.

5.4.3.1 Regional Arab TSOs Committee
During Stage 1 of the transitional regional market, the regional Arab TSOs committee will not
have specific roles and responsibilities —this will lie with the subregional TSOs/market
facilitators and national TSOs. Instead, the committee will be a forum whose purpose will be the
exchange and promotion of ideas to improve and progress the regional market with the following
roles:
       Cooperation among national TSOs.
       Market integration, reliability and security of supply, efficiency, and technical
        innovation.
       Coordinated implementation of network plans.
       Coordinated administration of network codes.
       Research and development.
       Public acceptability.
       Energy policy including as necessary preparing positions and consultation on
        environmental and renewable initiatives.
It is recommended that the committee meet annually and more often when considered beneficial.
The annual meeting will be attended by representatives of the TSOs in the three regional markets
and the countries that are not currently participating in any of the regional markets. The meetings
will include representatives from the subregional TSOs/market facilitators, the LAS secretariat,
the AUE and the regional advisory and regulatory committee. The annual meetings will enable
the exchange of ideas and experiences, and enable each country and subregional market to gain
perspective on current events and undertakings elsewhere in the Arab world.
It is anticipated that following implementation of subsequent stages of the regional-market
reform (stage two and beyond), the committee will become a going concern with a board of
directors and a full complement of regular staff. The Board would be made up of senior staff
members of the national TSOs. Ultimately, the association will have similar roles and

                                                      136
responsibilities as the European Network of Transmission System Operators for Electricity
(ENTSO-E). Its purpose will be to coordinate and cooperate with national TSOs, promote the
interests of national TSOs, and play an active role in the rule-setting process.
5.4.3.2 Regional Advisory and Regulatory Committee
The regional advisory and regulatory committee will have the following duties and
responsibilities. It will not have approval authority, but rather will send advisories to the
Executive Bureau which will approve the advisory, or alternatively, send the advisory to the
Arab Ministerial Council for Electricity for approval.
      Reviewing and advising on regional-market governance documents including the
regional grid code and the general regional electricity market agreement.
      Approving subsequent changes to the grid code.
      Ensuring compliance with regional-market governance documentation.
      Reviewing and advising on each member country’s national transmission tariff.
      Ensuring that transmission tariffs are applied in a fair and nondiscriminatory manner.
      Reviewing and advising on generation-reserve criteria.
      Reviewing and advising on rules governing allocation of cross-border transmission
capacity to eliminate bottlenecks.
      Reviewing and advising on the methodology for calculation of available transmission
capacity.
       Regulation of the subregional TSOs/market facilitators and the national TSOs with regard
to the regional market.
       Market surveillance to ensure regional-market participants and the regional market are
functioning consistent with the spirit and intent of the market objectives.
      Advising on credit obligations and payment-default procedures.
      Reviewing proposals for expansion of international interconnections.
      Dispute resolution.
      Coordinating with national regulatory entities.
The committee will be staffed through invitation of appropriate membership relevant to the
function of the committee, but is anticipated to include one member from each of the countries
participating in the regional market. Each country will be responsible for nominating a senior
member of the entity responsible for regulating its power sector. No member will be entitled to
remuneration incurred in the performance of its duties as a member of the committee. Decisions
will be approved by simple majority and chairmanship will be rotated among the members. The
regional advisory and regulatory committee will meet regularly, at least every quarter, and will
draw on the support and expertise of the LAS secretariat as necessary. The AERF will attend the
meetings of the regional advisory and regulatory committee as necessary.
5.4.3.3 Secretariat


                                               137
The role of the secretariat will be to move the regional-market-integration process forward. 63 Its
main responsibilities will include:
        Providing administrative support to other regional-market institutions.
        Reviewing proper implementation of governing documents and submitting yearly
         progress reports to the Arab Ministerial Council for Electricity and Executive Bureau.
        Building and maintaining comprehensive information systems with up-to-date data on
         member countries’ expansion plans, regulatory c hanges, and so on.
        Other tasks as assigned by the Arab Ministerial Council for Electricity and Executive
         Bureau or by market governance documentation.
The secretariat will include staff with expertise in most areas of electricity-market reform and
design, but will be allowed to contract outside assistance when comprehensive areas of expertise
are needed. As already discussed, it may be desirable to combine the regional advisory and
regulatory committee and the secretariat into a single entity.
5.4.4 Transitional-Regional-Market Governance Documentation
The transitional-regional-market design calls for four principle documents to meet the objectives
of the REM and ensure the basic tenets of fairness, nondiscrimination, and reciprocity:
        Memorandum of understanding (MOU)
        General agreement
        General Pan-Arab electricity market agreement
        Regional grid code
While the MOU and the general agreement would cover all Arab countries, it is anticipated that
the three subregional markets would have their own versions of the general Pan-Arab electricity
market agreement64 and regional grid code, although the basic principles covered in each region
would be the same.
A brief description of the content of each document is provided below and a summary is
provided in table 5.5. Greater detail of the content of governance documentation and the
framework for such documentation applicable to the recommended transitional regional market
design is provided in Volume 2.
        Table 5.5 Regional market governance documentation for transitional REM: Stage 1




63
   T his pertains t o all regional integration initiatives including: the GCC, Maghreb, and EIJLLPST interconnections, the Nile
Basin Initiative (NBI), and the joint ownership and sharing of hydrogeneration and transmission capacity among Guinea, Mali,
Mauritania, and Senegal. T he secretariat would need to draw upon the accomplishments and activities of these entities to carry
out its duties.
64
   T he fact that the GCC interconnection is a shared facility constructed by the member states requires that regional -market
governance documentation be somewhat different from that of EIJLLPST and Maghreb, which do not have such shared facilities.



                                                             138
Document                              Primary content
Memorandum of understanding           Commitment of Arab countries to REM integration.
                                      Legal basis for regional market and subsequent reforms.
                                      Legal basis for regional market institutions.
General agreement                     Objectives and guiding principles for development of REM.

                                      Formation of, and roles and responsibilities of regional institutions.
                                      Bylaws of regional institutions; i.e., membership, chairperson, meetings, voting rights, expenses,
                                      remuneration, etc.
General Pan-Arab electricity market   Specifies commercial aspects of regional market, including operation, participation, and
agreement                             administration.
                                      Roles and responsibilities.
                                      Metering, billing, and settlement.
Regional grid code                    Specifies minimum technical requirements for operation and planning national transmission
                                      networks and international interconnections.
                                      Roles and responsibilities.
                                      Reporting requirements.

5.4.4.1 Memorandum of Understanding (MOU)
The MOU would be a high-level document signed by the Arab Ministerial Council for Electricity
with the purpose of establishing their commitment to pursue market integration and reform. It
establishes the intergovernmental framework and legal basis for the regional market and its
supporting institutional infrastructure. Examples of such documents include the Marco Treaty in
Central America and the Energy Community Treaty in southeast Europe. In effect, all market
governance documentation stems from the MOU, which would cover the following:
      The commitment of the countries to regional integration and cooperation in the
development of a REM.
         The legal basis for the regional market and subsequent reforms.
         The legal basis for the regional institutions.
5.4.4.2 General Agreement
The general agreement would be signed by the governments of the member states, and would set
out the objectives and principles of the REM and identify the roles and responsibilities of the
regional-market institutions. The document would cover:
         The objectives and guiding principles to be followed in the development of the REM.
         Formation, roles, and responsibilities of the regional institutions.
      Bylaws of regional institutions; i.e., membership, chairperson, meetings, voting rights,
expenses, remuneration, etc.
5.4.4.3 General Pan-Arab Electricity Market Agreement
The general Pan-Arab electricity market agreement would be a lower-level document that
provides more detail governing how the countries will meet the commitments identified in the
MOU and the general agreement. It will cover commercial aspects of the regional market, in
effect, incorporating the market rules (or commercial code). The GCC provides a good example
of a general regional electricity market agreement (known as the “General Agreement Relating
to the Interconnector”), as does the EIJLLPST interconnection (known as the “General
Interconnection Agreement for the Electrical Interconnection among the Five Electrical Power
Utilities of Egypt, Iraq, Jordan, Syria and Turkey [EIJST]”).
The agreement would cover:

                                                                  139
      Authorization and commitment of the parties.
      Objectives.
      Definitions.
      Description of the regional market.
      Legal status, roles, and responsibilities of the regional-market institutions.
      Identification and roles and responsibilities of regional-market participants.
      Services to be traded and procedures for trade.
      Responsibilities and payment for transmission services.
      Metering, billing, settlement, and payment guarantees.
      Planning and coordination.
      Operation and maintenance practices.
      Exchange and publishing of information.
      Administrative matters such as force majeure, confidentiality, liability, applicable law,
review and amendment, dispute resolution, effective date, validity, and termination.
5.4.4.4 Regional Grid Code
A grid code is a document that legally establishes the technical requirements for the connection
to, and use of, the transmission system by network users in a manner that ensures reliable,
efficient, and safe operation. Grid codes become necessary due to changes in regulatory
structure, industry structure (that is, unbundling), or industry ownership, and the need for “open
access” to the transmission system. The grid code enables the TSO to manage the high -voltage
transmission network in a safe, secure, and economical manner. It provides a level playing field
for the nondiscriminatory and transparent use of the transmission network. In Europe, the
Operation Handbook serves as the grid code.
At the national level, the national TSO is responsible for ensuring that market participants
comply with the grid code. The grid code is generally approved by the national regulatory
authority and updated as necessary through a defined process, with changes also approved by the
regulator. At the regional level, the regional advisory and regulatory committee will be
responsible for ensuring each national grid code meets the minimum requirements set out in the
regional grid code.
Grid codes are legally binding on all parties and provide guidance for interfaces between the
network and the network users, including generators, distributors, nonembedded consumers, and
external interconnections. It specifies the duties of both network users and the TSO. Its purpose
is to bring the power systems in all countries up to a minimum standard to ensure that
international interconnections are not detrimental to the overall reliability of the interconnected
power systems.
The regional grid code should comprise the following sections:
      Definitions : Set industry standards.


                                                 140
   Planning : Define roles in the development and expansion of the network.
   Connection: Set asset boundaries and ensures compliance.
   Demand forecasting : Provide for data collection from market participants to improve
    accuracy of forecast.
   Outage scheduling: Provide for authorization and approval of transmission and
    generation maintenance schedules.
   Frequency and voltage control: Specify procedures for setting frequency and voltage
    control to meet relevant standards.
   Operating margins: Provide for adequate response and reserves for sufficient system
    regulation.
   Testing and monitoring: Enable assessment of user compliance.
   Demand control: Provide action plans to cover generation/demand mismatch under
    either planned or emergency conditions.
   Information exchange: Set agreed level of disclosure.
   Safety coordination: Provide for common safety practices by all users at connection
    sites.
   Contingency planning: Set procedures and obligations for contingencies.
   High-voltage apparatus identification: Establish procedures to minimize risk of
    conflicting configurations.
   System tests: Formalize requirements for arranging tests for simulating conditions on the
    system.
   Scheduling and dispatch: Set out responsibilities of market participants for system
    operation.
   Metering: Set out minimum technical requirements of metering installations
   Data registration: Set out data-reporting requirements
   General conditions: Set out procedures for grid-code review, dispute resolution, rules
    change process, and other miscellany.




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6      Next Steps
This report has proposed a transition path to help Arab countries move gradually from the
current status of their electricity markets to an “ultimate” integrated regional market that would
enable efficient and open participation by all market players in cross-border trade. The proposed
transitional market design will go a long way toward meeting the Arab countries’ objectives
relating to sustainability, reliability, and security of supply without the need for significant
national power sector reform. This will allow time for the Arab countries to eliminate constraints
and mitigate risks associated with the more-complex market designs proposed for later stages of
regional-market integration.
As mentioned at the outset, this report covers the first of two phases of a study on the
development of the institutional and regulatory framework for electricity trade in the Arab world.
The second phase (Volume II) focuses on articulating the governance and legal framework for
the market and providing technical support for the dialog among the relevant stakeholders. Phase
2 of the study addresses:
      Preparation of governance documents. The immediate priority is to assist in preparing
the four governance documents discussed above: a memorandum of understanding, a general
agreement, a general regional electricity market agreement, and a regional grid code.
      Creating the legal authority and governing institutions.
      Establishing the terms under which electricity will be traded, including the conditions for
access to interconnections, the basis for determination and allocation of available interconnection
capacity, and the basis for pricing of access and use of available interconnection capacity.
      Establishing the principles relating to operational, control, and connection requirements
on national and regional systems including operating procedures governing dispatch during
system emergencies, metering quality at points of interconnections, and billing and settlement.
      Establishing the principles and process for rulemaking and dispute resolution.
       Preparation of a roadmap and action plan for market integration and negotiations. The
governance documents will develop steps for institutional setup and market harmonization, and
the second phase must propose a roadmap and action plan that can be used by the Arab countries
to implement these steps. The report will also provide support, as required, for negotiation of the
governance documents.
The above tasks would pursue two distinct objectives: (i) supporting each subregion as it moves
toward market integration while identifying and promoting opportunities for increased cross-
border trade volume; and (ii) creating the institutional infrastructure for a Pan-Arab electricity
network. In regard to the first objective, the three subregions are in distinct situations and may
require different types of support. The GCC has a well-designed organizational setup and a
systematic approach to encouraging trade transactions among the participating countries, but
EIJLLPST and Maghreb have limited functional organizational capacity. Phase 2 of the study
will attempt to bring to the attention of the Arab countries lessons from international experience
in increasing trade volume and, more importantly, will assist in transferring international
experience to the subregions. In regard to the second objective, Phase 2 of the study will support
the development of consensus among Arab countries while also assisting in capacity building.
Account will be taken of existing governance documentation of each subregion when preparing

                                                142
the governance documentation for the Pan-Arab region. Phase 2 of the study will also help in
developing the terms of reference for the various regional entities, and if appropriate, in setting
up the proposed secretariat. The study brings about a comparative advantage in identifying the
relevant required skills and the options to access and recruit such expertise.
Interactions between this study and the other LAS studies: As mentioned earlier this joint
League of Arab States (LAS)– World Bank study constitutes part of a broader three-part effort
being launched by the LAS and its development partners. The three parts are as follows:
Part I: Study of Interconnections of Electrical Systems in the Arab World.
Part II: Study of Electricity-Gas Trade among the Arab Countries.
Part III: Study of Institutional and Regulatory Frameworks (this joint LAS– World Bank study).
Therefore, this LAS– World Bank study is interlinked with the other two studies. In particular,
this study must be consistent with the Part I study regarding energy profiles of Arab countries,
the generation expansion plans of each country, the plans for future interconnections, and the
present and future potential for electricity trade among Arab countries. Though the Part I study
was not yet complete, the LAS and the World Bank decided to proceed with the Part III study
based on the World Bank’s previous work on the technical feasibility of electricity
interconnections in the Arab world to progress the regional-integration agenda. While this
arrangement does not preempt the need for the Part I study, it has enabled the LAS and the
World Bank to analyze and deliberate the institutional and regulatory issues involved in
integrating the power networks of the Arab countries. It has at the same time fully understood
that the results of the Part I study will be analyzed and incorporated in the final report of this
LAS– World Bank joint study as soon as the Part I study is completed.
Interaction between this study, the World Bank’s gas -trade study, and the Part II gas -trade
study: Because development and trade of natural gas in the Arab world may have a significant
impact on cross-border electricity trade, the LAS intends to carry out a gas-trade study among
Arab countries. The World Bank also plans to review the opportunities and constraints in cross-
border gas development in the Arab world. The two studies are considered complimentary as the
LAS study will concentrate on the technical aspects of the subject matter, and the World Bank
study will focus on the policy issues. Both of these studies could also have implications for
electricity trade. In particular, there are various trade-offs in the costs and benefits of electricity
versus gas interconnections that are normally taken into account by the policy makers of each
country while addressing cross-border energy trade. There are also collective benefits that would
emerge if one takes a regional perspective in assessing the optimum use of energy resources.
This LAS– World Bank study (Part III) will be updated to take account of the conclusions and
possible implications of both gas-trade studies as soon as the results are available. In particular,
the World Bank gas-trade study will address the regulatory and contractual aspects of cross-
border gas trade, which could affect so-called gas-to-gas versus gas-to-power competition. It is
therefore important to align the development of legal and regulatory frameworks of cross-border
electricity and gas trade.




                                                 143
Volume II: Attachments




          144
                            Attachment 2.A
                          Retail Tariff Analysis
As discussed throughout this report, retail tariffs in the Arab countries are generally far below the
economic cost of supply. Subsidized energy prices negatively impact trade because they place
power companies in a precarious financial position, making it difficult for them to raise funds to
invest themselves, and denying them the cash flow necessary to pay their suppliers. Traders and
investors are highly unlikely to make deals with power companies that are not in a position to
pay for services provided - they will simply look elsewhere for more credit-worthy off-takers. If
they do decide to deal with customers who are not credit-worthy, they will require a significant
mark-up, or risk premium, to compensate for the increased risk, leading to higher electricity
prices (or a further deterioration in the company’s creditworthiness). Traders and investors may
require payment guarantees which may not be forthcoming from commercial banks and/or
Governments. This is particularly important to investors/traders in energy because they are the
last in the chain to get paid; i.e., retail customers pay the distribution company which in turn pays
the single buyer which in turn pays the generators.
A fundamental problem in the region is the near absence of what would be considered
“independent and informed” regulation. Tariffs have often been established on the basis of
political expediency and do not reflect the economic cost of supply. This holds for both
electricity and primary fuels for generation such as gas and oil. The Governments convey
substantial subsidies to the domestic energy sectors, and cross-subsidization between and within
customer classes goes well beyond assistance for the socially disadvantaged. In some cases, large
segments of the population are unable to pay prices that reflect the economic cost of supply, but
the difficult challenge facing Governments is that the long history of subsidization and cross-
subsidization in the prices of fuels and electricity have resulted in an unwillingness of the
population to pay for energy. It is a difficult task to eliminate the complex system of subsidies
that have developed over the years.
Countries that are energy deficient are under pressure to reduce subsidization because the
subsidies are taking a significant toll on the government budget. Even countries that are
relatively rich in energy resources will be unable to sustain subsidies indefinitely, particularly
under the very high levels of growth in energy consumption forecast for the Arab countries in the
immediate and longer terms. In addition to the problems relating to investment and trade,
subsidies lead to a number of performance, efficiency and resource allocation issues, including:
       Utilities do not have the funds necessary to maintain, let alone expand the system to meet
increasing demands and replace retired plant, thus leading to decreased reliability;
      The signals for investment are distorted, leading to less than optimal investment decisions
and higher energy costs; and
      Subsidies distort consumption decisions resulting in an inefficient allocation of resources.
Generally, subsidized prices lead to increased consumption, and provide incentives for
consumers to use the subsidized energy form rather than alternative energy forms that may be
more economic in certain applications.


                                                145
The use of subsidies distorts investment, production and consumption decisions, leading to
significant costs that are largely hidden. The costs of energy production and delivery are incurred
whether or not they are reflected in tariffs. By not reflecting economic costs in tariffs consumers
are making unwise consumption decisions that result in even higher costs of energy supply and
delivery, and/or further reductions in the reliability and quality of supply.
Electricity tariffs for residential and industrial customers in the Arab countries are shown in table
1. The tariffs shown include taxes. The average tariff for the residential class is based on a
monthly consumption of 500 kWh. The tariff for industrial customers is for supply at high
voltage. The Iraq figures are based on tariffs for Kurdistan, the UAE figures are based on tariffs
for Abu Dhabi. The average shown is a simple average of the residential and industrial tariff.
It can be difficult to determine the actual cost of electricity supply in many Arab countries
because the subsidies provided by Government to the energy sector are largely hidden. However,
a good proxy of the level of subsidization is provided by comparing tariffs to a benchmark based
on the average of the tariffs of countries whose tariffs reflect the full economic cost of supply.
The February 2009 World Bank report referenced earlier provides such a comparison of
countries in the Middle East and Africa to a benchmark based on an average of the tariffs of
France, Greece, Italy, Spain, Portugal and Turkey. This benchmark provides a reasonable
approximation of the opportunity cost of electricity. For comparison purposes, this “EU
benchmark” is included in table 1. As can be seen, the average of the tariffs of the Arab countries
is far below the EU benchmark. In fact, the average residential tariff in Arab countries is only 43
percent of the EU benchmark tariff, and the average industrial tariff is only 46 percent of the EU
benchmark tariff. Tariffs would be far less relative to the EU benchmark if it were not for the
very high tariff levels in Djibouti, Mauritania and Palestine. Tariffs for residential and industrial
tariffs in the region are compared graphically in figures 1 and 2, respectively.
The cross-subsidization in the tariff systems is evidenced by the fact that in many cases the
industrial tariff is greater than the residential tariff. Tariffs for residential customers should be
higher than tariffs for industrial customers because it costs more to supply them. More facilities
(i.e., transformers and distribution lines and substations) are needed and greater losses are
incurred to supply residential customers because they are supplied at lower voltage levels. As
can be seen in the EU benchmark case, industrial tariffs are lower than residential tariffs. Cross-
subsidization in the tariff regime results in many of the same problems discussed above; in
particular, it distorts consumption decisions and leads to an inefficient allocation of resources. It
can also make a country’s industry less competitive internationally leading to job loss.




                                                146
                              Table 1: Electricity Tariff Comparison (US cents/kWh)
       Country                              Residential                 Industrial                    Average*
       Saudi Arabia                             1.3                        3.2                           2.3
       Kuwait                                   0.8                        0.4                           0.6
       Bahrain                                  0.8                        4.4                           2.6
       Qatar                                    2.2                        1.9                           2.0
       UAE65                                    5.0                       15.0                          10.0
       Oman                                     2.6                        4.7                           3.6
       Yemen                                    4.8                        8.7                           6.8
       Egypt                                    2.5                        2.5                           2.5
       Iraq                                     0.7                        1.6                           1.2
       Jordan                                   7.5                        6.7                           7.1
       Syria                                    1.1                        8.9                           5.0
       Lebanon                                  4.6                        7.6                           6.1
       Palestine                               17.3                       10.8                          14.1
       Morocco                                 12.7                        9.7                          11.2
       Algeria                                  6.2                        3.6                           4.9
       Tunisia                                 12.3                        6.7                           9.5
       Libya                                    2.0                        2.5                           2.3
       Djibouti                                31.8                       19.7                          25.7
       Sudan                                    8.7                        8.7                           8.7
       Mauritania                               24                         24                            24
       Somalia                                 N/A                         N/A                          N/A
       Comoros                                 N/A                         N/A                          N/A
       Arab Country Average                     7.5                        7.6                           7.5
       EU Benchmark                            17.3                       16.5                          16.9

* Represents a simple average of the Residential and Industrial tariffs. N/A - Unavailable
Figure 1: Comparison of Residential Tariffs in the Arab Countries to Benchmark Tariff (US cents/kWh)

       EU Benchmark
        Arab Average
                Sudan
          Mauritania
             Djibouti
                 Libya
              Tunisia
              Algeria
            Morocco
            Palestine
            Lebanon
                  Syria
               Jordan
                   Iraq
                 Egypt
              Yemen
                Oman
                   UAE
                Qatar
             Bahrain
              Kuwait
         Saudi Arabia
                          0          5           10            15           20           25           30           35


Figure 2: Comparison of Industrial Tariffs in the Arab Countries to Benchmark Tariff (US cents/kWh)




65
     T he UAE was not included in the World Bank study, so information for UAE was based on information at www.rsb.gov.ae.



                                                            147
   EU Benchmark
         Average
            Sudan
      Mauritania
         Djibouti
             Libya
          Tunisia
          Algeria
        Morocco
        Palestine
        Lebanon
              Syria
           Jordan
               Iraq
             Egypt
          Yemen
            Oman
               UAE
            Qatar
         Bahrain
          Kuwait
     Saudi Arabia
                      0      5           10          15          20          25           30



The situation in the gas sector is much the same with many Arab countries providing significant
subsidies to domestic gas consumers, including power generation. This leads to inefficient
allocation of resources. For example, there may be an over-reliance on gas generation because
gas prices are lower than the economic cost of supply. Further, when gas prices are subsidized,
there may not be enough capital generated from sales to fund expansion of supply to meet the
needs of the domestic market, thus forcing consumers such as the power sector to seek
alternative supplies; i.e., oil or coal.
An example of the level of subsidization of gas prices in Arab countries is provided in figure 3.
The internal bulk prices of gas for countries in the region are compared to the average border
price for gas imports to the EU from Russia. The EU average represents the benchmark price for
the region. As can be seen, the internal gas prices for a sampling of Arab countries fall well
below the benchmark, with the average price for the region only 11% of the benchmarks.
      Figure 3: Comparison of Internal Bulk Price of Gas to Benchmarks (US$/MMBTU)




                                              148
          EU Average

     Regional Average

                Syria

               Jordan

                  Iraq

                Egypt

              Bahrain

                 UAE

                Oman

               Kuwait

                Qatar

         Saudi Arabia

                         0       1          2         3          4          5         6          7          8          9




Iran provides a good example of how subsidized energy prices can negatively impact trade.
Current domestic gas prices for various classes of consumers in Iran are in the range of 1 to 2
cents/cubic meter compared to the range of 4 to 6 cents required for financial cost recovery in the
sector.66 The government estimates that the subsidy to gas consumers was $5.76 billion borne by
the state budget. Such low prices have fostered rapid growth in consumption leading to a tight
supply demand balance, especially during the winter season when the domestic demand peaks. In
January 2008, the weather became very cold and the demand for gas rose sharply and a gas crisis
ensued. This was aggravated by the price dispute with Turkmenistan which suspended exports to
Iran. Iran in turn had to renege on its export contracts to Turkey and divert export gas for
domestic use. Similarly supplies to industries were suspended and gas was diverted for
household use.67




66
   Source: Hossein Razavi, Natural Gas Pricing in countries of the Middle East and North Africa, T he Energy Journal Volume 30,
Issue #3 of 2009, p15
67
   Narsi Ghorban, Iran’s future gas development and exports in view of the January 2008 Crisis, Middle East Economic Survey,
Volume LI No.8 , 25 February, 2008 available at www.mees.com/postedarticles/oped/v51n08-5OD01.htm



                                                             149
                                         Attachment 2.B
                          Private Sector Investment in Arab Countries
                   Item                               Algeria                                   Djibouti                                   Egypt

Electricity System and            Installed capacity of 8,500 MW. Algeria is          Capacity of 115MW small         Installed generation capacity of 23,000 MW.
Existing Available                interconnected with Morocco and Tunisia.            diesel generators.              Interconnections with Jordan and Libya.
Capacity                                                                              Interconnected with
                                                                                      Ethiopia from 2011.
Industry Structure                Sonelgaz, the former state owned electricity        Vertically integrated state-    Egypt’s power industry organized into the
                                  and downstream gas monopoly, was                    owned monopoly,                 Egyptian Electricity Holding Company
                                  reorganized into SPE (generation) and GRTE          Electricité De Djibouti         (EEHC), which includes six generation, nine
                                  (transmission). The 4 regional distribution                                         distribution, and one transmission-and-dispatch
                                  companies are also subsidiaries of Sonelgaz.                                        company, which also acts as the singly-buyer of
                                  Generation is open to independent producers                                         electricity. The sector continues to operate as
                                  like AEC, a 50/50 joint venture between                                             vertically integrated due to the single-buyer
                                  Sonelgaz and Sonatrach                                                              trading arrangements and firm financial and
                                                                                                                      corporate control of EEHC over its subsidiaries.
                     Generation   The 4 existing IPPs account for 2.9 GW. They        Auto-production for the         There are three private IPPs with total
                                  are mostly owned by public sector Algerian          Djibouti Port facility          generation capacity of about 2,049 MW, which
  private sector
  participation




                                  companies, but also have some international                                         started operating in 2002/2003, under long-term
                                  private ownership.                                                                  power purchase agreements with EEHC.
             Transmissi           Nil                                                 Nil                             Nil
             on
             Distributio          Nil                                                 Nil                             nil (except for several very small decentralized
             n                                                                                                        providers)
Private Sector Policy             Priorities include construction of new capacity      Main focus is to increase      Main focus is to ensure secure supply by
                                  (8 GW over 2009-2015), modernization of             access to electricity, reduce   increasing electricity generation capacity. All
                                  existing capacity (replacement of steam plants      cost of service delivery and    new investments are financed by EEHC, but the
                                  with gas turbines), development of                  improve the financial           government wants to attract private investment
                                  interconnection with neighboring countries.         stability of the utility.       as well. The challenge is to do it in a way which
                                  Algeria also aims to generate 15% of its                                            minimizes government exposure and guarantees
                                  electricity from renewables by 2025-2030                                            and also de-monopolizes electricity supply.
                                  (60% solar, 40% wind)
Pricing and Regulation            Power prices are very low in Algeria,               Djibouti stands out as          The Egyptian Electric Utility and Consumer
                                  especially for residential customers, thanks to     having by far the highest       Protection Regulatory Agency (EEUCPRA)
                                  low internal gas prices. Average price was 6.2      electricity rates in MENA,      licenses companies that operate in the sector,
                                  USc/kWh in 2008 for residential customers,          around $0.32 per kWh for        and creates conditions for competitive trading
                                  and 3.6 USc/kWh for industrial customers.           residential use and             arrangements. It has no tariff-setting powers.
                                  CREG regulates the electricity and gas              $0.2/kWh for industrial         The new Electricity Law should strengthen the
                                  markets                                             use, reflecting the high        authority of EEUCPRA. Significant under-
                                                                                      running cost of small diesel    pricing of electricity. Electricity prices
                                                                                      generators.                     increased in 2004 (first time since 1992). There
                                                                                                                      is program for increasing energy prices. Natural
                                                                                                                      gas price for energy intensive industries was set
                                                                                                                      to US$3 per mmbtu in June 2008, with
                                                                                                                      subsequent increase in electricity prices for
                                                                                                                      industrial consumers as follows (in USc/kWh):
                                                                                                                      6.3 for medium voltage; 4.6 for high voltage,
                                                                                                                      and 3.8 for ultra high voltage consumers. For
                                                                                                                      comparison, the average sale tariff in FY2008
                                                                                                                      was about 3.1 USc/kWh, in which fuel cost was
                                                                                                                      0.7 USc/kWh. EEHC purchased electricity from
                                                                                                                      IPPs and NhREA at the average price of about
                                                                                                                      2.5 USc/kWh, only about 5% above the average
                                                                                                                      cost of thermal generation from EEHC plants.
Perspective for                   Out of the 8 GW that are expected to be built       Potential for small IPP         There is significant potential for private
Private Sector                    by 2015, 2.2 GW would come from SPE, and            exploiting geothermal           investments, especially in electricity generation.
Participation                     5.8 GW from other producers. Identified             resources. Being explored
                                  projects include international private partners     by IFC and the Bank
                                  such as Alstom, Ansaldo, GE, Orascom, and           (Argeo project).
                                  Iberdrola




                                                                                    150
                                 Item                          Iraq                                  Jordan                                     Libya

Electricity System and                          Total capacity of 6,100 MW.           2,500 MW of installed electricity         6,200 MW of installed generating
Existing Available                              Large capacity needs.                 generation capacity. System               capacity. Interconnected with Egypt
Capacity                                                                              interconnected with Egypt and Syria.      and Tunisia.
Industry Structure                              MoE is responsible for the            Unbundled into 4 generating               The General Peoples Committee for
                                                policymaking and the electricity      companies, 1 single-buyer                 Electricity, Water and Gas is
                                                supply. The operational               transmission company, and 3               responsible for policy, planning and
                                                functions were reorganized into       distribution companies                    regulation of Libya’s electricity
                                                18 geographically based                                                         sector. The General Electricity
                                                directorates within MoE.                                                        Company of Libya (GECOL) is a
                                                Regional directorates in KRG                                                    vertically-integrated monopoly with
                                                report to the Ministry of                                                       control and ownership over all
                                                Electricity in KRG and appear to                                                electricity generation, transmission
                                                have minimum coordination with                                                  and distribution.
                                                the MoE in Baghdad
                                 Generation     Two power plants have been            3 of 4 generating companies are either    Nil
                                                developed in KRG through              wholly-owned or majority-owned by
  private sector participation




                                                private investment. (500 MW           the private sector. Only one company
                                                Erbil Power Plant, 750 MW             remains wholly-government owned
                                                Chamchamal Power Plant). KRG
                                                is providing fuel and receiving
                                                their electricity.
                                 Transmission   Nil                                   Nil                                       Nil
                                 Distribution   Nil                                   All 3 distribution companies are either   Nil
                                                                                      wholly-owned or majority-owned by
                                                                                      the private sector

Private Sector Policy                           Government policy focused on          Main focus is to ensure adequate          Main focus is to ensure the secure
                                                rehabilitation of existing assets     electricity supply. New electricity       and adequate supply of power to all
                                                and development of new                generation capacity being added via       areas of the country. Libya has a goal
                                                generation projects to improve        public-private partnership (PPP).         to improve service quality and
                                                electricity supply in Iraq                                                      efficiency, reduce technical and non-
                                                                                                                                technical     losses   and    reinforce
                                                                                                                                interconnections with neighboring
                                                                                                                                countries.

Pricing and Regulation                          Electricity tariffs in Iraq remain    Electricity pricing is cost-reflective,   Libya’s retail tariffs are far below
                                                far below cost recovery levels.       including some cross-subsidization.       cost recovery levels. Government
                                                Collection rates are low,             Regulation supports full cost-recovery    regulates industry and supports
                                                estimated at 40%. Improvement         for the state-owned transmission          subsidies. Residential customers pay
                                                of electricity supply would           company, competitive procurement of       only 2.0 US cents/kWh, about 10%
                                                advance electricity tariff reforms    private electricity generation, and       of a benchmark tariff that reflects the
                                                to ensure electricity tariffs reach   efficient loss-reducing service           opportunity cost of power This poses
                                                full cost recovery within a           delivery in distribution.                 a significant challenge to Libya’s
                                                reasonable timeframe.                                                           aggressive expansion plans.
Perspective for                                 The Iraqi government is very          Jordan is committed to private            Government does not appear
Private Sector                                  much interested in attracting         electricity generation. The second IPP    interested in attracting private sector
Participation                                   private sector investments in         is under construction. Procurement of     capital. However, GECOL is finding
                                                power generation. The Bank is         a private wind power project              it difficult to bring on enough new
                                                developing a technical assistance     development is underway. Oil shale-       generation and transmission to meet
                                                for preparation of project            based , nuclear and concentrated solar    growing demand, so policy toward
                                                documents and tender packages         thermal electricity generation are        private sector may change in the
                                                for potential power projects.         planned under PPP.                        future.




                                                                                            151
(continued)
                                  Item                           Kuwait                                   Lebanon                              Morocco

Electricity System and                           Total installed generation capacity of         2,300 MW installed               Installed capacity of 5,300 MW
Existing Available Capacity                      about 11,600MW.                                capacity. Large capacity         (hydro, coal, gas mostly). Imports
                                                                                                needs.                           from Spain growing.
Industry Structure                               Kuwait’s electric power system is              The sector is operated by        State-owned Office National de
                                                 vertically integrated with the utility         EdL, a vertically integrated,    l'Electricite (ONE) holds
                                                 owned and operated by the Ministry of          non-commercial, public           transmission monopoly. Since 1994,
                                                 Electricity and Water.                         establishment.                   ONE has been allowed to sign
                                                                                                                                 contracts with private generators.
                                                                                                                                 Distribution is shared between ONE,
                                                                                                                                 municipalities and private operators
                                                                                                                                 (in large cities)
                                  Generation     Nil                                            Nil                              Three IPPs account for 1,800MW.
   private sector participation




                                  Transmission   Nil                                            Nil                              Nil
                                  Distribution   Nil                                            nil, except for four             Municipal operators have been
                                                                                                concessions for the              active since 1961 and private
                                                                                                distribution of electricity in   operators since 1997. ONE is in
                                                                                                4 city areas of Zahle, Jbeil,    charge of rural areas, of a few urban
                                                                                                Aley and Bhamdoun.               centers, and of direct delivery to
                                                                                                                                 some large customers
Private Sector Policy                            It seems that there is a government            The development policy           Short-medium term focus is on
                                                 intention to diversify power generation        includes unbundling of the       building capacity. Coal is key to the
                                                 through utilizing alternative energy           sector and the incorporation     country owing to low cost and
                                                 resources (e.g. solar) and natural gas;        under commercial law of the      availability (Morocco doesn't
                                                 and implementing electricity DSM               new entities. Lack of            produce significant amounts of any
                                                 policies.                                      political agreement on a         fuel). Wind policy also very active.
                                                                                                final objective for sector
                                                                                                restructuring has impeded
                                                                                                progress.
Pricing and Regulation                           Electricity prices are highly subsidized       Electricity tariffs are well-    ONE's financial situation is squeezed
                                                                                                below cost and have not          between high cost of power (cost of
                                                                                                been changed since 1996          fuels, cost of PPAs) and relatively
                                                                                                (oil price was                   low tariffs
                                                                                                US$21/barrel). The sector is
                                                                                                regulated by the Ministry of
                                                                                                Electricity and Water and
                                                                                                Council of Ministers.
Perspective for                                  Kuwait has not yet introduced the              IFC provided advisory            Private sector generation projects
Private Sector Participation                     IPP/IWPP model but is seeking foreign          assistance on due diligence      include: (i) extension of Jorf Lasfar
                                                 investment for the construction of new         for the development of           coal-fired plant; (ii) Safi 1,320 MW
                                                 plants.                                        generation through IPP           coal-fired plant; (iii) Tarfaya 300
                                                                                                arrangements. Lack of            MW wind farm; (iv) Energipro
                                                                                                political agreement on           program, to favor renewable (mostly
                                                                                                private participation as well    wind) self generation by industrial
                                                                                                as uncertainty on fuel supply    users - 1 GW expected by 2012
                                                                                                options inhibited progress.




                                                                                          152
(continued)
         Item                                                Oman                                  Tunisia                                Saudi Arabia

Electricity System and                          Capacity of above 3,300 MW.       Total installed capacity has reached        Installed capacity of 37,200 MW.
Existing Available                              Plans for interconnections with   3,300MW.                                    SEC (state-owned utility) share in the
Capacity                                        other Gulf countries.                                                         installed capacity is 89%.
Industry Structure                              Unbundled generation and          The vertically integrated utility Société   The Ministry of Water and Electricity
                                                distribution, with a state-       Tunisienne de l’Electricité et du Gaz       is responsible for planning and policy
                                                owned single buyer of bulk        (STEG) generates approximately 75% of       making. SEC is vertically integrated.
                                                electricity and a state-owned     Tunisia's power, and has a monopoly         The Saudi Electricity Regulatory
                                                transmission company.             over transmission and distribution of       Authority was formed in 2001and in
                                                                                  electricity (and gas)                       2004 became the Electricity and Co-
                                                                                                                              Generation Regulatory Authority
                                                                                                                              (ECRA). ECRA is a financially and
                                                                                                                              administratively independent, and
                                                                                                                              regulates tariffs (except residential)
                                                                                                                              and market access.
                                 Generation     Privatization is high on the      Private operators are entitled to produce   Private sector participation was
                                                Omani agenda and all new          electricity under public concessions.       limited until Jubail IWPP and the
  private sector participation




                                                generation plants are IPPs.       There are two independent power             establishment of WEC in 2003. The
                                                                                  producers in operation: 471 MW              first IWPP project became
                                                                                  combined cycle gas turbine (CCGT) and       operational in 2009. Large IPPs will
                                                                                  30 MW gas fired plants                      play a major role in the sector.
                                                                                                                              ARAMCO project is under-
                                                                                                                              construction and will be operational
                                                                                                                              in 2013
                                 Transmission   Nil                               Nil                                         Nil
                                 Distribution   Nil                               Nil                                         Nil


Private Sector Policy                           Main focus is to meet growing     To increase generation capacity and         Saudi Arabia has plans to restructure
                                                demand, reduce reliance on        promote IPPs.                               the electricity sector, including
                                                gas by introducing other                                                      unbundling of SEC and the
                                                generation sources in the                                                     introduction of competition. The
                                                electricity mix and gradually                                                 issue of financing critical power
                                                implement cost-reflective                                                     generation projects is currently
                                                tariffs                                                                       putting the system’s reliability at high
                                                                                                                              risk as the reserve margin is rapidly
                                                                                                                              shrinking.
Pricing and Regulation                          Oman's electricity tariffs are    Tariffs are low. Frequently increased to    The current tariff level does not cover
                                                amongst the lowest in the         achieve STEG’s financial balance, and       the cost of supply. ECRA has been
                                                region. Residential tariffs       averages for domestic consumers             developing a tariff adjustment
                                                average $0.026/kWh and            $12.3c/kWh, and for industrial              program as part of its regulatory
                                                industrial tariffs average        consumers $6.7c/kWh (2008).                 mandate to assure cost-recovery.
                                                $0.047/kWh                                                                    ECRA does not have approval
                                                                                                                              authority for residential tariffs.
Perspective for                                 Significant with five new IPPs    New IPP planned in Bizerte (400MW           SEC has introduced IPP Program and
Private Sector                                  planned by 2015                   CCGT, 2014-2015) and new                    defined new potential IPPs to meet
Participation                                                                     interconnector project planned with Italy   critical generation requirements in
                                                                                  to come on line around 2016 with            2009-2020. Recent private sector
                                                                                  potential private sector involvement        activity was the selection of the
                                                                                                                              developer for the first project of SEC
                                                                                                                              IPP program.




                                                                                         153
(continued)
         Item                                                    Syria                                   Yemen                                    Palestine

Electricity System and                          7,700MW installed capacity.                Installed capacity of 1,200 MW,        The Palestinian Territories (West Bank
Existing Available                                                                         mostly heavy fuel oil and diesel       and Gaza) are dependent on the Israel
Capacity                                                                                                                          Electric Co. (IEC) for nearly 95% of
                                                                                                                                  their electric needs. The Gaza Power
                                                                                                                                  Plant (privately owned and operated) has
                                                                                                                                  a capacity of 140 MW but only operates
                                                                                                                                  at about 40-60MW. Gaza also supplied
                                                                                                                                  by about 17 MW from Egypt, while the
                                                                                                                                  West Bank is supplied by about 20MW
                                                                                                                                  from Jordan.
Industry Structure                              State-owned PEEGT is responsible for       Vertically integrated state-owned      For many years electricity services were
                                                the generating plants and transmission     monopoly, Public Electricity           provided in most parts of WBG by
                                                networks. PEDEEE has similar               Corporation (PEC)                      municipal and village councils and by
                                                responsibilities for the distribution                                             the Jerusalem District Electric Company
                                                network.                                                                          (JDECO). Recently distribution
                                                                                                                                  companies have been established, but not
                                                                                                                                  all are yet fully operational. The new
                                                                                                                                  Electricity Law requires the transfer of
                                                                                                                                  municipal electricity operations to the
                                                                                                                                  distribution companies
                                 Generation     Nil, however, MoE has launched a           nil, apart from providing rental       Gaza Power Plant is privately owned and
  private sector participation




                                                process for the development of a 230-      capacity to PEC, and for auto          operated
                                                250 MW power plant by private              generation
                                                developers. The Government requested
                                                IFC to assist for private sector
                                                participation in this Project.
                                 Transmission   nil                                        nil                                    Nill
                                 Distribution   Nil                                        Nil                                    JDECO is publicly owned with, in
                                                                                                                                  addition to municipal shareholders, some
                                                                                                                                  private shareholders
Private Sector Policy                           Main focus is on developing new            A new electricity law was approved     A new Electricity Law was enacted in
                                                generation capacity and substituting oil   by the GOY in Feb. 2009 which          May 2009. The law envisages private
                                                fueled power plants with natural gas.      calls for unbundling PEC into          investment in generation and
                                                The Government recognizes the              separate generation, transmission      distribution.
                                                inadequacy of domestic gas supply and      and distribution entities, and the
                                                is keen to secure gas from regional        creation of regulatory agency
                                                market. The Government has issued
                                                decrees to facilitate engagement with
                                                private sector.
Pricing and Regulation                          The average tariff level in Syria is low   Electricity prices are far below the   Electricity supplied by IEC is priced at
                                                and is not enough to cover the cost        cost of production and heavily         IEC medium voltage tariff levels. Retail
                                                operating costs let alone its investment   subsidized for most consumers. A       tariffs are set by municipal councils or
                                                needs. It is particularly low for          regulatory agency is expected to be    distribution councils, in areas where they
                                                residential consumers at an average of     set up according to the new            exist and operate. The new Electricity
                                                US Cents 1.1/kWh.                          electricity law.                       Law requires the establishment of a
                                                                                                                                  regulator with tariff setting
                                                                                                                                  responsibilities.
Perspective for                                 The Government of Syria is very keen       Potential for IPP exploiting           Potential for IPP in northern West Bank
Private Sector                                  to attract private investments in          renewable energy like wind, solar      is being considered. Private sector
Participation                                   generation. The Bank and IFC are           and geothermal resources. IFC is       participation in development and/or
                                                helping the Government develop a PPP       assisting with IPP for new oil-fired   operation of a concentrated solar power
                                                framework and advising the                 plants. Under the current country      plant in Jericho is likely.
                                                Government on its first IPP project.       and sector risks conditions for
                                                                                           private investment presents
                                                                                           challenges for the government.




                                                                                           154
(Continued)
         Item                                               Bahrain                                  Q atar                                     UAE

Electricity System and                          Small power sector with only         7,660 MW of installed generation           25,250 MW of installed generating
Existing Available                              2,500 MW of generating               capacity in 2010, increasing to 8750       capacity spread among 7 Emirates.
Capacity                                        capacity. Part of GCC                MW in 2011. Part of GCC                    Part of GCC Interconnection.
                                                Interconnection.                     Interconnection.
Industry Structure                              The Electricity and Water            The state-owned Qatar General              Structure varies for each Emirate.
                                                Authority acts as the single buyer   Electricity & Water Corporation            Abu Dhabi has one of the more
                                                of power from the BOO plants. It     (Kahramaa) purchases electricity from      advanced power reform programs
                                                also acts as the regulatory          private producers and acts as the sole     with an independent regulatory
                                                authority for the power sector.      transmitter    and     distributor   of    agency (the Abu Dhabi Regulation &
                                                The Ministry of Electricity and      electricity in the country. Kahramaa       Supervision Bureau). ADWEA, a
                                                Water is responsible for             buys power from IWPPs under 25-            public agency owned by the Abu
                                                electricity production and           year agreements and Qatar Petroleum        Dhabi government, is a holding
                                                distribution. Private sector         supplies     gas    under long-term        company       for   the   unbundled
                                                responsible for generation.          contracts.                                 electricity entities, owning the
                                                                                                                                electricity and water transmission
                                                                                                                                company        (TRANSCO),       two
                                                                                                                                electricity and water distribution
                                                                                                                                companies, two of the emirate’s
                                                                                                                                generation companies and the single
                                                                                                                                buyer, the Abu Dhabi Water and
                                                                                                                                Electricity Company (ADWEC). In
                                                                                                                                addition,      ADWEA       develops,
                                                                                                                                implements, and manages water and
                                                                                                                                electricity policy conducted by its
                                                                                                                                subsidiaries.
                                 Generation     The 950 MW CCGT plant is             Kahramaa accounts for about 68% of         Five IWPPs have been commissioned
                                                owned by the Bahraini Al Ezzel       all electricity generation – the private   on a BOO basis as joint ventures
  private sector participation




                                                Power Company on a build-own-        sector accounts for the rest. Captive      between ADWEA and various
                                                operate (BOO) basis. In January      generation owned by industry               international companies. ADWEA
                                                2007, International Power, Suez      accounts for close to 2000 MW. All         has a 60% share-holding while the
                                                Energy of Belgium and                new generation constructed by private      remaining 40% is owned by private
                                                Sumitomo of Japan acquired the       sector and IWPPs.                          investors. All IWPPs sell water and
                                                Al Hidd power and water plant                                                   electricity to the single buyer
                                                from the government.                                                            (ADWEC) under long-term contracts.
                                 Transmission   Nil                                  Nil                                        Nil
                                 Distribution   Nil                                  Nil                                        Nil



Private Sector Policy                           Government focus is on private       All new generation constructed by          Policy varies for each Emirate. Abu
                                                sector development of new            private sector. Kahramaa is working        Dhabi expects the private sector to
                                                generation. Recently, the            on several large-scale power projects      build new generation as IPPs/IWPPs.
                                                government announced an              with foreign companies, and is             Dubai has also introduced the IWPP
                                                international bid for a 1,200 MW     required to privatize its transmission     model for new generation and plans
                                                Al Dur power and desalination        and distribution systems.                  to reform its power sector similar to
                                                plant expected to be                                                            that of Abu Dhabi and privatize
                                                commissioned in 2011.                                                           assets as was done with ADWEA.
Pricing and Regulation                          Government sets tariffs and they     Tariffs are heavily subsidized and         Retail electricity tariffs continue to
                                                are heavily subsidized.              well below the economic cost of            be subsidized. Residential customers
                                                Residential customers pay only       supply. Residential customers pay          pay 5.0 US cents/kWh, only 28% of a
                                                0.8 US cents/kWh, about 4.5% of      only 2.2 US cents/kWh (for                 benchmark tariff that reflects the
                                                a benchmark tariff that reflects     consumption up to 4000 kWh/month,          opportunity cost of power.
                                                the opportunity cost of power.       and 2.7 US cents/kWh for
                                                                                     consumption above this level), about
                                                                                     12% of a benchmark tariff that
                                                                                     reflects the opportunity cost of power.
Perspective for                                 The Bahraini government is very      Good, but highly subsidized                Good in the generation sector, at least
Private Sector                                  much interested in attracting        electricity tariffs pose a significant     in the Emirates of Abu Dhabi and
Participation                                   private sector investments in        barrier.                                   Dubai.
                                                power generation.




                                                                                           155
(Continued)
                                    Item                               Sudan                                                 Mauritania

Electricity System and                             Sudan has over 2585 MW of generating                Power system is small and fragmented with only 90
Existing Available Capacity                        capacity. Not currently interconnected with any     MW of installed generation capacity. Not currently
                                                   Arab countries.                                     interconnected with any Arab countries.
Industry Structure                                 The Ministry of Electricity and Dams is             The Ministry of Hydraulics and Energy is responsible
                                                   responsible for policy formulation and              for the energy sector in Mauritania. State-owned
                                                   oversight of the electricity sector including the   Société Mauritanienne d’électricité (SOMELEC) is the
                                                   Dams Implementation unit and the Kenana and         national power utility and the major player in the
                                                   Rahad Canals            in Sudan. The National      power sector with responsibility for owning and
                                                   Electricity Corporation (NEC) was unbundled         operating power facilities. Agence de développement
                                                   and replaced with five companies, including:        de l’électrification rurale (ADER) is the agency with
                                                   Sudanese Thermal Power Generation Co., Ltd.,        responsibility for rural electrification. Autorité de
                                                   Sudanese Hydro Generation Co., Ltd, Merowe          regulation (ARE) is the body which regulates the
                                                   Dam Electricity Co., Ltd., Sudanese Power           power, water and telecom sectors. Participation in the
                                                   Transmission Co., Ltd., and Sudanese                regional power projects is handled by the government
                                                   Electricity Distribution Co., Ltd.         These    and SOMELEC with the latter having responsibility
                                                   companies were established under the Law of         for power purchase and payment.
                                                   Sudan (Companies Act 1925). The Sudanese
                                                   Power Transmission Company is responsible
                                                   for purchasing power from producers and
                                                   development and expansion of the national grid.
                                    Generation     Nil                                                 Nil
     private sector participation




                                    Transmission   Nil                                                 Nil


                                    Distribution   Nil                                                 Nil




Private Sector Policy                              Sudanese law allows private investment in the       Appears to be little in the way of policy relating to the
                                                   power sector (most likely generation, and           private sector. Instead, the Government has
                                                   perhaps distribution). Seeking to expand energy     concentrated on regional projects. Mauritania is
                                                   trade with Ethiopia, Eretrea and Egypt.             allocated 28 MW of capacity from the Manantali
                                                                                                       Hydropower project and Aggriko Diesel plants in
                                                                                                       Mali, owned jointly by Mali, Senegal and Mauritania
                                                                                                       and operated by SOGEM and OMVS. Further regional
                                                                                                       projects are under study.
Pricing and Regulation                             Government sets tariffs and they are subsidized,    Tariffs have been revised upwards several times in the
                                                   although not as much as other Arab countries.       last decade to about 24 US cents/kWh, but remain
                                                   Average tariff is 8.7 US cents/kWh.                 below the cost of supply placing SOMELEC in a
                                                                                                       precarious financial position.
Perspective for                                    Sudanese law allows private sector investment       Perhaps, but currently Government is concentrating on
Private Sector Participation                       in the electricity sector.                          regional projects which may include a role for the
                                                                                                       private sector.




                                                                                  156
Attachment 2.C: Electricity Sector in Europe
1.          Overview
The combined GDP of the EU member countries in 2009 was about Euro 11.8 trillion while the
per capita GDP (on the basis of purchase power parity) was about Euro 23,600.
The import dependency of the EU energy economy is rapidly rising. The import dependency
with respect to overall energy is expected to rise from the current level of 50% to 64% by 2020
and 67% by 2030. Between now and 2030 the import dependency for gas is expected to increase
from 59% to 84%, the oil import dependency will rise to 95%, while the import dependency with
respect to solid fuels is expected to rise from 40% to 63%. The import dependency for uranium
for nuclear power plants is nearly 98% (IEA Energy Policy Review EU 2008). There is little
import dependency with respect to electricity except through import dependency relating to the
fuels for power generation.
In this context the key objectives of the EU electricity policy initiatives relate to efficiency
improvements in electricity production, transmission, distribution and use, emissions reduction,
environmental mitigation, and ushering in a fully competitive internal electricity market. The
overarching concern is to ensure energy security through diversification of the forms of energy
imports and diversification of supply sources.
For the purposes of this report the European Union (EU) is dealt with as it exists today consisting
of 27 member countries (Austria, Belgium, Bulgaria, Cyprus, the Czech Republic, Denmark,
Estonia, Finland, France, Germany, Greece, Hungary, Ireland, Italy, Latvia, Lithuania,
Luxembourg, Malta, the Netherlands, Poland, Portugal, Romania, the Slovak Republic, Slovenia,
Spain, Sweden and the United Kingdom) with a total population of about 500 million people and
a surface area exceeding 4 million sq.km – about half the size of the USA. 68 Often data provided
will relate to the group of 23 European members referred to as the Organization of Economic
Cooperation and Development (OECD-Europe) consisting of: Austria, Belgium, the Czech
Republic, Denmark, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy,
Luxembourg, the Netherlands, Norway, Poland, Portugal, the Slovak Republic, Spain, Sweden,
Switzerland, Turkey and the United Kingdom, as some data are not readily or consistently
available for the EU.
2.          Power Sector Structure
The European electricity industry is one of the largest industries in the EU employing more than
700,000 people directly. A transformation of the industry has taken place during the past decade
owing to technological change and the introduction of the Commission’s Electricity Market
Directives (since 1996). Monopoly network components have been unbundled and considerable
merger and acquisition activity has taken place, some involving cross-border mergers and
acquisitions leading to “European utilities”.
The electricity industry in the EU is still highly concentrated, at both the EU and member state
level. The seven largest utilities in the EU had sales representing 72% of total demand in 2006.
The same companies produced 49% of total generation and owned 49% of total installed


68
     Much of the statistical data used do not cover Cyprus and Malta.



                                                               157
capacity. According to the Commission, generation markets in Belgium, France, Estonia,
Ireland, Greece, Portugal, Latvia, Slovenia and Slovakia were highly concentrated in 2005.
The retail market for sales to final customers is slightly more concentrated than the generation
market. This picture is reinforced when looking at the market position of the largest European
utilities (Exhibit 1). Several of these utilities also have other activities, most notably gas, making
them significantly more important in terms of their role in the EU energy sector.
                   Exhibit 1: Market Share of the Seven Largest Utilities in the EU




A total of 104 generation companies in the EU had a national market share of installed capacity
exceeding 5% in 2005 according to the Commission. In terms of generation output, 90
generation companies had national market shares above 5% in 2003 according to Eurelectric (an
industry association). In seven countries, the 3 largest generators had national market shares
above 90% in 2005.
According to Eurelectric, there were almost 3 000 distribution companies in the European Union
in 2003. Consolidation has continued since then, but there are still a high number of relatively
small distribution companies in some member states. In 2003 there were five or more
distribution companies in 15 EU countries. According to the Commission, there were 85
companies in the EU with a 5% market share or higher in each country in 2005. In seven
countries there is only one company with a market share higher than 5%. In 12 of the 25 EU
countries, the three largest companies had a retail market share of 90% or higher in 2005.
The distribution and retail supply component of the industry has a very high number of
companies, but relatively few companies have large market shares in half of the EU countries.
The second Electricity Market Directive includes requirements for all distribution companies
with more than 100,000 customers to unbundle network activities at the distribution level from
sales and generation. The unbundling can be either legal or functional separation. However,
according to the Commission, only six countries had complied fully and unambiguously with the
distribution network unbundling requirements by the end of 2005.


                                                 158
The second Electricity Market Directive requires legal separation of transmission system
operators (TSOs) to ensure that they operate independently from generation and supply interests,
and to enable fair and open access to the transmission grid. More than half of the EU member
states have chosen to fully unbundle TSOs through ownership separation. According to the
Commission, only 16 countries (including Norway69) had unambiguously and effectively
implemented unbundling requirements for transmission system operation in 2005.
European TSOs have a long tradition of co-operation at the regional level and beyond. They have
formed the association of European Transmission System Operators (ETSO) to facilitate co-
operation on European Union issues, including cross-border trade. Within UCTE, a system of
operational agreements has developed. Since the large blackout in Italy in 2003, the agreements
have been more detailed, formalized and contractually binding. In the Nordic region, the TSOs
have formed NORDEL, which is the platform for co-operation on operation, market design
issues and network planning. ETSO has since been replaced by ENTSO-E as described below.
3. Electricity Sector Reform and Market Organization
Several reform measures have been undertaken in the EU through various directives with the
objective of promoting competition in the internal electricity market. Their focus had been on
unbundling the monopoly elements, mainly the network operation from the other functions,
ensuring third party transmission access, independent regulatory oversight including cross border
exchanges and trade, as well as the provision that all customers have to choose their supplier.
The first package of directives included Electricity Directive 96/92/EC issued in 1996. This
enabled the largest consumers to choose their suppliers and also provided for open access, but
without a regulated access framework. It required the unbundling of the transmission system
operation function from the vertically integrated utilities through separation of accounts. It also
introduced the concept of a single buyer, acting in the internal energy market, but appointed to be
the sole supplier in a specific domain.
In order to accelerate reform and improve the provisions relating to access and regulation, a
second package of directives were issued in 2003. This included the Electricity Directive
2003/54/EC and the Regulation Directive 2003/1228/EC. The former required a step-wise
opening of the retail market with the target of full opening by July 2007, and made unbundling
provisions stricter by requiring legal separation (establishing a separate company) or full
ownership unbundling. Establishment of independent regulators was made mandatory.
The Regulation Directive dealt with cross border electricity trade, made provisions for market-
based allocation of transmission capacity and for the collection of congestion rents from
transmission capacity auctions and their use for investments to eliminate bottlenecks in the grid.
It also included provisions for calculating in a transparent and non-discriminatory manner the
available transmission capacity based on real physical bottlenecks.
Various reviews found that electricity markets largely remained national in scope and had high
levels of market concentration. The level of effective unbundling was inadequate and lack of
adequate cross border transfer capacity constrained trade and competition across the borders.
There was a lack of transparent and reliable market data and timely price information to foster
competition. The balancing markets tended to favor the incumbents. This led to issue of the third
69
     T hough Norway is not a member of the EU, it conforms to the key principles of the EU Directives voluntarily.



                                                              159
package of directives in June 2009 which resulted in full retail market liberalization ahead of the
target date of July 2007.
The wholesale electricity market evolved gradually, encouraged by progress in sector unbundling
and increasing transmission access. The association of European power exchanges, EuroPEX,
has members from power exchanges in 14 EU member states. Some of the oldest exchanges are
NordPool in the Nordic region, OMEL in Spain, APX in Great Britain and the Netherlands and
EEX in Germany. A review of the wholesale market prices in select exchanges (in terms of day
ahead spot prices) during Jan 2005-Jan 2008 shows some convergence of prices, but still there is
a great deal of scope for improvement (Exhibit 2). Traded volumes of electricity in the UK,
Germany and the Netherlands and in the Nordic market in 2005 were 1 to 6 times the national
electricity consumption. Market liquidity has since increased substantially.
              Exhibit 2: Monthly Average Day-Ahead Spot Prices in Select EU Markets




                             Source: IEA Energy Policy Review EU (2008)
The latest available daily arithmetic average spot prices in Euros/MWh (vertical axis) in the
various European power exchanges for the period December 26, 2009 to January 25, 2010 is
provided in Exhibit 3. The degree of convergence in prices among various exchanges seems to
have improved.
Exhibit 3: Daily Arithmetic Average Spot Prices for Electricity in European Power Exchanges 12/26/09
                                             to 1/25/10




                                                160
                                Source: http://www.europex.org/default.asp?kaj=markets
Though full retail market opening was achieved well before the target date of July 2007,
switching of suppliers for smaller consumers was about 5% in three countries and much lower in
others. With respect to large consumers there has been extensive switching of suppliers. More
than 50% of the largest consumers switched suppliers in seven countries, while more than 15%
of the largest consumers switched suppliers in another 16 countries.
4.          Demand and Supply
4.1 Demand
Simultaneous peak demand in 2006 in the UCTE area 70, Great Britain and Nordel (excluding
Norway) was 546 GW in January 2006, whereas aggregate individual peak load in the same
countries was 568 GW (Exhibit 4). This is the challenge that individual countries had to meet in
the absence of trade and co-operation. The difference results from diversity in the timing of peak
demand, and corresponds to 22 GW, approximately 4% of the simultaneous peak load, or 3% of
total installed capacity. The potential benefits derived from dynamic trade, co-operation and
appropriate transmission capacity are therefore obvious, both in terms of improved security of
supply and improved efficiency.
Exhibit 4: Hourly Peak Load in UCTE, Great Britain and Nordel (excluding Norway), Aggregate of
Individual Countries and Simultaneous across All Countries, 2006


70
     T he UCT E area includes most of the EU.



                                                         161
                              Source: IEA Energy Policy Review EU 2008
Exhibit 4 shows the annual load curve of the overall system in terms of monthly peak loads. As
can be seen the overall annual system peek occurs in January, and monthly peak demands are
lowest in summer.
During the past 15 years electricity consumption in the EU has increased at a rate of 1.7% per
year on average. From 1990 to 1995, the annual average growth rate was only 1%, owing to the
economic recession in Eastern Europe following the fall of the iron curtain. From 1990 to 1992
total electricity consumption in the EU fell slightly with a steep reduction in electricity
consumption in the former communist countries. Growth increased markedly from 1995 to 2000,
with annual average growth rates of 2.3%, slowing down again from 2000 to 2005 to an average
annual growth rate of 1.8%. Economic growth outpaced growth in electricity consumption from
1995 to 2000 with average annual real growth rates of 2.8%. From 2000 to 2005, economic
growth was at par with growth in electricity consumption.
This general picture obscures some important developments in parts of the EU, in particular the
rapid growth in electricity demand on the Iberian Peninsula, and the shift of consumption growth
from the industrial to the tertiary sector. The EU has several large industrial nations as member
states, and this is reflected in electricity consumption patterns. In 2005, about 41% of electricity
was consumed in industry. This is a high share compared to the IEA countries in general and
remarkably, it is a relatively small decline from the 46% share in 1990 compared to non-EU IEA
member countries. It is expected that this share will remain stable, although this expectation is
subject to developments in electricity supply costs driven by increasing fuel prices, investment in
renewables, and the cost of CO 2 certificates after 2013. Growth of electricity consumption has
been particularly rapid in the consumer groups covering government, households, agriculture,
and the services sector, both in volume and in share. Households alone consumed about 29% of
total electricity in 2005, and the expected growth in the use of appliances makes it likely that
demand in the residential sector will continue to increase strongly throughout the EU. Transport
electricity consumption is relatively small, at only 3%, and is expected to remain stable (Exhibit
5).
           Exhibit 5: Electricity Consumption Mix in the Past and Forecast through 2030



                                                162
                                     Source: IEA Energy Policy Review EU 2008
Based on the reference scenario forecast made by the IEA in its World Energy Outlook (2009),
electricity demand in the EU is expected to grow at a compounded annual average rate (CAGR)
of only 0.9% during the period 2007-2030 from 2840 TWh in 2007 to 3485 TWh in 2030. This
compares with a forecast of 1% annual rate for OECD (Europe) and 2.5% for the world (Exhibit
6).
                         Exhibit 6: Electricity Demand Projection for the EU (TWh)
                Item         1980      2000      2007     2015      2030        CAGR 2007-2030
                EU           na        2520      2840     2973      3485        0.9%
                OECD (E)     1709      2696      3062     3202      3855        1.0%
                World        6799      12642     16429    20381     28930       2.5%
                                     Source: World Energy Outlook, IEA (2009)

4.2 Supply
The electricity demand/supply balance in the EU for the period 2002-2007 is summarized in
Exhibit 7. The installed generation capacity has increased from 716 GW in 2002 to 779 GW in
2007 and further to around 811 GW in 2008. About 7% of this capacity was owned by auto-
producers (industries producing power mainly for their own consumption). The remaining 93%
was for public supply.
                      Exhibit 7: Electricity Demand/Supply Balance, 2002-2007 (GW)
   Item /unit                                   2002     2003     2004     2005     2006   2007   2008

   Total Installed Capacity GW                   716      728      737      747      762    779
     Of which Hydro                              142      137      138      139      140    140
     Wind                                        23       29       34       41       48     56     65
     Geothermal                                 0.68     0.72     0.66     0.69     0.70   0.70   0.85
     Nuclear                                     138      137      136      135      134    133
     Conventional Thermal                        412      424      427      432      440    449
   Capacity in Utilities (GW)                    670      682      685      690      717    731
   Capacity of Auto producers (GW)               46       47       51       53       53     54
   Gross Generation (TWh)                       3117     3216     3288     3309     3540   3362   3260
     Of which Hydro                              348      338      357      341      345    344   414
     Wind                                        36       44       59       70       82     104
     Geothermal                                   5        5        6        5        6      6     6
     Nuclear                                     990      996     1008      998      990    935   936
     Conventional Thermal                       1738     1832     1857     1893     1929   1969   1904
   Net Generation (TWh)                         2953     3049     3117     3134     3178   3185   3096
   Imports into EU (TWh)                         285      290      281      324      311    318   297
   Exports from EU (TWh)                         272      292      288      313      307    308   285


                                                       163
    Self consumption by producers (including   289        298       302       305      296       298      45
    pumped storage)
    Network losses (TWh)                        208       215       223       219       202      204
    Final consumption (TWh)                    2600      2668      2722      2763      2826     2843
      Of this Industry                         1092      1102      1126      1135      1133     1150
      Transport                                 72        72        72        74        71       72
      Households                                739       771       784       795       807      801
      Services, others                          697       722       738       758       816      821

   Source: http://epp.eurostat.ec.europa.eu/cache/ITY_OFFPUB/KS-PC-09-001/EN/KS-PC-09-001-EN.PDF
Note : Data for 2008 are provisional from Monthly Statistics of Issue 11/2009 of Eurostat. In 2008 hydropower
generation includes wind power and self consumption relates to pumped storage units. Also note that the above data
exclude solar, biomass and waste-based generation and capacity.
About 57.6% of the capacity was fired by fossil fuels including coal, lignite, gas and oil.
Hydropower capacity had a share of 17.9% followed by nuclear power at 17.0% and wind power
at 7.2%. Geothermal at 700 MW had only a tiny share. Gross generation in 2007 amounted to
3362 TWh and the largest share in generation came from fossil fuel fired plants at 58.7%,
followed by nuclear generation at 28%, hydropower at 10.2% and wind power at 3.1%.
Natural gas has been replacing coal-fired capacity, increasing its share from 7% in 1990 to
21.8% in 2007. This trend is expected to continue, with natural gas station output growing
further to 24% by 2020, and becoming the second most important source of power after coal and
ahead of nuclear towards the end of the next decade. By 2030, gas-fired power output is expected
to reach 995 TWh per year, up from 600 TWh in 2005. Gas has also replaced oil which still
played a prominent role in 1990, contributing 8% of generation, but fell to 3.4% in 2007.
Renewable energy sources contribute the remainder. In 1990 their share was 12%, almost
entirely from hydro. In 2007 the share had increased to nearly 16% with the importance of hydro
reduced to 9.3% and marked increases in wind power and power from biomass, each
contributing about 3.2% in 2007. An indicative target of 20% of electricity generation from
renewables by 2010 has been set by the Commission.
IEA forecasts under its reference scenario in its World Energy Outlook (2009) that the total
annual electricity generation will increase from 3,325 TWh in 2007 to 3,765 TWh in 2030, and
annual increase of 0.77%. The generation levels and generation mix envisaged for 2015, 2020
and 2030 are summarized in Exhibit 8.
            Exhibit 8: Forecast Generation Levels and Generation Mix in the EU through 2030




                                                       164
                                Source: World Energy Outlook, IEA 2009
In 2007 coal and gas capacity shares were at about 25% and 22%, respectively. There were 146
nuclear power plants (NPPs) operating in 15 member states. Nuclear power represented 16% of
installed capacity but generated 28% of the energy. This corresponds to an average capacity
factor of 81%, a notable increase from the average nuclear capacity factor of 72% in 1990,
indicating the progress made in increasing the performance of the plants. Average coal and gas
capacity factors were both at 53.2% in 2007. This reflects that some coal plants are old and see
little utilization, but are still present as a source of flexibility. Gas plants are often used as mid-
merit order plants, with utilization rates varying with the price of gas. Capacity factors from
hydro plants are relatively stable, depending on precipitation levels. Hydro is an essential source
of short-term flexibility but is dependent on precipitation to deliver seasonal flexibility. Wind
power is fully dependent on wind resources. Hence, seasonal flexibility to meet changes in
resource or demand conditions will have to come from coal-, gas- and to a certain extent,
biomass plants. Wind provided 37% of capacity additions and replacements in the EU from 2000
to 2007.
In 2007 alone, 11.5 GW of net new natural gas capacity was added, and from 2000 to 2006, net
capacity additions stood at 92 GW, roughly equivalent to the total generating capacity of the
United Kingdom. From 2000 to 2006, net capacity of nuclear power generation was reduced by
2.6 GW in the EU. There will be no significant new nuclear capacity before 2011 when the new
Finnish reactor is expected to be commissioned. Later in the next decade, a new French reactor
currently under construction will come on line, while there are expectations that some new
reactors may begin generating towards the end of the next decade in Great Britain. Over the next
decade these additions, even when combined with capacity increases at some existing reactors,
will not suffice to reverse the trend of declining nuclear power generation capacity in the EU
because of the parallel decommissioning of significant capacity in a number of member states.
Coal capacity has also declined by more than 11 GW since 2000. Increasingly demanding
environmental performance standards from the Large Combustion Plant Directive, together with
the expected impact from the move towards full auctioning in the next phase of the Emissions
Trading Scheme (ETS), will put pressure on the economics of investment in new coal plant as
long as carbon capture and storage is not a commercial technology.
Based on the reference scenario, IEA has forecasted the EU’s total generation capacity growth
and the changes in the capacity mix through 2030, which is summarized in Exhibit 9.
             Exhibit 9: Growth in EU Generation Capacity and Changes in Capacity Mix




                                                 165
                              Source: World Energy Outlook (2009), IEA
The increasing share of wind power, competition and trade within and across regions, pressure
from the EU emission trading scheme (ETS) since 2005, and most importantly the preference for
highly-efficient gas turbine plants, have resulted in significantly increased efficiency of power
generation in the EU between 1990 and 2005 (from 34% to 38%) despite the accession of some
new member states with relatively inefficient power generation. It is expected that this trend will
continue and that generation efficiency will reach 42% by 2030. Further the system loss volumes
are expected to remain constant at current low levels despite a major increase in production
volume.
Generation capacity additions of 213 GW from 2008-2015, and 460 GW from 2016-2030 will be
needed to replace retiring units and meet incremental growth in demand. Generation investments
of the order of $467 billion during 2008-2015 and $996 billion during 2016-2030 will be needed.
Transmission and distribution investments would amount to about $276 billion and $557 billion
for the two time frames (Exhibit 10)
            Exhibit 10: Power Capacity Additions and Investments in the EU through 2030
Item                       2008-2015                                        2016-2030
            Capacity   Gene- Trans-      Distri-         Capacity   Generation Transmission Distributio
            Addition   ration mission    bution          Addition   $b          $b          n $b
            GW         $b       $b       $b              GW
EU 27       213        467      69       206             460        996        140           417
OECD (E)    220        477      71       214             492        1047       155           470
                              Source: World Energy Outlook (2009), IEA
4.3 Trade
Unlike in the case of gas and oil, most of the electricity needed in the EU is produced within the
EU; import dependency with respect to electricity is small, and mostly confined to the former
Soviet Union states which have since become members of the EU. While electricity trade among
the members of the EU is substantial and growing, import of electricity into the EU from outside
remains modest.
The EU was a net importer of comparatively small volumes of electricity in 2005, primarily from
Norway, Ukraine, and Russia (directly or through Belarus). Some EU members, in particular the

                                                   166
Baltic States, which acceded in 2004, are very heavily dependent on energy imports from outside
the EU. Electricity imports are highly variable, depending to large extent on annual precipitation
levels. The EU is also exporting electricity, for example to Morocco.
As can be seen in Exhibit 11, imports and exports in the EU are around 10% of net generation,
and net imports/exports are insignificant. Most of the exports and imports are among the EU
member countries.
                       Exhibit 11: EU Electricity Imports and Exports (TWh)
Item                                 2002       2003      2004    2005     2006     2007      2008
Net Generation in EU (TWh)             2953        3049     3117   3134      3178     3185      3096
Imports into EU (TWh)                    285         290      281    324       311      318      297
Imports as a % of net generation       9.6%        9.5%     9.0% 10.4%       9.8%      10%     9.6%
Exports from EU (TWh)                    272         292      288    313       307      308      285
Exports as a % of net generation       9.2%        9.6%     9.2%    10%      9.7%     9.7%     9.2%
   Source: http://epp.eurostat.ec.europa.eu/cache/ITY_OFFPUB/KS-PC-09-001/EN/KS-PC-09-001-EN.PDF

With respect to OECD (Europe), imports and exports in 2007 amounted to 338 TWh and 336
TWh, respectively. Of this, trade among member countries of OECD (Europe) covered about
92% of the imports and exports. The remaining 8% of the imports came mostly from Russia and
former Soviet Union states (16 TWh), and the Balkan states in South East Europe (9 TWh).
About 14 TWh of exports went to the Balkans, and about 3 TWh went to the former Soviet
Union states.
4.4 Role of ENTSO-E/UCTE
The European transmission network is highly integrated. Though developed with a national
focus, it has interconnections among nations that allow robust system operation across the main
synchronized blocks and for significant exchange of power across national borders and across
synchronized blocks. Cross border transmission capacity is viewed not only as improving
dispatch efficiency and system security, but also as an essential element to enable competition in
the internal market. The liberalization of the European electricity markets has encouraged more
integrated dispatch based on economic grounds across larger and larger regions. It has also
highlighted important bottlenecks to electricity flows.
The Association of European Transmission System Operators (ETSO) focused on facilitation of
the emergence and operation of the internal competitive European electricity market, and on the
market rules and harmonization needed. Its focus encompassed issues relating to: inter-TSO
compensation, congestion management, real time electronic data exchange, tariffs, system
security and legal and regulatory aspects.
Any discussion of the EU power sector would be incomplete without mentioning the Union for
the Coordination of Transmission of Electricity (UCTE) which coordinated the interconnected
and synchronized operation of 29 Transmission System Operators (TSOs) from 24 countries in
Europe. Unlike the gas sector, the interconnected synchronous operation of the electricity grid
covers most of the EU, and several other countries which are not members of the EU, including:
      The 18 countries which are members of both the EU and the UCTE: Austria, Belgium,
Bulgaria, Czech Republic, Denmark (West), France, Germany, Greece, Hungary, Italy,
Luxemburg, Netherlands, Poland, Portugal, Romania, Slovenia, Slovak Republic and Spain.


                                                167
       The six countries which are part of the UCTE, but not members of the EU are: Bosnia-
Herzegovina, Croatia, Former Yugoslavian Republic of Macedonia, Montenegro, Serbia and
Switzerland.
       The nine countries which are members of the EU but are not operating in synchronism
with UCTE are: Cyprus, Estonia, Finland, Ireland, Latvia, Lithuania, Malta, Sweden and UK,
apart from the rest of Denmark. 71
The former Yugoslavian states in the Balkans disconnected from the main UCTE owing to war
damages sustained in 1991, but were successfully reconnected to UCTE and synchronized in
October 2004. At present, ENTSO-E, the successor of UCTE, is examining the possibility of: (a)
Turkey joining ENTSO-E; and (b) the interconnection between Tunisia-Libya that would bring
the UCTE frequency up to Syria and Lebanon. It is also studying requests from Ukraine and
Moldova to join ENTSO-E, and the possibility of interconnecting two of the largest systems in
the world, namely ENTSO-E and IPS/UPS of Russia.
For over fifty years UCTE coordinated the synchronized operation and development of the
European grid which supplies 500 million people and is one of the largest synchronized grids in
the world. It provided a market platform for all participants in the European internal electricity
market, and was responsible for the efficient and secure operation of the synchronized European
grid issuing all of the technical standards for coordination of the international operation (cross
border energy transfers) of the high voltage grids.
For over 40 years, enforcement of UCTE rules was voluntary, relying on the common interests
of members to maintain secure operation of the synchronized grid. However, the network failure
in 2003 when supply to much of Italy was temporarily lost led to the realization that system
security had become more complex. At that time, UCTE had also grown geographically and
members’ interests had become less homogenous. The UCTE produced the Operational
Handbook which codified all regulations and in 2005, each member country of UCTC was
obliged to sign a Multilateral Agreement as a condition of membership. This agreement obliged
each member to adhere strictly to the Operational Handbook, especially in relation to: frequency
control, scheduling and accounting, operational security, coordinated operational planning,
emergency procedures, communications protocols, data exchanges, and operational training. In
2007 the Compliance Monitoring and Enforcement Processes (CMEP) came into operation. This
enabled UCTE to gather all relevant information on compliance with the Operational Handbook
and impose penalties and/or remedial measures on transgressors. The enforcement is on a civil
contractual basis, and not on a statutory basis.
At the end of 2008 the UCTE area had a total generating capacity of 672 GW (16.7% nuclear,
20.4 % hydro, 51.6% fossil fuel fired, and 11.3% others including wind and other renewables)
and generated 2,543 TWh of electricity (52.6% from fossil fuel plants, 29.3% from nuclear
plants, 11.6% from hydropower plants, and 6.1% from other sources including wind power
units). Germany had 20% of this generating capacity, followed by France at 17.5%, Italy at
14.6% and Spain at 13.2%. Consumption in 2008 amounted to 2,602 TWh. The annual
maximum load of 392 GW occurred on January 16, 2008, and the annual minimum load of 217
GW occurred on August 20, 2008. Total energy exchanges amounted to 334.7 TWh of which
71
   UK and the Scandinavian countries have no AC linkage to the UCT E network owing to technical difficulties relating to
synchronization across the sea. T hey have asynchronous DC links for power transfer. Similar is the case with respect to the Baltic
countries.



                                                               168
285.2 TWh was exchanged among member countries and 49.5 TWh was exchanged with third
country systems.
As of 2008, the UCTE network had 117, 316 km of 220 kV lines, 104,532 km of 400 kV lines
and 170,854 km of composite 400 kV lines. 72 Exhibit 12 graphically presents the available
power transfer capacity across national borders in the UCTE area during the winters of 2003 and
2008.
       Exhibit 12: Available Transfer Capacities (MW) across State Borders in UCTE 2003-2008




                                                  Source; UCTE website

The overall area is divided into five blocks for system adequacy analyses. Exhibit 13 reproduced
from the System Adequacy Forecast Report of UCTE for 2009-2020 shows forecast growth in
the Simultaneous Regional Transmission Capacity for the period 2009 to 2020.
                     Exhibit 13: Simultaneous Regional Transmission Growth 2009-2020




72
  T he composite measure grosses up or down the km of lines at the different voltage levels to a 400kV equivalent. For example a
km of 220kV line is considered to be equivalent to (220÷400) km of 400kV line. T his is not a proper measure of the change in
power that can be transmitted but is still useful for illustration.




                                                             169
Exchange within UCTE member countries grew from 48.4 TWh in 1975 to 285.2 TWh in 2008,
a rate exceeding the rate of demand growth. Exchange with third countries grew during the same
period from 3.2 TWh to 49.6 TWh (Exhibit 14.)
                           Exhibit 8-14: Electricity Exchanges (TWh)
                     Exchange among UCTE Exchange with third Total electricity exchange
            Year     member countries          countries
            1975             48.4                       3.2              51.6
            1990             115.8                     23.9             139.7
            1995             139.4                     34.9             172.3
            2000             177.5                     51.7             229.2
            2005             298.9                     48.8             347.7
            2008             285.2                     49.5             334.7
                            Source: Statistical Report of UCTE for 2008

The export and import levels as a percentage of national demand vary considerably among the
five blocks and among the individual countries (Exhibit 15).




                                             170
                        Exhibit 15: Exports and Imports from UCTE Member States (2008)




                                                  Source: Data from the UCTE website

Among the reforms implemented under the third package of EU directives, one related to the
creation of ENTSO-E to absorb UCTE, ETSO and other similar organizations such as UKTSOA,
NORDEL, BALTSO, and ATSOI. 73 In mid-2009 ENTSO-E came into existence and now all
UCTE functions are carried out in the name of ENTSO-E. In order to achieve fully its objective
of creating a single internal competitive market, EU foresees the need for supra-national
organizations in certain sectors. ENTSO-E in electricity and ENTSO-G in the gas sector are to

73
     T hese are UCT E like organizations for UK, Nordic countries, Baltic countries and Ireland respectively.



                                                                171
evolve as single transnational TSOs to fully oversee market and market platform development.
ENTSO-E has a wider mandate than UCTE, and has a specific legal role and legal powers.
          5. Tariffs
Electricity retail prices including all taxes and duties for households and industries as of July
2009 for some of the key markets in the EU are summarized in Exhibit 16.
Exhibit 16: Electricity Prices for Household and Industrial Consumers in Select EU Retail Markets
                                        (Euro Cents/kWh)
Country               Households with             Households with         Industries with             Industries with consumption
                      consumption of 3500         consumption of 7500     consumption of 2000         of 24 GWh/year. Maximum
                      kWh/year (30% at night)     kWh/year (30% at        MWh/year. Maximum           Demand 4 MW load factor
                                                  night)                  Demand 500 kW load          6000 hours/year
                                                                          factor 4000 hours/year
Austria                        17.05                     14.36                      12.30                         10.23
Belgium                        17.22                     14.92                      12.59                         10.26
Bulgaria                       7.39                      7.01                        6.70                          6.42
Czech Republic                 11.42                     8.57                        9.86                          8.66
Denmark                        26.71                     23.25                      12.93                         12.48
Estonia                        8.15                      7.27                        6.98                          4.88
Finaland                       12.35                     9.84                        7.53                          7.03
France                         13.19                     11.83                       7.65                          6.63
Germany                        21.25                     20.10                      13.89                         12.73
Hungary                        14.45                     13.73                      12.70                         11.05
Italy                          25.54                     22.13                      17.07                         14.01
Netherlands                    23.77                     23.34                      13.38                          9.18
Poland                         13.69                     12.36                       8.31                          7.51
Romania                        12.60                     11.30                      12.85                          9.76
Spain                          13.36                     11.40                       8.82                          7.61
Sweden                         18.73                     18.32                       6.89                          6.04
United Kingdom                 13.76                     12.85                       9.90                          3.95
                                                Source: http://www.energy.eu/

EU-wide average price movements for medium size households and industries during 2005-2009
are provided in Exhibit 17. Medium size industrial consumers have annual consumption between
500 MWh and 2000 MWh. Medium size households consume between 2,500 and 5000
kWh/year. The prices do not include taxes and duties.
            Exhibit 17: Price Changes for Industries and Households in EU (2005-2009)
                                                Prices in Eurocents/kWh
       Consumer Category                       2005                 2006               2007               2008            2009
       Medium Households                       10.13               10.68              11.73               11.87           12.36
        Medium Industry                        6.72                 7.52               8.20                8.78           9.41
            Source: http://epp.eurostat.ec.europa.eu/tgm/table.do?tab=table&init=1&language=en&pcode=tsier040&plugin=1


6. Prospects for Trade
ENTSO-E continues to expand. In order to interconnect to the ENTSO-E grid, the supplying grid
is required to conform to EU regulations and directives, and strictly adhere to them. The
principal objective of the EU synchronized operation of larger and larger areas is to reap the
benefits of increased reliability and system security, including reduced capacity reserve margins,
better utilization of capacity by taking advantage of diversity in peak demand among the member
countries which are stretched across a continent with different time zones and different weather
conditions, and above all, to develop a platform for competitive trade and exchange of power
among the member countries. The EU is an excellent export destination with attractive electricity
prices, an open, competitive market structure with third party access, multiple market

                                                                 172
participants and synchronous network operation. However, exports must enter the EU through
countries that have power systems that meet the ENTSO-E requirements.




                                           173
Attachment 2.D: Electricity Sector in Turkey
     1. Overview
Turkey has a population of 72.8 million, a GDP of US$ 957 billion (purchasing power parity)
and a per capita GDP of US$ 13,392 (estimated 2010). Its economy grew steadily from 2002-
2008 at a high annual rate of about 7%. Inflation has come down to single digits and interest
rates have declined significantly. Growth has been sustained largely by rising exports and
substantial capital inflows to the private sector. Since the fourth quarter of 2008, the effect of
world-wide recession has been felt through a decline in export demand and capital inflows. As a
result, the overall growth for 2008 was only 1.7%.
Oil has the largest share of Turkey’s total energy consumption at 35% followed by natura l gas at
29%, coal/lignite at 25%, and hydropower and other renewable energy at 11%. Its energy
resource endowments are modest, requiring that major portions of the energy demand be met by
oil, gas and coal imports. The cost of energy imports in 2008 amounted to US$ 48 billion or
about 36% of the value of Turkey’s corresponding total exports.
As of January 2009, Turkey’s proven oil and natural gas resources were estimated at 300 million
barrels and 300 billion cubic feet (bcf), respectively. Domestic production of oil at 46,120 barrels
per day (2008) was only 6.8% of the total oil consumption. The share of the domestic production
of natural gas was even lower at 2.5% of the total gas consumption. 74 Domestic production of
hard coal (with high sulfur) at around 2.0 million tons is about 10% of domestic consumption.
The country has extensive lignite deposits (also with high sulfur) and the reserves are estimated
at 8.1 billion tons (about 80% of which has calorific values lower than 2,500 kcal/kg). About
34% of the deposits have been developed and another 3% is in the process of being developed.
Annual production was at about 55 million tons in 2005 to meet the demands of the power,
cement and steel industries. 75
With respect to renewable energy, the country’s economically exploitable potential has been
estimated at: (a) 126 to 128 TWh for hydroelectricity (about 30% of which has been developed);
(b) 48,000 MW (or 96 TWh) for wind energy; and (c) 600 MW for geothermal with another
30,000 MW of possible geothermal sources suitable mainly for heating.
The state-owned Turkish Petroleum Corporation competes with the private sector in oil
exploration, production and refining and has a 70% share of domestic production. It has
preferential rights and many foreign oil companies form joint ventures and partnerships with it
for these activities. The state owned Petroleum Pipeline Corporation (BOTAS) dominates the gas
industry and owns the gas transmission networks. In order to increase the role of the private
sector, BOTAS is required to transfer a good part of its long term import contracts to the private
sector. Gas distribution has been entirely privatized. In the power sector, the role of the private
sector is increasing and a competitive market structure is in the process of being implemented as
part of electricity sector reform.



74
  Data from Country Analysis Brief on T urkey (updated as of April 24, 2009) available at www.eia.doe.gov
75
  Mustafa Balat, Energy Consumption and economic growth in T urkey during the last two decades in Energy Policy 36 (2008)
118-127



                                                          174
   2. Power Sector Structure
The original state owned vertically integrated Turkish Electricity Corporation (TEK) has been
unbundled over several years to enable private sector participation and the implementation of a
competitive electricity market. Currently:
      Generation in the public sector is handled by the Electricity Generation Company of
       Turkey (EUAS). It directly owns most hydropower units, and also acts as the holding
       company for six portfolio generation companies with thermal power units and some
       hydropower units. In addition there are several private sector generating units established
       under BOT and BOO arrangements supplying power to the grid on the basis of power
       purchase agreements guaranteed by the government. There are also a few privately
       owned independent power producers (IPPs). Industries with captive generating units
       (called auto-producers) and privately owned renewable energy units also supply power to
       the grid.
      Transmission and dispatch are handled by the Turkish Electricity Transmission company
       (TEIAS). It also operates the balancing market and acts as the settlement agent.
      Distribution   is handled by 21 regional distribution companies, twenty of which are the
       holders of      operating rights for their franchise areas from the Turkish Electricity
       Distribution    Company (TEDAS). The remaining one (Kayseri) is a privately owned
       distribution   company.
      Turkish Electricity Trading and Contracting Company (TETAS) acts is the buyer of all
       power from BOT and BOO units under the terms and conditions of the PPAs, and in turn
       markets the power to distribution companies.
      Electricity Market Regulatory Authority (EMRA) is the independent regulator of power,
       gas, petroleum and LPG, responsible for licensing, tariff setting and other associated
       responsibilities.




                                               175
       3. Market Organization
The current market structure is shown in Exhibit 1.
                           Exhibit 1: Turkey’s Current Electricity Market Structure




TETAS blends the more expensive power from BOT and BOO units with the less expensive
power from the hydropower units of EUAS, and sells it to the 20 distribution companies on the
basis of long term contracts (called transitional or vesting contracts) valid through 2010 initially,
but since extended by a few years. The six portfolio companies of EUAS have similar
transitional long term contracts with the 20 distribution companies. The IPPs have bilateral
contracts with the buyers. The buyers include not only the distribution companies, but also
“eligible consumers” who are large consumers (with an annual consumption of 6 GWh or higher)
eligible to choose their suppliers. As a part of the progressive liberalization of the market, the
eligibility threshold was reduced in 2008 to 1.2 GWh. Eligible consumers have a 41% share of
the total electricity market. The consumption threshold for eligibility is being further lowered
with the aim of making all non-residential consumers eligible by 2011. By 2015 all consumers
are expected to be eligible. 76
The transitional contracts enable absorption of the high cost power under guaranteed PPAs and
provide guaranteed supply to the distribution companies (which are being privatized). The
distribution companies can cover only up to 85% of their demand by such contracts and must use
the balancing market for the remaining requirements. Dispatch is based on long term contracts
supplemented by the balancing market where prices fluctuate as a function of supply and
demand. In 2007 about 31.3 TWh (or 19% of all electricity sold in Turkey) traded in the
balancing market. In all, there are 129 licensed market participants consisting of 103 private

76
     T he threshold has come down to 0.4 GWh/ year in 2009.



                                                              176
entities and 20 regional distribution companies besides TETAS, EUAS and its portfolio
companies.
The current balancing and settlement system involves day-ahead bidding and scheduling
administered by the market operator unit of TEIAS, and real time pay-as-bid balancing
administered by the national load dispatch center of TEIAS. Settlement is monthly.
Improvements actively under consideration include:
         (a) Change from monthly to hourly settlement periods;
         (b) Progressive development of balancing and settlement into a separate and
             complementary day-ahead spot market 77 operated by a market operator (expected to
             be a TEIAS subsidiary with adequate financing and autonomy) and a real time
             balancing market operated by TEIAS dispatch center; and
         (c) Introduction of a capacity mechanism (capacity obligations and trading of capacity
             certificates) to complement energy trading through bilateral contracts and the
             balancing market.
The prices in the balancing market reflect the marginal cost of electricity at the wholesale market
level. The average price at which power was sold in the balancing market in 2007 was YTL
128/MWh (or about 11 US cents/kWh). By March 2008 the average price rose to 160 YTL
reflecting the increasingly tight supply position. 78 Owners of most wind power and other
renewable energy units prefer to sell in the balancing market rather than use the government
guaranteed “feed-in” rate as they get much higher prices in the balancing market. 79 Further, the
wholesale electricity price moved up sharply by 44% during 2007-2008 largely as a result of gas
price increases. During the period May 2007 to May 2008 prices remained above 10 US cents /
kWh throughout the day during the months of January and February. In the remaining months
prices tended to dip to the 4 to 7 US cent range during the off-peak period (1AM to 7AM).
During the remainder of the day prices in the range of 11 to 14 cents prevailed, reflecting both
high gas prices and a relatively tight supply condition. 80 The average base load price during the
period from August 2006 to April 2009 was Euro 73.88 / MWh. The highest base load price
occurred in August 2008 at Euro 98.14 / MWh, while the lowest base load price was in February
2009 at Euro 59.17/MWh. 81
     4. Demand and Supply
4.1 Demand
In 2007 the peak demand was 29,249 MW and the ratio of the base load to peak load was 38%.
The system load factor had been around 70% for the past decade. The daily load curve of the
Turkish grid on the day of the annual peak in 2007 is provided in Exhibit 2.

77
   T he dry run for the day-ahead trading was to start in July/ August 2009.
78
   World Bank, Implementation Completion Report on T urkish National T ransmission Grid Project, June 2008
79
   T he balancing market prices in 2006 and 2007 ranged from 7 to 10 Euro cents / kWh compared to the government guaranteed
feed-in price of 5 to 6 Euro cents / kWh. See Latham & Watkins and Fidan & Fidan , Turkish renewable energy —blowing in the
right direction? (Feb 24, 2009) available at www.lw.com
80
   Electricity Export Opportunities from Georgia and Azerbaijan to T urkey, a Report prepared by Econ Poyry AS, of Norway for
the government of Georgia available at www.minenergy.gov.ge
81
   A Spotlight on Turkish Electricity Market , a presentation by Cem Ali Atilgan in Budapest on June 3-4, 2009, available at
www.atilganenergy.com



                                                            177
                      Exhibit 2: Daily Load Curve on Day of 2007 Annual Peak




                                       Source: www.teias.gov.tr
In the Turkish grid the annual peak occurs in winter, and during the last several years the annual
peak occurred in December. As a result of rise in tourism and air conditioning load, summer
loads (especially in July and August) are rising rapidly and from time to time approach the level
of the winter peak load. The monthly variation in the loads over the year during 2001-2007 can
be gauged from Exhibit 3 which shows the ratio of monthly peaks to annual peaks.
              Exhibit 3: The Ratio of Monthly Peaks to Annual Peak in Turkish System




                                       Source: www.teias.gov.tr
The primary generators are in the east and south-east of the country, while the major load centers
are in the west and north-west. This necessitates long transmission lines. Transmission is by 400
kV, 154 kV and 66 kV lines with a total length exceeding 46,000 km and 535 substations with a
total transformer capacity exceeding 82,000 MVA. The Turkish grid is interconnected with those
of Bulgaria, Iran, Georgia, Syria, Azerbaijan, Iraq, and Greece. Despite the long distances
involved in the transmission grid, transmission losses are only about 2.6% (2007).
Most areas in the country have access to grid-supplied electricity; electrification of the country is
near 100%. Distribution is by 33 kV, 15.8 kV, 10.5 kV, and 0.4 kV. Total length of distribution
lines in 2007 was about 0.923 million km. The total transformer capacity in the distribution
system was greater than 100,000 MVA. Overall losses in the distribution system (including theft)
were reported at 21.6% in 2000, but have come down to about 14.8% by 2007. However, losses



                                                 178
range widely among the 21 distribution entities —from 6.3% for the Osmangazi distribution
company to 64% for the Dicle distribution company. 82
Electricity demand has been growing at an average annual rate of about 8% during the last four
decades. From 1998-2007 peak demand grew at a compounded annual growth rate (CAGR) of
5.7% while the energy demand grew at a CAGR of 5.8%. The growth was more rapid during
2003-2007 facilitating a steady spurt in economic growth (see Exhibit 4). However, energy
demand growth slowed down to 3.7% in 2008. Demand actually declined in the last months of
2008 and first months of 2009 by 5-7% on a monthly basis compared to the previous year as a
result of the deceleration of economic growth and economic contraction.
                         Exhibit 4: Historical Growth in Turkey’s Electricity Demand
                                   Year            Peak Demand (MW)           Energy Demand (GWh)
                                   1998                   17.799                       114,023
                                   1999                   18,938                       118,485
                                   2000                   19,390                       128,276
                                   2001                   19,612                       126,871
                                   2002                   21,006                       132,553
                                   2003                   21,729                       141,151
                                   2004                   23,485                       150,018
                                   2005                   25,174                       160,794
                                   2006                   27,594                       174,637
                                   2007                    29249                       190,000
                                 CAGR (%)                  5.67%                        5.84%
                       Source: 10-Year Generation Capacity Projection (2008-2017) available at www.teias.gov.tr


Per capita annual electricity consumption in Turkey at 2,150 kWh is around a third of that in the
EU.
In 2007, industrial consumers had the largest share in total consumption at about 48%, followed
by residential consumers at 24%, commercial consumers at 15%, public offices at 4%, street
lighting at 3% and others at 6% (see Exhibit 5).




82
   T easer for Distribution Privatization in 2008 available at www.oib.gov.tr the website of the Privatization Agency of the
T urkish government



                                                                179
                Exhibit 5: Breakdown of Electricity Consumption by Customer Class




A demand forecast has been made by the Turkish Power Transmission Company (TEIAS) for the
period 2008-2017. In the base case, gross energy demand is expected to have a CAGR of 7.45%
and in the low case scenario the CAGR is expected to be 6.6% (see Exhibit 6).
                    Exhibit 6: Demand Forecast for the Turkish Electricity System
               Year                        Base Case                                      Low Case
                             Peak Demand            Gross energy          Peak Demand             Gross energy
                                 (MW)             demand (GWh)                 (MW)              demand (GWh)
               2008              32,478               204,000                 32,143                 204,000
               2009              35,053               219,013                 34,571                 216,992
               2010              37,832               236,182                 37,182                 230,705
               2011              40,716               253,837                 39,573                 246,181
               2012              43,819               272,812                 42,331                 262,696
               2013              47,159               293,205                 45,167                 280,319
               2014              50,753               315,123                 48,193                 299,124
               2015              54,622               338,679                 51,421                 319,190
               2016              58,560               363,695                 54,788                 340,379
               2017              62,782               390,559                 58,376                 362,975
             CAGR (%)            7.60%                 7.45%                  6.85%                   6.60%
                  Source: 10-Year Generation Capacity Projection (2008-2017) available at www.teias.gov.tr


4.2 Supply
Turkey operates a national grid with an installed generating capacity of 42,186 MW of which
about 66% is thermal, 33% is hydroelectric and the rest based on geothermal and wind. Annual
energy generation in 2008 was 198.6 TWh serving 29.5 million consumers.
From 1998-2008 supply expanded from 111 TWh to 199 TWh at a CAGR of 6.0%, and installed
generation capacity increased from 23,354 MW to 42,186 MW at a CAGR of 6.1% (see Exhibit
7).
                  Exhibit 7: Historical Expansion of Electricity Generation in Turkey

                                                           180
                                  Installed Generation Capacity (MW)                      Annual Power Generation (TWh)
              Year           Thermal             Hydro               Total             Thermal           Hydro       Total
              1998            13,039             10,315              22,354               69               42         111
              1999            15,573             10,546              26,119               82               34         116
              2000            16,070             11,194              27,264               94               31         125
              2001            16,641             11,692              28,332               99               24         123
              2002            19,586             12,260              31,846               96               33         129
              2003            22,989             12,598              35,587              105               36         141
              2004            24,160             12,664              36,824              105               46         151
              2005            25,917             12,926              38,844              122               40         162
              2006            27,380             13,122              40,565              132               44         176
              2007            27,295             13,541              40,836              156               36         192
              2008            27,782             14,404              42,186              164               35         199
                          Source: www.teias.gov.tr - Note: Hydro figures include wind power and geothermal power


Installed generation capacity at 42,186 MW was well above the peak demand of about 32,500
MW in 2008 providing an apparent reserve margin of about 30%. However, the demand/supply
balance was tight because available capacity was only about 33,000 MW owing to wide
fluctuations in annual river flows in respect of hydropower units and the old age of lignite fired
thermal power plants.83 Demand is expected to outstrip supply in 2011 if additional new
generation capacity does not come on line.
In 2008, hydropower had the largest share of generation capacity at 32.9%, but contributed only
16.8% of the total electrical energy production in that year. Natural gas fired combined cycle
units had a 32.3% share of the capacity, but made the largest contribution to energy at 48.4%.
Lignite and hard coal had a share of 23.9% of the capacity and contributed 29.0% of the energy
(see Exhibit 8). The rising cost of imported natural gas has significantly increased the average
cost of generation in Turkey.
                     Exhibit 8: Generation Capacity and Energy Production in Terms of Fuel
                                                      Installed        Percentage in     Generation in     Percentage in
                 Category of Generation Unit       capacity (MW)       total capacity     2008 (GWh)            total
                                                                                                            generation
                        Hard Coal fired                    1,986                4.7            15,618            7.9
                          Lignite fired                    8,110               19.2            41,939           21.1
                         Fuel oil fired                    1,745                4.1             9,315            4.7
                     Diesel, LPG, Naphtha                    48                 0.1             1311             0.7
                          Natural Gas                     13,612               32.3            96,041           48.4
                           Multi-fuel                      2,214                5.2               --              --
                        Bio-gas /waste                       67                 0.2              195             0.1
                          All Thermal                     27,782               65.9            164,419          82.8
                          Hydropower                      13,875               32.9            33,283           16.8
                          Geothermal                         77                 0.2              98               ..
                          Wind power                        452                 1.0              798             0.4
                        All Renewables                    14,404               34.1            34,179           17.2
                          Grand Total                      42186              100.0            198,598         100.0
                                    Source: Info available at www.teias.gov.tr and World Bank (May 2009)


In 2007 thermal power plants in Turkey consumed 5.6 million tons of hard coal, 50.6 million
tons of lignite, 1.8 million tons of liquid fuels (fuel oil, diesel and naphtha) and 17.0 bcm of
natural gas, and generated 155.2 TWh of electricity. The heat value of the total fuels used has
been estimated at 333,654 Tcals.
Of the total installed capacity of 40,836 MW in 2007, state-owned power plants had a 58.6%
share while the private sector had a 41.4% share. The private plants include units under build and

83
     About 57% of the thermal plants owned by the state had been in operation for 20 years or more



                                                                   181
operate contracts (BO), build, operate and transfer contracts (BOT), transfer of operational rights
contracts (TOOR), mobile units, privately owned generating companies and “auto-producers”
(captive generating units owned by industries). The share of the state-owned power plants has
come down from about 90% in 1990 to 58.6% in 2007.
Of the 191,558 GWh of electricity generated in 2007, private sector plants had a share of 51.8%,
while the state owned units had a lower share of 48.2%. The private sector share in generation
has grown from about 8% in 1990 to 51.8% in 2007. A substantial portion of the output from the
private plants is covered by power purchase agreements with the state owned utilities and
guaranteed by the state.
In order to meet forecast demand under the base case scenario, Turkey plans the addition of
17,136 MW with an annual production capability of 77.9 TWh during 2008-2015 time frame.
State-owned plants under construction amount to 4,518.7 MW with an annual production
capability of 16.8 TWh. A total capacity of 12,817.5 MW with an annual production capability
of 61.1 TWh is covered by generation licenses granted to private investors. About 68% of the
new capacity will be hydroelectric, 26% will be thermal and the remaining 6% will be based on
renewable sources such as wind and geothermal.
Under the low load growth scenario, capacity additions envisaged during the same period
amount to 12,917 MW of which 33% will be from state-owned entities and the remainder from
private licensees. The expansion plan scenarios are shown in Exhibit 9.
                                Exhibit 9: Generation Expansion Plan (2008-2015)
     Categories                                              Additional       Additional    Additional annual firm
                                                             generation       Annual        power generation
                                                             capacity (MW)    generation    (GWh)
                                                                              (GWh)
     A. Base Case
     State owned power plants under construction                  4,318.7        16,825.9         12,520.4
     Private Sector power plants licensed                         12,817.5       61,061.8         47,339.7
     Total                                                        17,136.2       77,887.7         59,860.1
     Hydropower Capacity                                          11,682.4       41,587.4         24,537.9
     Thermal power Capacity                                       4,523.2        32,586.4         32,312.8
     Wind / Geothermal / other                                     930.6          3,713.9          3,189.4
     Total                                                        17,136.2       77,887.7         59,860.1
     B. Low Case
     State owned power plants under construction                  4,318.7        16,825.9         12,520.4
     Private Sector power plants licensed                         8,598.8        41,848.9         33,581.6
     Total                                                       12,917.5        58,674.8         46,102.0
     Hydropower Capacity                                          8,627.2        29,455.4         17,542.9
     Thermal power Capacity                                       3,791.5        27,194.7         26,921.1
     Wind / Geothermal / other                                     498.8          2,024.7          1,638.0
     Total                                                       12,917.5        58,674.8         12,520.4
                                                   Source: www.teias.gov.tr


The approach to generation expansion is to give high priority to hydropower, lignite fired
thermal units, wind power and to lower the predominance of gas fired thermal units in view of
the high and rising imported gas prices. In the recently announced sector strategy paper, the
government has set an ambitious target of 20,000 MW for wind power by 2023. The government
is also pursuing the possibility of constructing an investor-owned nuclear power plant of 4000 to
5000 MW by 2020.




                                                            182
4.3 Trade
Details of the existing interconnections between Turkey and its neighbors are provided in
Exhibits 10 and 11.
                        Exhibit 10: Turkey’s International Interconnections




                     Source: Cem Ali Atilgan, A Spotlight on the Turkish Electricity Market, June 2009


                Exhibit 11: Details of Existing International Power Interconnections
   Country      Details of existing interconnection
   Bulgaria     Two 400 kV lines from Babaeskito in Turkey to Maritsa East Power station in Bulgaria. The first one is 136 km
                long and its thermal limit for transmission is 1000 MW. The second line is 150 km long and its thermal limit for
                transmission capacity is 2000 MW.
   Greece       400 kV line from Babaaeski to Nea Santa in Greece. Turkish portion was completed in 2006 and operated at 154
                kV and connects to Greece 154 kV network. The Greece portion was completed in mid-2008. When operated at
                400 kV, its transmission capacity is 2000 MW.
   Georgia      220 kV line from Hopa (Turkey) to Batumi. Price paid 2.6 cents/kWh in 2007. Import in island mode.
   Armenia      220 kV. This has not been operated in recent years.
   Azerbaijan   One 110 kV line and one 154 kV line from Nakhchivan enclave of Azerbaijan to Turkey via Iran. Operates in
                island mode for import and export.
   Iraq         400 kV line operated at 154 kV. Exports to Iraq take place in island mode. Prices paid by Iraq were reported at 4.9
                Euro cents/kWh (about 6.3 US cents/kWh).
   Iran         154 kV link currently not in operation, but the new 400 kV link is operated at 154 kV. Import of power from Iran
                takes place in island mode. Import price from Iran was reported at 3.5 US cents/kWh in 2007.
   Syria        400 kV AC line from Birecik (Turkey) to Halep (Syria). Exports to Syria were done in unit direction mode in 2007
                and in 2008.

Although the Turkish grid is interconnected to those of Bulgaria, Greece, Syria, Iran, Iraq,
Georgia, Azerbaijan and Armenia, the volume of electricity exchanges has been modest at less


                                                             183
than 2% of Turkey’s annual consumption in recent years (see Exhibit 12). Imports from Bulgaria
(significant in earlier years) ceased in 2004. Imports from Turkmenistan via Iran have increased
significantly since 2003 following commissioning of: 1) the 270 km, 220 kV line from
Balkanabat (Turkmenistan) to Gonbad (Iran) and further on to Khoy Bashkale (Turkey), and 2)
the transmission line linking of Serakhs (in Turkmenistan) to Sarakhs (in Iran). 84
In 2004 the price for imports from Turkmenistan were reported as 3.45 US cents/kWh. The
transit fee payable to Iran was 0.65 cents/kWh. 85 Georgia and Azerbaijan are seriously
examining the possibilities of expanding their exports to Turkey by promoting investments in
new Georgian hydropower projects and Azeri thermal power projects.
                 Exhibit 12: Historical Electricity Import-Export Trade Volumes of Turkey (GWh)
       Country                     Exports from Turkey                                  Imports to Turkey
                        2001      2003       2004      2006         2007       2001   2003      2004      2006   2007
  Bulgaria                                                                     3776   1135          0        0      0
  Greece                                                0.0           90
  Georgia                                               107          118        523                         41    216
  Azerbaijan             433       402        379       326           15                                           15
  Iraq                             186        766      1669         1237
  Iran                                                                          281      0         0         0      0
  Syria                                                  135        962
  Turkmenistan             0         0          0          0           0                24       464       533    633
  Total                  433       588       1145      2237        2422        4580   1159       464       574    864
                                                    Source: www.teias.gov.tr


Turkey’s electricity imports have increased steadily from 433 GWh in 2001 to 2422 GWh in
2007. Exports to Azerbaijan have decreased reflecting the domestic supply improvements there.
Exports to Iraq and Syria have increased significantly.
       5. Tariffs
End-user tariffs are the sum of the energy cost, the transmission charge and the distribution
charge. Energy costs are determined by the cost of power purchased under bilateral contracts and
energy prices in the balancing market. The transmission charge and the distribution charge are
regulated. The distribution companies are being privatized and will have a cost reflective tariff
based on a trajectory of performance improvements in such areas as loss reduction, billing and
collection. The electricity purchase cost will have a price cap, and distribution charges will have
revenue caps which cover operating expenses and investment needs. The transmission charge is a
full pass through item. This approach results in different tariffs for different distribution
companies depending on their cost structure.
To avoid sudden price fluctuations, the government is maintaining the national uniform tariff
scheme under which the tariff for each customer class is uniform across the country during a
transition period from 2006-2010. This is accompanied by an equalization scheme involving
transfer of revenues across the various distribution companies so that each distribution company
is able to secure revenues to cover its costs. The transition period has since been extended until
year-end 2012 to facilitate the orderly completion of the privatization of distribution and
generation companies.


84
     Based on information from www.turkemenistan.ru news items dated April 12, 2004 and August 23, 2004.
85
     Based info at www.eurasianet.org/resource/hypermail/200404/0013.shtml



                                                              184
The average cost of supply/kWh in the distribution segment rose from YTL 0.118 in 2005 to
YTL 0.121 in 2008, while the average retail tariff rose from YTL 0.120 to YTL 0.154 enabling
full cost recovery. This was achieved through tariff increases in January, July and October 2008
resulting in an overall increase of 50%. 86 Further, an automatic mechanism enabling full pass-
through of cost increases such as fuel price changes has been implemented.
The average end-user price/kWh in the fourth quarter of 2008 was 15.28 US cents/kWh
including taxes (12.68 US cents/kWh excluding taxes). Corresponding average residential prices
were 15.81 cents (with taxes) and 12.82 cents (without taxes) while the average non-residential
prices stood at 15.02 cents (with taxes) and 12.62 cents (without taxes). 87
Considering Turkey’s tariffs from an international perspective, Turkey’s average residential
tariff of 15.81 US cents/kWh (including taxes) is comparable to tariffs of countries in the EU.
     6. Prospects for Trade
Turkey’s joining the UCTE through interconnections with Greece is a key element of the
Mediterranean Electricity Ring interconnecting the systems of France, Spain, Morocco, Algeria,
Tunisia, Libya, Egypt, Near Eastern countries, Turkey, Greece and Italy. Similarly, the Turkey-
Bulgaria link is a key element of the Black Sea Electricity Ring initiative interconnecting the
systems of Russia, Ukraine, Romania, Bulgaria, Turkey and Georgia.
Interconnections of Turkey with Syria and Iraq are key components of the Eight Countries
Interconnection Project linking the systems of Egypt, Iraq, Jordan, Lebanon, Libya, Syria,
Palestine and Turkey.
Azerbaijan, Georgia and Turkey have recently signed an MOU for a “Power Bridge project” to
facilitate a much greater level of electricity trade among the three countries. This envisages:
     a) The construction of a new 500 kV AC line from Azgunz (Azerbaijan) to Zeastaponi
        (Georgia) via Garadabani (Georgia);
     b) The construction of 500 kV AC lines from Zestaponi and Gardabani to Akhalsikhe
        (Georgia);
     c) A back-to-back AC to DC and DC to AC facility at Akhalsikhe; and
     d) The construction of a 400 kV AC line from this facility (in Georgia) to Borchka in north
        eastern Turkey.
Total cost is expected to be about US$ 312 million. Power transfer capacity of this “Power
Bridge” would be about 1000MW. Georgia is promoting investments in hydropower projects
with export objectives, and Azerbaijan hopes to export its surplus thermal power. Tendering is
expected for the line in 2009. 88
Details of other Interconnection Proposals under consideration are given in Exhibit 13.


86
   World Bank (May 2009) Program Document for the First Programmatic electricity sector loan to T urkey
87
   Information from www.erra.net
88
   Electricity Export Opportunities from Georgia and Azerbaijan to T urkey, a report by ECON Poyry AS to the Government of
Georgia available at www.minenergy.gov.ge See also (a) the Presentation to Medelec on March 24, 2009 entitled Electricity
Network Interconnections of T urkey by T EIAS officials, and (b) P resentation entitled “ Recent developments in T urkish Power
System” by T EIAS in BST PP WG Meeting at Lviv, Ukraine, on 3 -4 December 2008



                                                             185
                         Exhibit 13: Details of Other Electricity Interconnection Proposals
               Country                                                    Details of proposals
               Georgia         Converting the 220 kV line Hopa- Batumi to 400 kV AC with back to back AC/DC/AC convertor
                               station at Batumi (Georgia) is under consideration.
                 Iran          Asynchronous connection through a back-to-back DC/AC convertor on the existing 400 kV line and
                               construction of an additional 400 kV line are being considered.
                 Iraq          Construction of an additional 400 kV line is underway. The cross border point has been determined.
                               Construction of the line on the Iraqi side has been initiated and construction on the Turkish side is to
                               begin soon.
               Romania         A 400 km, 400 kV HVDC submarine cable under the Black Sea from Constanta in Romania to
                               Pasakhoy in Turkey with an expected commissioning date of 2018 is being pursued. 89 It will have
                               convertor stations at either end, and will have a transfer capacity of 600 MW.

Turkey has excellent prospects as an electricity export destination and as a transit country for
exports to the EU. It has attractive electricity prices, an open, competitive market structure with
third party access, multiple market participants and in light of its impending membership in
ENTSO-E, synchronous operation with the European grid (expected in 2012). Exhibit 14
provides an update on the status of Turkey’s application to join ENTSO -E, and on its
involvement in the Energy Community of South East Europe (ECSEE) Treaty.
Turkey’s tightening supply position and the rising cost of generation has prompted increased
interest in relatively less expensive imports. Further, its use of high sulfur coal and lignite for
power generation has raised environmental concerns which can be partially mitigated through
imports of non-, or less-, polluting power imports.
Import and export of electricity in Turkey is liberalized. Turkish electricity market import/export
regulations follow Regulation 1228/2003 of the European Commission. Besides TETAS, the
state owned power trading company, and the 22 distribution companies, there are over 36
licensed private sector wholesale power traders – all of which are eligible to import and export
electricity on the national grid. Many of the private licensees are large multinational firms with
substantial annual turnovers (in the range of US$ 5 million to US$ 168 million).
The Electricity Market and Security of Supply Strategy Paper approved by the High Planning
Council of Turkey on May 18, 2009 outlines the approach for increasing electricity trade in the
following terms:
          The goal is to join UCTE and operate the Turkish system in a parallel and synchronous
           manner with the European Transmission network by 2010;
          Complete studies and improvements to the grid in time to achieve this goal;
          Carry out cross border trade with Europe in conformity with the EU Cross- Border Trade
           Directive and national legislation;
          Connections with other non-EU countries will be required to comply with conditions
           associated with Turkey’s membership in UCTE and its connection to the European grid;
          For such countries, Direct Current (DC) methods will generally be necessary including
           the construction and use of AC to DC and DC to AC convertor stations. Such convertor
           stations and facilities which must be constructed within Turkey’s border will be
           constructed by TEIAS as a part of the national transmission system;

89
     T ransmission Development Plan (2008), UCT E available at www.ucte.org



                                                                    186
        Until such DC connection facilities become available, imports and exports will only be
         possible through unit direction or in an island mode; and
        Trade carried out by unit direction or in island mode must not adversely affect the quality
         and security of supply on the Turkish system. The quality of imports must comply with
         Turkish legislation.
The Electricity Market Law of 2001 obliges the transmission and distribution companies to allow
open, guaranteed and non-discriminatory access to the network by third parties to facilitate
competition in the electricity market. Such third party access to the networks, connection fees,
and system usage tariffs are all regulated by EMRA. The Grid Code and the electricity market
licensing regulations incorporate the principles and practices of third party access and its
requirements. Transmission system capacity for export-import transactions is allocated by
TEIAS on a pro-rata basis. TEIAS is obliged to make use of a bidding process when demand
from traders exceeds currently available capacity. Procedures relating to transmission access are
broadly in line with EU directives. When the capacity demand for imports / exports is within the
available capacity, normal regulated transmission prices apply.
Transmission tariffs generally follow EU guidelines for transmission pricing and consist of:
     a) A connection charge;
     b) A use-of-system charge related to the investment and O & M costs of the system for bulk
        transfer of electricity, system security and quality of supply; and
     c) A system operation charge related to the costs of real time balancing of supply and
        demand and ancillary services.
The use of system charge is based on the concept of long run marginal costs, while the system
operation charge is regulated on the basis of a revenue cap methodology. Further, the use of
system charge varies among the 22 regions to provide incentives for the location of generation
where it is most needed form the point of view of regional supply-demand balance.
The average transmission revenue for TEIAS was estimated at 0.46 US cents/kWh in 2008. 90
The transmission charges are shared on a 50:50 basis between the generators and the distributors
(or more generally, the buyers and sellers in the wholesale and balancing markets).
There appears to be no special regulation regarding the wheeling of power to third countries via
the Turkish grid. When Turkey becomes a member of the ENTSO-E, the basis for wheeling
charges is likely to follow EU and ENTSO-E guidelines.




90
  World Bank, Implementation Completion Report on T urkish National T ransmission Grid Project, June 2008



                                                          187
Attachment 2.E: Electricity Sector in Iran
     1. Overview
Iran’s 2010 estimated population is 76.9 million and GDP is US$ 830.7 billion (purchasing
power parity). The real GDP growth rate during 2001-2007 was in the range of 3.0% to 7.5% per
annum and it declined sharply to 2.5% in 2008, largely due to oil and gas price movements.
Government revenues as a percentage of GDP fell during FY 2007-08 to 24.5% from the
previous year level of 30%, while expenditures increased from 24.8% to 25.1%. A large part of
the expenditures were met by drawing down the Oil Stabilization Fund. The year was expected
to end with a fiscal deficit of 0.6%. Trade surplus declined from $40.8 billion to $21.0 billion.
Current account surplus fell from 11.9% of GDP to 6.7%. Tight monetary policies helped to
lower the annual inflation rate to 18% from the previous year level of 22.4%. 91
Iran is well endowed in terms of oil and gas. Its proven oil reserves at year-end 2008 were
estimated at 18.9 billion tones (10.9% of the world total and second largest in the world after
Saudi Arabia) with reserves to production ratio of 86.9 years. Iran’s proven natural gas reserves
were estimated at 29.61 trillion cubic meters (16% of the world total and the second largest in the
world after Russia) with a reserve-to-production ratio exceeding 100 years. It has also modest
reserves of coal estimated at about 462 million tons.
Iran’s technical hydropower potential had been estimated at 42,000 MW, of which only 23,000
MW is considered practical. About 7,500 MW have actually been developed. 92 Its primary
energy consumption in 2008 was estimated at 192.1 million tonnes of oil equivalent (MTOE) of
which 105.8 MTOE (55%) was gas, 83.3 MTOE (43.4%) was oil, 1.7 MTOE (0.9%) was
hydroelectric power and 1.3 MTOE (0,7%) was coal. 93 Primary energy consumption increased
from 2000 to 2008 at an average annual rate of 6.4%, and one source forecasts that from 2008 to
2020 it may increase at an annual rate of 4.7%. 94
     2. Power Sector Structure
The Ministry of Energy is responsible for energy policy and for the regulation and control of the
electricity sector in all respects including the formulation of tariffs for approval by the Majlis.
The Ministry also fully owns Tavanir, the sector holding company, which in turn is the main
shareholder of the 16 Regional Electric Companies (which own the thermal generation and
transmission facilities within their territory) and the 42 Distribution companies.
The electricity sector is unbundled vertically by function and horizontally by the existence of
multiple companies for generation and distribution. Hydropower stations are owned and operated
by either the Regional Water Companies or by the Iran Water Resource Management Company,
which is fully owned by the Ministry of Energy. In addition, the Ministry of Energy fully owns
Iranian Grid Management Company which, though it does not own the transmission system, is

91
   Economic Update, Spring 2009 of the World Bank/IMF
92
   GH Bahmannia, Developing Gas Markets in Persian Gulf Case Study: Iran, Paper presented in the 23 Gas Conference at
Amsterdam in 2006 available at www.igu.org/html/wgc2990/pdf/paper/add9935.pdf
93
   T he main data source is BP Statistical Review of World Energy, June 2009. A recoverable coal reserv e of 462 million tons
(2007) was indicated in the Iran Country Analysis Brief of US Department of Energy available at www.eis.doe.gov
94
   Presentation by Dr. Fereidun Fesharaki on September 18 -19, 2009 at University of Southern California in the seminar on
Iranian Economy at Crossroads: Domestic and Global Challenges.



                                                            188
responsible for the operation of the transmission system (TSO), for system dispatch and for
market operations at the wholesale level. It is thus both a TSO and a MO. However, it is not
independent as it reports to Tavanir and the Ministry of Energy and is bound by their directives.
In the generation segment, besides the generation units (in the public sector) owned by the
Regional Electric Companies, there are a number of privately owned IPPs which are organized
as BOT or BOO units operating with energy conversion agreements (ECAs) with Tavanir.
Tavanir supplies them with free fuel and they produce power and supply it to Tavanir for a
conversion fee which covers capacity costs (related to the available capacity) and actual energy
conversion costs (related to the volume of electricity delivered).
   3. Market Organization
Iran operates a mandatory power pool. IPPs have energy conversion agreements with Tavanir,
which sells the power purchased from them to the pool. All public sector generating units sell
their output directly to the pool. All sales to the pool are on the basis of hourly bids with price-
quantity pairs submitted three days ahead of the day of dispatch. Power plants can submit up to
10 price-quantity pairs for each hour. The maximum capacity available can be changed up to 14
hours ahead of the day of dispatch. As of January 2009, about 90 power plants submitted bids in
the power pool for about 400 generating units.
The pool follows the principle of “pay-as-bid”. The sellers to the pool receive energy payments,
capacity payments and fuel payments (except in the case of hydro power units). The bid prices
for energy reflect non-fuel operating and maintenance costs plus a fuel price component
equivalent to about 0.5 US cents/cubic meter of gas. Bid prices are limited by a price cap of 1.3
US cents/kWh (as of January 2009). The capacity payment for each hour of the year for which
the plant was available is based on the annualized unit investment cost (typically $80/kW/year
for a gas turbine plant) suitably adjusted for the reserve margin. Payment for fuel is calculated on
the basis of about 7 US cents/cubic meter of gas and the same fuel charge /kWh is paid for all
units irrespective of the fuel used and the heat rate of the plant to encourage the more efficient
units and penalize the less efficient units. Payments for ancillary services such as reactive
support, primary frequency regulation and black start are currently based on negotiated contracts.
The rates for these services range from 1% to 6% of the availability payments.
The buyers in the pool are the 42 distribution companies and a few “independent licensees” who
can arrange for bulk electricity purchases for third party consumers. The buyers are obliged to
submit their estimated average demand (MW) and peak demand (MW) for each hour of the day.
The sale price from the pool to the buyers is based on the pooled average hourly prices and
consists of a capacity charge and an energy charge which are suitably adjusted for deviations
from the declared demand and energy.
The dispatch schedule is prepared on the basis of running a security constrained economic
dispatch model using the price-quantity pairs submitted by the generators and the demand
schedules submitted by the buyers.
The objective of the Government is to promote private investment, especially in the generation
segment, and to promote the use of bilateral contracts to create a competitive market
environment and to ensure a greater level of transparency in generation costs. All consumers
irrespective of the size of their annual consumption and the voltage level of their connection to



                                                189
the network have been given, under the law, the right to choose their supplier. In practice, only
large industrial consumers make use of this right.
All privately owned power plants connected to the network have three options: (a) to participate
in the Wholesale Electricity Market (WEM) either directly or through the mechanism of ECAs
with Tavanir; (b) to supply to the distribution companies, or other consumers on the basis of
bilateral contracts; and (c) to sell to IGMC on the basis of a guaranteed pre-determined rate
which varies from 0.5 US cents/kWh during off-peak hours to 3.1 US cents/kWh during peak
hours (also adjusted to reflect variations in seasonal demand). However, to this point, all power
plants supply to the pool either directly or through Tavanir and have not used the other options.
The only exceptions are the captive generating units owned by large industries which sell their
surplus generation to IGMC under the guaranteed rate.
The Market Monitoring Unit of the Ministry of Energy monitors the performance of the
electricity market. Market operations are also subject to regulatory oversight by the Electricity
Market Regulatory Board in relation to compliance with the market rules and the need to modify
or amend the rules. The Board consists of seven professionals appointed by the Minister of
Energy.
In spite of the elaborate market structure, there does not appear to be adequate competition
attracting new investments to meet the narrowing reserve margins owing to:
   1. Inadequate commercialization of the state-owned generation and distribution companies;
   2. Low price caps on spot energy bids;
   3. Low capacity payments that do not adequately reflect the scarcity of capacity; and
   4. Most importantly, monopoly and price distortions in the primary fuel markets.
   4. Demand and Supply
4.1 Demand
The breakdown of consumption by customer class is shown in Exhibit 1. Residential customers
have the largest share at 33.4%, followed by industrial customers at 32.6%, public offices and
services at 12.9%, agricultural customers at 11.6%, street lighting at 2.9%, and miscellaneous
customers (mostly commercial) at 6.6%. The annual load factor of the system is around 67%.




                                              190
                                        Exhibit 1: Electricity Sales by Sector




Iran’s daily peak demand occurs around 9 pm and the base load demand is about 40% of the
peak demand (Exhibit 2). System annual peak occurs in summer and the system minimum peak
occurs in winter or early spring. The seasonal variation in load is significant (Exhibit 3).
                                         Exhibit 2: Daily Load Curve (MW)

                    36000

                    34000

                    32000
      Demand (MW)




                    30000

                    28000

                    26000

                    24000

                    22000

                    20000
                            1   3   5       7     9     11     13   15   17      19   21   23

                                                      Hour of the day



Source: www.tanavir.org.ir




                                                         191
                       Exhibit 3: Monthly Variation of Peak Demand (MW)


                             37,000
                                                                  34,894
                             35,000

                             33,000

                             31,000

                             29,000
                                      26,863
                             27,000

                             25,000
                                      Mar-     Apr- May-   Jun-   Jul- Aug- Sep- Oct-   Nov- Dec-   jan-   Feb-
                                      Apr      May Jun      Jul   Aug Sep Oct Nov       Dec Jan     Feb    Mar


                                                                      Peak Demand MW




                                                    Source: www.tanavir.org.ir

During the last eight years electricity sales (in GWh) and Peak Demand (in MW) grew at
compounded annual growth rates of 7.8% and 7.6% respectively, compared to the real GDP
growth rate of 5.9%. Installed generation capacity and actual gross energy generation grew
during the same period at a compounded annual rate of 8.6% and 8.1%, respectively (Exhibit 4).
Lower availability of generation capacity and relatively high levels of network losses and self
consumption by generating units has resulted in reserve margins becoming tight with supply
constraints emerging, particularly in the summer months.
                 Exhibit 4: Historical Growth in Electricity Supply and Demand
                           Installed Generation              Energy Generation
              Year                                                                        Peak Demand MW          Energy sales GWh
                              Capacity MW                          GWh
            2000-01               27,188                              118,441                       20,609             90,366
            2001-02               28,944                              127,169                       21,853             97,171
            2002-03               31,517                              137,814                       23,494            105,077
            2003-04               34,328                              149676                        26,216            114,624
            2004-05               37,300                              162,871                       27,600            124,468
            2005-06               41,003                              178,072                       30,754            132,897
            2006-07               45,288                              192,535                       32,977            144,598
            2007-08               48,413                              203,983                       34,581            152,853
        Compound Annual
         Growth Rate (%)          8.6                       8.1                     7.6                                 7.8
                                Source: System statistics available at www.tavanir.org.ir


According to an Iranian Ministry of Energy presentation made in February 2008, peak demand
of the system was forecast to grow from 37,053 MW in FY 2007-08 to 88,166 MW by FY 2020-
21, initially at 8 - 9% per year and later tapering off to 5% as can be seen in Exhibit 5. To meet
the forecast demand the Ministry’s plan was to raise the total installed generation cap acity to
about 125,000 MW to 130,000 MW by FY 2020-21.
                                      Exhibit 5: Peak Demand Forecast
                    Year                 Peak Demand (MW)                                   Annual Growth Rate ( % )
             2007-08                           37053                                                  -
             2008-09                           40189                                                  8
             2009-10                           43762                                                  9
             2010-11                           47501                                                  9
             2011-12                           51484                                                  8
             2012-13                           55797                                                  8
             2013-14                           60500                                                  8
             2014-15                           64843                                                  7

                                                                      192
                    2015-16                               69473                                  7
                    2016-17                               72293                                  4
                    2017-18                               76261                                  5
                    2018-19                               80230                                  5
                    2019-20                               84198                                  5
                    2010-21                               88166                                  5
Source: Presentation by the Ministry of Energy of Iran on February 19, 2008
Available at www.igmc.ir/usrFiles/../ElectricPowerIndustry-iri-feb2008

Earlier in 2004, the Iranian Power Holding Company Tavanir developed a load forecast for the
period FY2005-06 to FY2015-16 taking into account GDP growth forecasts and the efforts to
reduce price subsidies. According to their forecast, energy at the generation level would need to
increase from 175,528 GWh in FY 2005-06 to 400,539 GWh in FY 2015-16 representing an
average annual growth rate of 8.6%. During the same period, peak demand was projected to
grow at a slightly lower growth rate, from 31,494 MW to 69,473 MW. The actual growth during
the first three years suggests that the above forecasts might be optimistic. Financial resource
constraints arising from the very low levels of electricity tariffs which are well below the cost of
supply seems to be slowing capacity additions in the public sector. A much greater degree of
reform would be needed to attract private sector investment. Owing to the slower pace of
capacity additions and other related reasons, the peak demand forecast for FY 2015-16 appears
to have been scaled down by Tanavir to slightly less than 55, 000 MW.
4.2 Supply
At the end of FY 2007-08, total installed generation capacity was 49.4 GW, meeting a system
peak demand of 34.9 GW and annual energy generation of 204 TWh. Iran imported 1.84 TWh of
electricity and exported 2.52 TWh. Domestic electricity sales amounted to 152.9 TWh. The
overall power losses in the system were about 24% (consisting of about 3.9% in auxiliary
consumption of generating stations, about 4.85% in transmission and sub-transmission losses,
and about 17.9% of distribution losses). 95 The system had transmission and sub-transmission
lines (400 kV, 220 kV, 132 kV, 66 kV) exceeding 99,000 circuit km, medium and low voltage
lines exceeding 593,500 km serving over 21.6 million customers, about 82% of whom were
residential consumers. Access to electricity is close to 100%.
The nominal generation capacity at the end of FY 2007-08 was 49,413 MW of which 43,907
MW (or 88.9%) was in the public sector under the control of Ministry of Energy, and the
remaining 5,506 MW was in the private sector in the form of IPPs and captive generating units
of large industries. The type of technology at the end of FY 2007-08 is shown in Exhibit 6 with
84.9 % thermal, 15% hydroelectric and the remaining 0.1% wind. Nearly 63% of the capacity
consists of steam turbines and simple cycle gas turbines which use natural gas.
                                          Exhibit 6: Generation Technology (MW)
            Types of Power Plant units               Units under MOE          Other Units        System Total      Percentage
                                                                                                                      share
      Steam Power stations                                          14,935                 663            15,598          31.6%
      Gas fired Combined Cycle units                                10,479                   0            10,479          21.2%
      Simple Cycle Gas Turbines                                     10,590               4,844            15,434          31.2%
      Diesels                                                          418                   0               418           0.9%
      Subtotal for thermal power units                     36,422                5,507               41,929          84.9%

95
   Auxiliary consumption is a percentage of gross generation, transmission and sub-transmission loss is a percentage of net
generation plus imports and distribution loss (technical +non-technical) is a percentage of the net input into the distribution
system. More than 50% of the distribution companies had higher loss levels than the average of 17.9%. In a few, technical los ses
alone were 38%.



                                                                     193
      Hydropower units                                    7,422                        0             7,422           15.0%
      Wind Power Units                                       63                        0                63            0.1%
      Subtotal for Hydro and wind units          7,485                    0                    7,485             15.1%
      Total for all units                                43,907                 5,507               49,414            100%
Source: www.tavanir.ir


The average available capacity of the public sector generators in FY 2007-08 was about 40,066
MW accounting for ambient temperature variations (which affect the rated capacity of gas
turbine units and combined cycle units) and the drought adversely affecting the hydrology of the
hydropower units.

Total gross electricity generation in FY 2007-08 was 203,983 GWh of which 91.1% was from
thermal power plants, 8.8% from hydropower units and 0.1% from wind power units. Public
sector units under the control of the Ministry of Energy produced 93% of the total output (see
Exhibit 7).

                     Exhibit 7: Energy Generation in FY 2007-08 by Type of Unit (GWh)

           Types of Power Plant units     Units under MOE         Other Units              System Total      Percentage share
    Steam Power stations                               90,900            13,953                   131,832               64.6%
    Simple Cycle Gas Turbines                          26,979
    Gas fired Combined Cycle units                     53,796                     0                53,796                26.4%
    Diesels                                               225                     0                   225                 0.1%
    Subtotal for thermal power units           171,900              13,953                   185,853             91.1%
    Hydropower units                                    17987                     0                17,987                8.8%
    Wind Power Units                                      141                     0                   141                0.1%
    Subtotal for Hydro and wind units           18,128                0                       18,128              8.9%
    Total for all units                              190,028                  13,953              203,983                100%
Source: www.tavanir.ir




                                                          194
In order to meet increasing demand, new generation capacity of 22,204 MW is expected to be
added during FY 2007-08 – FY 2015-16, bringing the total installed capacity in the country to
71,617 MW. The new capacity will consist of 14,380 MW of gas fired combined cycle units,
4,570 MW of hydropower units, 2,614 MW of gas turbine units and 640 MW of steam turbine
units (Exhibit 8). About 55% of the total capacity additions will be in the private sector in the
form of BOT and BOO projects. The remainder will come from public sector.
                                                     Exhibit 8: Generation Expansion Plan (MW)

                                             25000
                    Capacity addition (MW)



                                                                                                              20190     21244   22204
                                             20000                                       15329      17956

                                             15000                           10115

                                             10000
                                                                   5365
                                              5000        2803               4750        5214
                                                          2803     2562                             2627      2234
                                                                                                                        1054    960
                                                0
                                                      2008-09 2009-10 2010-11 2011-12 2012-13 2013-14 2014-15 2015-16

                                                                                         Year
                                                              Annual Capacity Addition          Cumulative Capacity Addition




In FY 2007-08, privately owned power generating plants accounted for 11% of the total
generating capacity in the country. This included captive generation units owned by large
industrial companies that supply their surplus energy to the grid. These private units, however,
had only a share of 6.8% of the total annual generation of electricity. Most of the privately
owned IPPs had long term energy conversion agreements with Tavanir and sold their outputs to
the power pool through Tavanir. Capacity addition plans through FY 2015-16 envisage that out
of a total of 22,204 MW of new capacity, 12,312 MW (or 55.5%) would be private sector units
with energy conversion agreements with Tavanir. These are considered “confirmed” power
plants. About 62% of the capacity will be in the form of BOO units and the rest will be BOT
units. More than 7,200 MW of the new private sector capacity were under construction and the
rest were negotiating their ECAs.
In addition the Government plans to privatize about 7,500 MW of gas turbine units, so that the
buyers could make the necessary investments to convert them into combined cycle units. For this
purpose the government is planning to provide to the winning bidders five year loans to help
them meet the non-equity part of the acquisition costs and part of new investment costs. Private
sector management contractors appear to be operating the generating units of the RECs. The
government also plans to privatize the distribution companies eventually.
The fuel consumption by the thermal power plants in FY 2007-08 amounted to 36.98 bcm of gas,
8,435 million liters of heavy fuel oil and 4,557 million liters of diesel oil with a total heating
value of 446,059 billion kcal.
4.3 Trade
Iran has numerous international interconnections to the power systems of Armenia, Azerbaijan,
Turkey, Turkmenistan, Afghanistan, Pakistan and Iraq. Details of the existing interconnections
and the type of trade taking place are provided in Exhibit 9.


                                                                                 195
                            Exhibit 9: Details of Existing Interconnections and Trade
     Country                    Number of Tie-        Voltage level/s            Type of trade                           Capacity
                                lines
    Armenia                             2                     230 kV                  Balanced Energy exchange              300 MW
    Azerbaijan                         3+                230/132/20/11 kV                      Transit                      250 MW
    Turkey                              2                     154 kV                           Transit                      250 MW
    Turkmenistan                        3                     230 kV                      Import & Transit                  300 MW
    Afghanistan                         2                   132/20 kV                          Export                        40 MW
    Pakistan                           1+                   132/20 kV                          Export                        40 MW
    Iraq                               2+                   132/63 kV                          Export                       150 MW
 Source: Presentation by the Iranian Ministry of Energy on Feb 19, 2008 available at www.igmc.ir/usrFiles/.../ ElectricPowerIndustry-IRI-Feb-
                                                                  2008.ppt -


In spite of the large number of international interconnections, trade plays a relatively minor role
in the Iranian power sector. The total volume of trade in FY 2007-08 was 4.36 TWh representing
about 2.1% of the total generation in the country. The country was a small net exporter with a net
export volume of 678 GWh (see Exhibit 10).
                 Exhibit 10: Volumes of Exports and Imports during FY 2007-08 (GWh)
   Item             Nakhjavan      Turkey      Armenia     Azerbaijan     Turkmenistan      Pakistan     Afghanistan      Iraq      Total
   Exports to            75         608          361            0               4             181            206           1085     2520
   Import from           56          0           310           298            1178             0              0             0       1842
   Net Trade             19         608           51          -298           -1174            181            206           1085      678
Source: www.tavanir.org.ir


     5. Tariffs
The overall average end-user electricity tariff was 164.98 Rials/kWh (1.8 US cents/kWh) in FY
2007-08. Agricultural consumers had the lowest tariff at 0.23 US cents/kWh followed by
households at 1.36 US cents/kWh, public facilities at 1.74 US cents/kWh, industry at 2.25 US
cents/kWh and commercial consumers at 5.55 US cents/kWh.96
Tavanir estimates the total average cost of supply at 310 Rial/kWh or 3.39 US cents/kWh. 97 Thus
all consumers with the possible exception of the commercial consumers are subsidized. The cost
of supply had been calculated on the basis of highly subsidized fuel prices. 98 Adjusting for this
and other subsidies to the sector the “full average cost of supply” in FY 2006 -07 has been
estimated at 749 Rials/kWh (8.1 US cents/kWh). 99 At such low tariff levels supply entities are
unable to generate the internal resources needed for system expansion to cope with increasing
demand. Tariff structures allow for time-of-use and seasonal demand variation considerations.
However, they do not reflect the cost of supply at different voltage levels, and are very comple x
covering a wide range of consumer categories.
Considering Iran’s tariffs from an international perspective, a February 2009 World Bank report
shows that a residential customer in Iran (Tehran) consuming 700 kWh per month pays only

96
   Based on data found at www.tavanir.gov.ir and using the exchange rate of 9158 Rials to a US dollar as at the end of FY 2007 -
08
97
   About 53% of this was attributed by T avanir to generation costs, 21% to transmission costs and 26% to distribution costs
98
   Fuel prices for the power sector, even after substantial revision in 2007, remained low. Natural gas at about US$ 2/million
BT U was less than a third of the prices prevailing in North American and European markets. T he consumers were insulated from
the impact of the fuel price increases which fell on the state budget. T he government estimated the subsidies to the power
consumers to be of the order of US$ 9.3 billion in 2007 (FACT s Global)
99
   Islamic Republic of Iran Power Sector Report, June 2009, World Bank. T he full cost of supply in 2007 -08 is believed to be
about 773 Rials/kWh or 8.44 US cents/kWh.



                                                                    196
35% of a benchmark tariff based on an average of the tariffs of France, Greece, Italy, Spain,
Portugal and Turkey. These countries were chosen as the benchmark because their tariffs reflect
the cost of supply, and as such, provide a reasonable approximation of the opportunity cost of
electricity. Iran’s tariffs are even below the average tariff paid by other countries in the Middle
East and Africa (MENA). A residential customer in Iran consuming 700 kWh per month pays
only 90% of the MENA average. Iran’s retail tariff for its industrial customers is likewise far
below the benchmark, and even well-below the MENA average.
       6. Prospects for Trade
Several new interconnections are either under construction or in the planning and negotiations
stage. They are summarized in Exhibit 11. Interconnections with Russia (presumably via
Azerbaijan), Tajikistan via Afghanistan, United Arab Emirates via submarine HVDC link, and
Turkey via an HVDC link are under active discussion and study.
             Exhibit 11: Electricity Interconnections under Construction or in the Planning Stages
       Country                Number of Tie-         Voltage level/s                Type of trade                        Capacity
                                    lines
     Armenia                          1                 400 kV                       Barter-ECA                        300-600 MW
     Azerbaijan                       1                 400 kV                     Inter-state trade                    Under study
     Russia                          NA            Under Negotiation         Transit or Inter-state trades          Under negotiation
     Turkey                           1                 400 kV                          Export                         250-650 MW
     Turkmenistan                     1                 400 kV                   Import and Transit               300 MW + 500 MW
     Tajikistan                      Via                400 kV
                                Afghanistan                                   SWAP (ECO initiative)                     1000 MW
     Pakistan                   Under study             400 kV
     Pakistan                         1                 230 kV                          Export                           120 MW
     Iraq                         Up to 9          400 /230/132 kV                      Export                           900 MW
Source: Presentation by the Iranian Ministry of Energy on Feb 19, 2008 available at: www.igmc.ir/usrFiles/.../ ElectricPowerIndustry-IRI-Feb-
2008.ppt -


The 180 km submarine HVDC link between Iran and UAE will have a transfer capa city of 1,500
MW and will connect Iran to the Gulf Cooperation Council (GCC) Grid. The interconnection
among the power systems of these six countries is being coordinated by the GCC Interconnection
Authority. Iran’s HVDC link to this grid has significant implications to its export prospects.
Similarly Iran’s interconnections to Turkey and Iraq will connect it to the evolving regional grid
among Egypt, Libya, Jordan, Iraq, Syria, Lebanon, Palestine and Turkey (EIJLLPST). 100
Interconnection from Iran to the 230 kV line from Tajikistan to Afghanistan would enable Iran to
export winter power to Tajikistan.
Iran is well-endowed with energy resources and has aggressive plans to expand international
trade. However, implementing these plans poses numerous challenges for Iran, including:
           There is an urgent need for tariff reform, both in terms of tariff levels and structure, to
            reflect the cost to supply the various classes of consumers (reduce cross-subsidies) and to
            simplify tariff categories and reflect supply voltage levels.
           The subsidies on primary fuel used for power generation needs to be eliminated by
            raising prices to the full economic cost of supply. This will promote greater generation
            efficiency and optimize investment costs.

100
      H.Shakouri et ale, Economically optimized electricity trade modeling: Iran -T urkey Case, Energy Policy 37 (2009) pp 472-483



                                                                     197
      More rapid and comprehensive reform of the power sector is necessary to foster
       commercialization of the supply entities and promote improved efficiency of operation
       through elimination of cross subsidization between entities.
      More realistic price caps and capacity payments are necessary to generate funds for
       power supply entities to invest.
      Competition in the electricity market will be improved with transmission network
       expansion to remove bottlenecks, and by making third party transmission access a
       practical proposition.
      ECA contracts should be abandoned obliging generating entities to assume fuel supply
       and market risks.
Iran’s substantial gas reserves and its location give it a comparative advantage for electricity
exports to Turkey and possibly the European Union via Turkey. Iran will also be a key transit
country for electricity exports from Turkmenistan to Turkey and beyond. To achieve its export
and transit ambitions, Iran will have to invest in domestic transmission system improvements and
will have to improve the investment climate including sector marketing arrangements and
transmission access. International sanctions and Iran’s domestic policy and organizational
complexity are not conducive to attracting the foreign investment needed to increase electricity
and gas production.




                                              198
Attachment 2.F: Nile Basin Initiative
      1. Overview
The Nile Basin Initiative (NBI) was established in 1999 between nine Nile riparian countries
namely Burundi, Congo, Egypt, Ethiopia, Kenya, Rwanda, Sudan, Tanzania and Uganda,101 with
the mandate and shared vision to “achieve sustainable
socio-economic development through the equitable                      Shared Vision
utilization of, and benefit from, the common Nile Basin
water resources.” The NBI is chaired by a Council of               Shared
Water Ministers (Nile-COM) from each of these countries            Vision
and advised by a Technical Advisory Committee (Nile-
                                                                  Program     Subsidiary
TAC). The NBI aims to build integrated regional programs
in seven thematic areas through the Shared Vision                                Action
Program. One of the thematic projects pursued is to create                     Program
a platform for cross-border electricity trade among the Nile
riparian countries through a Regional Power Trade Project         Action on the Ground
(RPTP). The implementation arm of NBI’s vision is carried
out by the Subsidiary Action Program which comprises: (i) Source: http://www.nilebasin.org/
the Eastern Nile Subsidiary Action Program (ENSAP) 102;
and (ii) the Nile Equatorial Lakes Subsidiary Action Program (NELSAP). 103
      2. Regional Power Trade Project (RPTP)
The RPTP aims to establish a basin-wide framework for low-cost electricity trade that once
implemented will create an enabling environment for regional investments in NBI countries.
Initially, the RPTP is focused on providing technical assistance to foster compatible policy and
regulatory frameworks, common technical operating standards, access rules and cross-border
trade principles, among others. Once the regional regulations and relevant institutions are in
place, the RPTP will focus on infrastructure development, specifically regional electricity
investments and cross-border interconnections.
Thus far, the RPTP has successfully created a Nile Basin Power Forum for technical integration
where national power experts from riparian countries can exchange ideas on how to develop
power supply facilities and ways to expand power trade in the Nile Basin. The creation of this
forum was strategically designed to allow for a participatory process among the riparian
countries and to enhance understanding of the common benefits that can be attained.
Furthermore, a number of studies have been completed including an Environmental Impact
Assessment, a Power Trade Study, and a preliminary Basin Wide Study.
      3. Legal and Regulatory Framework
A trade treaty that has to be signed by the riparian countries will outline the principles of trade
that have to be implemented between NBI countries. The treaty will also create regional
institutions and establish their roles among other key elements. A study entitled ‘Institutional,

101
    Although Eretria is a Nile riparian country, it is not an active participant in the NBI
102
    Investment program for Egypt, Ethiopia and Sudan
103
     Investment program for Burundi, Democratic Republic of Congo, Kenya, Rwanda, T anzania and Uganda—as well as the
downstream riparians Egypt and Sudan



                                                        199
Regulatory and Cooperative Framework Model for the Nile Basin Power Trade’ completed in
December 2007 proposes a phased approach to the roll-out of NBI regional trade (see Exhibit 1).
Bilateral cross-border trading is only envisaged to commence once the implementation of Phase-
I is completed. Under Phase-II, an important feature is the approval of a regional regulatory
framework by all NBI countries which will govern cross-border electricity trade. Due to the
significant disparity in the regulatory environments and power sector structures among the Nile
riparian countries and in order to facilitate power trade, it is envisioned that the regional
regulatory framework established will only apply to cross border trading, i.e. from one country’s
interconnection point to that of its trading partner, without impacting or modifying the divergent
national regulatory frameworks. 104 Moreover, regional regulation will only apply to permanent
or frequent transactions where standardization may be necessary and where common interests
and benefits of NBI members are involved. Therefore, bilateral trade decisions that do not
involve all member countries are left to negotiations between the countries involved.
                  Exhibit 1: Phased Roll-Out of Regional Regulation and Integration




  Phase-I: Preparation                        Phase-II: Bilateral Cross                 Phase-III: Multi-Party
  • Sign Power Trade Treaty                   Border Trading                            Transactions and
  • Set-up Phase-I institutions               • Approve regional power trade            Transits
                                                regulations (constrained to
  • Unify technical standards                                                           • Expand regional power trade
                                                bilateral trade only, not individual      regulations to ease restrictions on
  • Promote information sharing                 agents)
                                                                                          individual agent power trade
    among countries                           • Set-up procedures, databases,           • Expand regulation to allow for
  • Create regional database for                tools and human capital to
                                                                                          power transit through third
    studies, consultancies and                  develop regional system                   countries
    procedures for implementation               expansion plans and identification
                                                of core regional investmetns            • Centralized the identification and
  • Prepare country report son                                                            decision making process of
    national regulatory framework             • Prepare for establishment of
                                                                                          regional investment opportunities
    and impediments to regional                 Regional Regulator and Regional
    integration                                 System/Market Operator                  • Establish Regional Regulator

  • Agree on dispute resolution                                                         • Establish Regional System/
    mechanisms                                                                            Market Operator




       4. Institutions
The aforementioned study recognizes the need to set up new regional institutions to manage,
monitor and regulate cross-border electricity trade. Upon treaty signature, and as mentioned
above, the study proposes a phased approach to institutional establishment in order to allow for
the market to evolve in a sustainable manner. Exhibit 2 describes the institutions to be
established and their respective roles.


104
      Deep reforms and uniform national regulations were proposed, but not considered



                                                              200
                                       Exhibit 2: Institutions and their Functions
                                                Phase-I                              Phase-II                        Phase-III
Nile Basin Initiative Council of   Existing as the highest level of      Coordinate with NBI Power Trade Council of Ministers (PT -COM)
Ministers (Nile-COM)               authority in NBI                      only in those issues where water intervenes
                                   Gives final clearance to
                                   Electricity Ministers to Treaty
                                   according to NBI procedures
Power Trade Council of             Created through Treaty signed in       Performs activities established in the Treaty including guidance on
Ministers (PT-COM)                 Phase-I                                power trade development, approval of strategic action plan and
                                                                          approval of rules, regulations and agreements submitted by the
                                                                          Secretariat
Steering Committee (SC)            Created through Treaty signed in       Performs activities established in the Treaty including oversight over
                                   Phase-I                                power trade development, oversights over Power Trade Secretariat
                                                                          (PTS) activities, reviews PTS products issued for PT -COM final
                                                                          approval and communication channel between PT -COM and PTS
Power Trade Secretariat (PTS)      Created through Treaty signed in       Performs activities established in the Treaty including implementation
                                   Phase-I                                of PT-COM issued policies, creates or eliminates working groups
                                                                          (WG) with TORs, supervises and coordinates activities of WGs,
                                                                          submits WGs recommendations to PT -COM through SC, submits
                                                                          rules, regulations, agreements to the PT -COM for approval, prepares
                                                                          3-year action plan for SC and PT -COM approval, prepares
                                                                          implementation of Regional Regulator and Regional System Operator
                                                                          and establishes coordination mechanism with other institutions.
NELSAP                             Participates in regional planning activities as coordinated by PTS in Phases I and II and by Regional System
                                   Market Operator in Phase-III
ENSAP                              Participates in regional planning activities as coordinated by PTS in Phases I and II and by Regional System
                                   Market Operator in Phase-III
Regional System/Market                                                    Created at the end of Phase-II as      Leads and coordinates regional
Operator                                                                  required to begin in Phase-III         planning.

                                                                                                             Performs the function of
                                                                                                             Regional System/Market
                                                                                                             Operator
Regional Regulator                                                       Created at the end of Phase-II as   Enforces regional regulation,
                                                                         required to begin in Phase-III      develops rules and regulations to
                                                                                                             be presented to PT -COM for
                                                                                                             approval and participates in
                                                                                                             dispute resolution as established
                                                                                                             by Treaty
Regional Court of Justice          Already exists in international regional institutions                     Provides its Court of Justice as
                                                                                                             forum for dispute resolution

     5. NBI Generation Development and Cross Border Interconnections
Through the implementation arm of the NBI namely the Subsidiary Action Program, two
electricity projects are currently under development:
     (i)        The NELSAP Regional Rusumo Falls Hydro-electric and Multipurpose Project which
                aims to generate 60 to 80 MW of electricity to support the development of Burundi,
                Rwanda and Western Tanzania at an estimated cost of US$250 million. Currently,
                US$4 million from the NBI Trust Fund and other donors has been allocated for
                project preparation. Project implementation is expected to commence in early 2012;
                and
     (ii)       The ENSAP Ethiopia Power Export Project (formerly Ethiopia-Sudan Transmission
                Interconnection Project) aims to facilitate, through 230/220 kV transmission lines,
                cross-border power trade between Ethiopia and Sudan. The project which was
                recently completed was financed by the International Development Association for
                US$41 million on the Ethiopian side and by the Sudanese Government for the Sudan
                interconnection for about US$ 25 million.


                                                                      201
      6. Trade Opportunities among Nile Riparian and Arab Countries
A number of NBI member countries are pursuing independent generation development and
interconnection opportunities (see Exhibit 3). Some of those in closer proximity to the Arab
world are discussed below.
6.1 Ethiopia
Generation: Ethiopia recently commissioned three hydropower plants: Gilgel Gibe II generating
420 MW, Tekeze Hydroelectric Project generating 300 MW and Tana Beles Multi-purpose
Hydro-electric Power Project generating 460 MW. Moreover Ethiopia has launched the
construction of the Amerti Neshi Gibe III and Finchaa hydropower projects with a combined
generating capacity of over 2200 MW. Other projects in the pipeline include the 254 MW Genale
Dawa 3 hydropower project and other hydro and wind projects expected to generate an
additional 500 MW.105
Transmission: Ethiopia and Djibouti received a loan from the African Development Bank to
finance the construction of interconnecting transmission lines (283 km of 220 kV; 84.5 km of 63
kV; and 3.2 km of 33kV lines). Moreover, the Ethiopia Electric Power Corporation also plans to
invest in additional interconnections with Kenya and at a later stage, Egypt, Tanzania, Somalia
and Yemen.
6.2 Sudan
Generation: Sudan has a highly-constrained electricity supply system. At the end of 2008, Sudan
had a total installed generation capacity of 1,235 MW of which 343 MW was hydroelectric.
Some new generation capacity has been commissioned: the Merowe Hydropower project 106 on
the Nile River with a generation capacity of 1,250 MW and the Al-Fula Thermal Power Station
(oil-fired) with about 400 MW generating capacity. By the end of March 2010, the total installed
capacity is estimated to have increased to over 2,890 MW. Moreover, a number of projects are in
an advanced stage of construction/commissioning: (i) the 300 MW Kajbar Hydropower project
close to the northern border of Sudan, (ii) Kosti steam power plant (about 500 MW) using crude
oil as fuel; (iii) Garri 4 power plant (110 MW) using sponge coke and LDO as fuel; (iv)
Khartoum North (phase III) Steam Power Station 200 MW using Bunker C oil as fuel; (v) a 500
MW coal fired thermal power project at Port Sudan107 using coal imported from South Africa,108
and (vi) a number of diesel power generators at several locations.
Transmission: At the end of 2009, the Sudanese power system had 966 circuit km of 500 kV
lines, 4,983 circuit km of 220 kV lines and 1,350 circuit km of 110 kV and 66kV lines. The
substation capacity was 1,500 MVA (at the 500 kV level), 5,027 MVA (at the 220 kV level),
2,261 MVA (at the 110 kV and 66 kV level). As part of the Merowe project, about 1,745 km of
500 kV and 220 kV transmission lines as well as 7 substations were also added. Sudan‐Eritrea,
and Sudan‐Uganda interconnections are planned and will link the Eastern African grid to the
Northern African grid.

105
    See Ethiopian News at http://www.ethiopian-news.com/power-export-to-sudan-starts-in-october/.
106
    T his is a major multipurpose project also providing irrigation facilities to about 400,000 ha of land in North Sudan. See
Startup at Merowe: A major boost for the Socioeconomic development of Sudan, in Hydropower and Dams, Issue 3, 2009 pp
115-120
107
    T his may also have a configuration of 2 x 300 MW
108
    See news item at http://us-cdn.creamermedia.co.za/assets/articles/attachments/22474_namane.pdf



                                                            202
             Attachment 3.A
   Summary of EU Legislation on Internal
 Market and Cross-Border Electricity Trade                                                                      109




Introduction
This document presents an overview of the key EU legislation related to electricity issues in the following
areas: internal energy market, security of supply, external dimension, enlargement, and renewable energy.
This document is not intended to be a comprehensive list of all EU acts in this sector, but a user-friendly
tool of the main legislation driving the EU internal market in electricity.
The summaries of the legislation contained in this document have been compiled from EU sources 110 . An
introduction to the different types of EU legislation and a brief overview of the construction of the
internal energy market are included to facilitate the reading of the five sections: a competitive internal
market, an interconnected EU internal market, taxation, security of supply, external dimension, EU
enlargement, and renewable energy.




109
      All legislation can be found in the “EU Directive” folder: P: \!UNIT S\MNSSD\Arab League-WBStudy_Energy
110
      http://europa.eu/legislation_summaries/energy/index_en.htm



                                                            203
                                                      Table of Contents
Introduction 203
Table of Contents               204
Basics of EU legislation 205
Milestones in the construction of the EU internal energy market 205
I.        A competitive internal market 206
    1. Regulation 713/2009 establishing an Agency for the Cooperation of Energy Regulators .......... 206
    2. Directive 2003/54 concerning common rules for the internal market in electricity................... 207
    3.      Directive 2009/72 concerning common rules for the internal market in electricity and repealing
    Directive 2003/54 as from March 3 2011 ................................................................................ 208
    4. Communication COM(2006) 841 “Prospects for the internal gas and electricity market” of 10
    January 2007 ...................................................................................................................... 210
    5. Council Directive 90/377 of 29 June 1990 concerning the transparency of gas and electricity
    prices charged to industrial end-users ..................................................................................... 212
    6. Directive 2003/87 establishing a scheme of greenhouse gas emission allowance trading .......... 213
II.       An interconnected EU internal market 214
    7. Green paper – towards a secure, sustainable, and competitive European energy network......... 214
    8. Decision 1364/2006 laying down guidelines for trans-European energy networks ................... 215
    9. Communication COM(2006) 846 on Priority Interconnection Plan ...................................... 217
    10.     Regulation 1228/2003 on conditions for access to the network for cross-border exchanges in
    electricity ........................................................................................................................... 217
    11.     Regulation 714/2009 of 13 July 2009 on conditions for access to the network for cross- border
    exchanges in electricity and repealing Regulation 1228/2003 ..................................................... 219
III.      Taxation              220
    12.     Council Directive 2003/96 of 27 October 2003 on taxation of energy products and electricity
            220
IV.       Security of supply                222
    13.     Directive 2005/89 concerning measures to safeguard security of electricity supply and
    infrastructure investment ...................................................................................................... 222
V.        EU External dimension 223
    14.     Council Decision 2006/500 on the conclusion by the European Community of the Energy
    Community Treaty .............................................................................................................. 223
VI.       EU Enlargement – Turkey (ongoing) 225
    15.     Commission Report COM (2008) 674 final – SEC (2008) 2699 –not published in the Official
    Journal225
VII.      Renewable energy                  227
    16.     Directive 2009/28 of 23 April 2009 on the promotion of the use of energy from renewable
    sources227




                                                                     204
Basics of EU legislation
EU institutions adopt three types of laws, directives, regulations and decisions, which take
precedence over national law and are binding on national authorities. The EU also issues non-
binding instruments, such as recommendations and opinions.
1. Directive
EU directives lay down certain end results that must be achieved in every Member State. National
authorities have to adapt their laws to meet these goals, but are free to decide how to do so.
Directives may concern one or more EU countries, or all of them.
Each directive specifies the date by which the national laws must be adapted - giving national
authorities room to maneuver within the deadlines necessary to take account of differing national
situations. Directives are used to bring different national laws into line with each other, and are
particularly common in matters that affect the operation of the single market (e.g. product safety
standards).
2. Regulation
Regulations are the most direct form of EU law - as soon as they are passed, they have binding
legal force throughout every Member State, on a par with national laws. National governments
do not have to take action themselves to implement EU regulations.
They are different from directives, which are addressed to national authorities, who must then
take action to make them part of national law, and decisions, which apply in specific cases only,
involving particular authorities or individuals. Regulations are passed both jointly by the EU
Council and European Parliament, and by the Commission alone.
3. Decision
Decisions are EU laws relating to specific cases. They can come from the EU Council
(sometimes jointly with the European Parliament) or the Commission.
They can require authorities and individuals in Member States either do something or stop doing
something, and can also confer rights on them.
EU decisions are:
       • addressed to specific parties (unlike regulations),
       • fully binding.
Milestones in the construction of the EU internal energy market 111
The first electricity and gas directives were adopted in the late 1990s, with the objective of
opening up the electricity and gas markets by gradually introducing competition.
The Commission has consistently argued that liberalization increases the efficiency of the energy
sector and the competitiveness of the European economy as a whole. But a number of
stakeholders and member states, notably France and Germany, vehemently disagree with this
assessment.


111
      Source: http://www.euractiv.com/en/energy/liberalising-eu-energy-sector/article-145320



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While most member states had implemented the electricity and gas directives by September
2000, a 2001 Commission inquiry concluded that further measures were necessary in order to
complete the internal energy market and to reap its benefits.
The second gas    and      electricity directives, adopted in June 2003, include  'un
bundling', whereby energy transmission networks have to be run independently from the
production and supply side.
According to the directives, markets for all non-household gas and electricity customers are to be
liberalized by July 2004. For private households, the deadline is July 2007. After these dates,
businesses and private customers would theoretically have been able to choose their power and
gas suppliers freely in a competitive marketplace.
But a competition enquiry in the electricity sector, published in January 2007, revealed some
"serious malfunctions" in the market for industrial consumers.
For example, market concentration still reflects the 'old' market structure, characterized by
national or regional monopolies - usually dominated by vertically integrated companies - which
control electricity prices in the wholesale market and block new entrants to the market. In the gas
sector, "incumbents tend to control imports and/or domestic production," according to the
Commission.
Corrective action was promised by the EU executive, which tabled a further package of
proposals in September 2007. After long negotiations, the Parliament and the Czech Presidency
struck a compromise deal on the legislative package on 23 March 2009 (see Directives 2009/72
and 2009/73 below)
I.      A competitive internal market
1.    Regulation 713/2009 establishing an Agency for the Cooperation of Energy
Regulators
SUMMARY
This Regulation establishes the Agency for the Cooperation of Energy Regulators with the aim
of exercising at Community level the tasks performed by the Member States’ regulatory
authorities.
The Agency for the Cooperation of Energy Regulators is a Community body with legal
personality. It shall issue opinions on all questions related to the field of energy regulators. It
shall participate in the creation of network codes in the fields of electricity and gas and it can
make decisions regarding cross-border infrastructure, including derogations from certain
provisions in the applicable regulations.
Tasks
Tasks concerning the cooperation of transmission system operators
The Agency is responsible for issuing an opinion on the draft statutes, the list of members and
the draft rules of procedure of the ENTSO (European Network of Transmission System
Operators) for electricity and gas, and for monitoring the execution of the tasks. The Agency
shall play an important role in drafting the framework guidelines which the network codes must
comply with. In addition, the Agency shall monitor regional cooperation between transmission


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system operators in the electricity and gas sectors, and the execution of tasks by the ENTSO for
electricity and gas.
Tasks concerning national regulatory authorities
The Agency is responsible for adopting, under certain conditions, individual decisions on
technical issues. It may make recommendations with the aim of promoting the exchange of good
practice between regulatory authorities and market players. It shall also provide a framework for
cooperation between the national regulatory authorities.
The Agency may issue an opinion on whether a decision taken by a regulatory authority
complies with the applicable Community rules. If its opinion is not followed, the Agency shall
inform the European Commission and the Member State concerned.
The Agency is also responsible for determining, under certain conditions, the terms and
conditions for access to and operational security of electricity and gas infrastructure, which
connects at least two Member States.
Tasks concerning cross-border infrastructure
The terms and conditions for access applicable to cross-border infrastructure include:
     -   a procedure for capacity allocation;
     -   a time-frame for allocation;
     -   shared congestion revenues;
     -   the levying of charges on the users of the infrastructure.
The Agency is responsible for the terms and conditions for access and security only when the
national regulatory authorities have not been able to reach an agreement within a period of six
months or they have jointly requested it.
The Agency is responsible for monitoring the internal markets in electricity and natural gas, in
particular the retail prices of electricity and natural gas.
To facilitate the consultation of Member States’ regulatory bodies, Commission Decision
2003/796/EC has established an independent consultation group for the electricity and gas
sectors (European Regulatory Group for Electricity and Gas or ERGEG). Although the results of
its work are positive, it became apparent that Member States need to cooperate under a
Community structure in order to strengthen the internal market in gas and electricity.
2.       Directive 2003/54 concerning common rules for the internal market in electricity
SUMMARY
This Directive establishes common rules for the generation, transmission and distribution of
electricity. It lays down the rules relating to the organization and functioning of the electricity
sector, access to the market, the criteria and procedures applicable to calls for tenders and the
granting of authorizations and the operation of systems.
Public service obligations and customer protection




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Electricity undertakings must be operated in accordance with commercial principles, with no
discrimination between undertakings as regards either rights or obligations. The objective is to
achieve a competitive, secure and environmentally sustainable market in electricity.
Member States must:
       impose on undertakings operating in the electricity sector public service obligations
which may relate to security, including security of supply, regularity, quality and price of
supplies and environmental protection, including energy efficiency and climate protection;
      ensure that all household customers and small enterprises, at least, enjoy the right to be
       supplied with electricity of a specified quality within their territory at reasonable, easily
       and clearly comparable and transparent prices;
      take appropriate measures to protect end-users and vulnerable customers, including
       measures to help them avoid disconnection;
      ensure the implementation of a system of third party access to the transmission and
       distribution systems for all eligible customers;
      inform the Commission upon implementation of this Directive.
      providing the operator of any other system to which its system is interconnected with
       sufficient information to ensure secure and efficient operation;
      ensuring non-discrimination between system users;
      providing system users with the information they need for efficient access to the system.
3.    Directive 2009/72 concerning common rules for the internal market in electricity
and repealing Directive 2003/54 as from March 3 2011
SUMMARY
This Directive aims at introducing common rules for the generation, transmission, distribution
and supply of electricity. It also lays down universal service obligations and consumer rights, and
clarifies competition requirements.
Rules for the organization of the sector
The rules for the organization of the sector are aimed at developing a competitive, secure and
environmentally sustainable market in electricity.
Member States may impose on undertakings operating in the electricity sector public service
obligations which cover issues of security and security of supply, regularity and quality of
service, price, environmental protection and energy efficiency.
Member States shall ensure that all customers have the right to choose their electricity supplier
and to change supplier easily, with the operator’s assistance, within three weeks. They shall also
ensure that customers receive relevant consumption data.
Electricity suppliers are obliged to inform final customers about:
     the contribution of each energy source;
     the environmental impact caused;
     their rights in the event of a dispute.

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Member States shall put in place an independent mechanism (energy ombudsman or consumer
body) to manage complaints or disputes efficiently.
Member States are also obliged to ensure the monitoring of security of supply. They shall define
technical safety criteria to ensure the integration of their national markets at one or more regional
levels. In addition, the national regulatory authorities are to cooperate with the Agency for the
Cooperation of Energy Regulators to guarantee the compatibility of regulatory frameworks
between regions.
Generation
Member States shall define criteria for the construction of generating capacity in their territory
taking account of aspects such as:
      the security and safety of electricity networks;
      the protection of health and public safety;
      the contribution made towards the Commission’s “20-20-20” objectives.
Transmission system operation
From 3 March 2012, Member States must unbundle transmission systems and transmission
system operators.
An undertaking must first be certified before being officially designated as a transmission system
operator. A list of transmission system operators designated by Member States shall then be
published in the Official Journal of the European Union.
Transmission system operators are mainly responsible for:
      ensuring the long-term ability of the system to meet demands for electricity;
      ensuring adequate means to meet service obligations;
      contributing to security of supply;
      managing electricity flows on the system;
      providing to the operator of any other system information related to the operation,
       development and interoperability of the interconnected system;
      ensuring non-discrimination between system users;
      providing system users with the information they need to access the system;
      collecting congestion rents and payments under the inter-transmission system operator
       compensation mechanism.
Distribution network operation
Member States shall designate distribution system operators or require undertakings that own or
are responsible for distribution systems to do so.
Distribution system operators are mainly responsible for:
      ensuring long-term capacity of the system in terms of the distribution of electricity,
       operation, maintenance, development and environmental protection;


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      ensuring transparency with respect to system users;
      providing system users with information;
      covering energy losses and maintaining reserve electricity capacity.
Organization of access to the system
Member States shall organize a system of third party access to transmission and distribution
systems. The tariffs based on that system shall be published.
Member States shall also lay down criteria for the granting of authorizations to construct direct
lines in their territory, on an objective and non-discriminatory basis.
National regulatory authorities
Member States shall designate a regulatory authority at national level. It shall be independent
and exercise its powers impartially. It is mainly responsible for:
      fixing transmission or distribution tariffs;
      cooperating in regard to cross-border issues;
      monitoring investment plans of the transmission system operators;
      ensuring access to customer consumption data.
Context
The Communications entitled ‘Prospects for the internal gas and electricity market’ and ‘Sector
inquiry into the gas and electricity markets’ emphasized the inadequate framing of the rules and
measures in force relating to the internal electricity market. The Commission deemed it
important to amend the current rules with a view to ensuring fair competition and supplying
electricity at the lowest possible price in order to complete the internal market in energy.
4.     Communication COM(2006) 841 “Prospects for the internal gas and electricity
       market” of 10 January 2007
SUMMARY
The aim of the European Union (EU) is to set up a truly competitive internal market for gas and
electricity to offer consumers a real freedom of choice at fair, competitive prices, to stimulate
clean energy production and to improve security of supply.
Although the internal energy market is well established, malfunctioning (identified by the sector
inquiry into the gas and electricity markets) persists, preventing both consumers and the
economy from getting the full benefit of the advantages of opening up the national gas and
electricity markets.
As current rules do not allow effective correction of this malfunctioning, new measures must be
taken as the final step in achieving integrated operation of the internal energy market in Europe.
Advantages of creating the internal energy market
The opening of national markets in gas and electricity to competition visibly gives consumers the
freedom to choose their energy supplier and, therefore, the opportunity to make savings. It also
improves the security of supply by encouraging, on the one hand, investment in facilities, so that
interruptions to supply can be prevented, and, on the other hand, diversification of transport

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routes and energy sources. The existence of a truly competitive energy market also contributes to
sustainable development, notably by enabling suppliers of electricity from renewable energy
sources to enter the market.
Continued malfunctioning
In practice, the EU is still a long way from achieving its objective of a real internal market in
which each consumer has the legal right to choose his supplier and exercise this right simply and
effectively armed with the facts, and the current rules do not effectively prevent market
malfunctioning.
The legal and functional unbundling of system operators vertically connected to suppliers and
producers has proven insufficient to guarantee equal access to the networks. The traditional
operators thus maintain their dominant position and new companies wishing to enter the market
encounter many problems caused by discriminatory access conditions, lack of available network
capacity, a lack of transparent data on the network situation and poor investment.
National regulators do not have the powers or independence necessary for succeeding in their
mission. Their powers vary considerably from one Member State to the next, hindering cross-
border trade and access to consumers in other Member States.
New set of rules for completion of the internal energy market
      Provision of non-discriminatory access to the networks through unbundling
Current legal and functional unbundling has proven insufficient in removing the conflict of
interests arising from vertical integration. Clearer separation between operation of transmission
systems and production or supply activities must be introduced to ensure that operators maintain,
operate and develop the networks in the general interest of the network users.
The separation may be based either on complete ownership unbundling, due to transmission
system operators being both operators and owners of the system, or on introduction of an
independent transmission system operator for maintenance, development and operation of the
systems, which remain the property of the vertically integrated companies.
Complete ownership unbundling appears to be the most economically effective way to ensure
development of a real internal energy market. Not only does it eliminate the different interests of
system operators but also avoids the need for excessively detailed and complex regulations
ensuring independence of vertically integrated system operators.
      Strengthening of the role of regulators at national and Community level
The regulatory framework and therefore the powers of the regulators must be strengthened to
ensure the conditions of transparency, stability and non-discrimination necessary for
development of competition and for investment.
Better coordination of national regulators at European level is, in addition, needed to mitigate the
market segmentation resulting from the regulatory differences between Member States. In this
sense, it is possible either to improve the present approach, with the disadvantage of continuing
to rely on voluntary agreements between 27 national regulators often with different interests, or
to formalize the role of the European Regulators Group for Electricity and Gas (ERGEG) into a
European Network of Independent Regulators (ERGEG +), or lastly to set up a new single body
at Community level.

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      Cooperation of transmission system operators (TSOs)
To enable free circulation of gas and electricity within the EU, it is essential to establish
compatible technical rules and regular exchange of information, increase investment in the
network and, in particular, in cross-border interconnections, and move towards regional system
operators.
      Reduction in possibilities for unfair competition
Due to the monopolies held by the traditional operators before liberalization, the lack of
integration and their natural characteristics, in particular low elasticity of demand, the gas and
electricity markets are particularly exposed to the risk of dominant positions.
Greater transparency, recourse to the ‘use -it-or-lose-it’ principle, genuine access to gas storage
facilities and maintenance of incentives in favor of new storage capacities would facilitate the
transition to a more competitive gas and electricity market.
      Encouragement of investment in electricity power plants and gas infrastructures
Creating a stable environment for investment is a priority. Other factors may also influence
investment, such as the award of emission certificates or specific incentive measures, for
example for production of electricity from renewable energy sources.
      Consumer protection
Consumer protection and public service obligations must be an integral part of the process of
opening up the gas and electricity markets. An energy consumers’ charter must therefore protect
their essential rights: the right to relevant information on the different suppliers and supply
possibilities, the right to a straightforward procedure for changing supplier, protection against
energy poverty for the most vulnerable consumers, protection against unfair commercial
practices, etc.
5.     Council Directive 90/377 of 29 June 1990 concerning the transparency of gas and
       electricity prices charged to industrial end-users
SUMMARY
The transparency of energy prices contributes to the creation and smooth operation of the
internal energy market.
The transparency of gas and electricity prices in fact improves the conditions ensuring fair
competition within the market. It can help eliminate discrimination of consumers, by promoting
their freedom to choose between different energy sources (oil, coal, fossil fuels and renewable
energy sources) and between different suppliers.
The Member States make sure that companies supplying gas or electricity to European end-users
send the Statistical Office of the European Communities (Eurostat) information relating to:
      prices and conditions of sale of gas and electricity to these consumers;
      the pricing systems in force;
      breakdown of consumers by category and their respective market share.
Information regarding gas and electricity prices is sent to Eurostat twice a year whereas
information on consumer breakdown by category is only sent every two years.

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The methods adopted by Eurostat guarantee that the confidentiality of the information is not
compromised and that, as a consequence, commercial confidentiality is respected.
For energy price transparency to be truly effective, prices and pricing systems must be published
and broadcast for consumers as widely as possible. Furthermore, the reliability of data sent to
Eurostat can be checked.
6.     Directive 2003/87 establishing a scheme of greenhouse gas emission allowance
trading
SUMMARY
This Directive establishes a Community greenhouse gas emission trading scheme from 1 January
2005. In this context, 'allowance' means the entitlement to emit a tonne of carbon dioxide or an
amount of any other greenhouse gas with an equivalent global warming potential during a
specified period.
Greenhouse gas emission permits
With effect from 1 January 2005, all installations carrying out any of the activities listed in
Annex I to this Directive (activities in the energy sector, iron and steel production and
processing, the mineral industry and the wood pulp, paper and board industry) and emitting the
specific greenhouse gases associated with that activity must be in possession of an appropriate
permit issued by the competent authorities.
Applications for greenhouse gas emission permits must describe:
      the installation, its activities and the technology used;
      the materials used which could emit the greenhouse gases listed in Annex II;
      the sources of gas emissions;
      the measures planned to monitor and report emissions.
The authorities will issue a permit provided that they are satisfied that the operator of the
installation is capable of monitoring and reporting the emissions. A permit may cover one or
more installations on the same site operated by the same operator. The permit will contain details
of:
      the name and address of the operator;
      the installation's activities and emissions;
      the monitoring methodology and frequency;
      the reporting requirements in respect of emissions;
      the obligation to surrender, during the first four months of each year, a quantity of
       allowances commensurate with the total emissions over the previous year.
Management of allowances
Each Member State must draw up a national plan complying with the criteria set out in Annex III
to this Directive, indicating the allowances it intends to allocate for the relevant period and how
it proposes to allocate them to each installation. The plans covering the initial three-year period
specified in the Directive (1 January 2005 to 1 January 2008) had to be published by 31 March

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2004 at the latest, and those relating to the subsequent five-year periods are to be published at
least eighteen months before the beginning of the relevant period. When drawing up the plans,
Member States should take due account of comments from the public. If a plan does not comply
with the criteria in Article 10 of or Annex III to this Directive, the Commission may reject it
within three months of notification.
Under the Directive, at least 95% of the allowances for the initial three-year period were to be
allocated to the installations free of charge. For the five-year period beginning 1 January 2008,
Member States must allocate 90% of the allowances free of charge.
Member States will ensure the free circulation of allowances within the European Community.
Each year, no later than 30 April, they will also make sure that the operators of the installations
surrender the correct quantity of allowances commensurate with the total emissions over the
previous year. The surrendered allowances are subsequently cancelled.
Kyoto Protocol project mechanisms
Directive 2004/101/EC reinforces the link between the EU's emission allowance trading scheme
and the Kyoto Protocol by making the latter's 'project-based' mechanisms (Joint Implementation
and the Clean Development Mechanism) compatible with the scheme. This will enable operators
to use these two mechanisms in the allowance trading scheme to fulfill their obligations. The
result will be lower compliance costs for installations in the scheme. It is estimated that annual
compliance costs in the period 2008-12 for all installations covered in the enlarged EU will be
reduced by more than 20%.
This Directive thus recognizes joint implementation (JI) and clean development mechanism
(CDM) credits as equivalent to EU emission allowances, except for those from land use, land use
change and forestry activities. Credits from JI projects are called 'emission reduction units'
(ERU), while credits from CDM projects are called 'certified emission reductions' (CER). The
Directive also takes steps to prevent ERUs and CERs being counted twice where they result from
activities which also lead to a reduction in, or limitation of, emissions from installations covered
by Directive 2003/87/EC.
II.    An interconnected EU internal market
7.     Green paper – towards a secure, sustainable, and competitive European energy
       network
SUMMARY
Through this Green Paper, the Commission launches a public consultation with a view to
developing a new strategic approach to energy networks which aims to achieve the climate and
energy objectives of the European Union.
Priorities
The main priority is to improve the Community framework with a view to developing the energy
networks of the Member States of the Union and to integrate them better so as to enhance the
operation of the internal energy market.
Energy transportation networks make up the keystone of energy policy. For this reason the
Trans-European Energy Networks (TEN-E) should correspond to the new requirements of
energy policy with regard to sustainability, supply and competitiveness. Adopted in 1996, they

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should be amended so that they correspond to the objectives set out in the 2007 Energy Policy
for Europe.
The external dimension is also a significant issue for the development of energy networks. The
internal energy market depends strongly on imports. New import routes will need to be
integrated into the network from:
      Central Asia;
      the Caspian Sea;
      the Middle East;
      Africa.
The coordination and management of the networks will be carried out by the future Agency for
the Cooperation of Energy Regulators, and by two European Networks of Transmission System
Operators. The infrastructure plans will be implemented for a duration of ten years.
There is also an urgent need (in addition to the investments necessary to modernize energy
networks and to replace obsolete infrastructures) at European level, for new projects that allow
all Member States to be integrated in the internal market and also integrate new technologies.
New energy resources must therefore be developed and be accessible across the best
interregional connections.
A new approach to energy network development
Energy network development should become a central issue when implementing energy policy.
The 20-20-20 objectives should be implemented effectively through programs relating to both
the public and private sectors. These objectives consist of:
      the integration of renewable energy sources in the network;
      the transport of energy from resource-rich areas to consumption centers;
      the use of technologies for the decentralization of energy production and intelligent
       networks;
      the use of energy coming from offshore wind farms;
      the development of technologies for the transport and storage of CO 2.
8.     Decision 1364/2006 laying down guidelines for trans-European energy networks
SUMMARY
The new guidelines for trans-European energy networks (TEN-E) list and rank, according to the
objectives and priorities laid down, projects eligible for Community assistance. They also
introduce the concept of 'project of European interest'.
Defining the objectives of the TEN-E
The interconnection, interoperability and development of trans-European networks for
transporting electricity and gas are essential for the effective operation of the internal energy
market in particular and the internal market in general. Users should have access to higher-
quality services and a wider choice as a result of the diversification of energy sources, at more
competitive prices. Closer links should therefore be established between national markets and the

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EU as a whole. With that in mind, the new Member States are now fully incorporated into the
Community TEN-E guidelines.
TEN-E also play a crucial role in ensuring the security and diversification of supply.
Interoperability with the energy networks of third countries (accession and candidate countries
and other countries in Europe, in the Mediterranean, Black Sea and Caspian Sea basins, and in
the Middle East and Gulf regions) is essential.
Access to TEN-E also helps to reduce the isolation of the less-favored, island, landlocked or
remote regions, thus strengthening territorial cohesion in the European Union (EU).
The interconnection of TEN-E also promotes sustainable development, in particular by
improving the links between renewable energy production installations and using more efficient
technologies, thus reducing losses and the environmental risks associated with the transportation
and transmission of energy.
Projects of common interest, priority projects and projects of European interest
Decision 1364/2006/EC lists projects eligible for Community assistance under Regulation (EC)
No 2236/95 and ranks them in three categories.
Projects of common interest relate to the electricity and gas networks referred to in the
Decision meeting the objectives and priorities laid down in it. They must display potential
economic viability. The economic viability of a project is assessed by means of a cost-benefit
analysis in terms of the environment, the security of supply and territorial cohesion. Projects of
common interest are listed in Annexes II and III to the Decision.
Priority projects are selected from among the projects of common interest. To be eligible, they
must have a significant impact on the proper functioning of the internal market, on the security
of supply and/or the use of renewable energy sources. Priority projects, which are listed in
Annex I to the Decision, have priority for the granting of Community financial assistance.
Certain priority projects of a cross-border nature or which have a significant impact on cross-
border transmission capacity are declared to be projects of European interest . Also listed in
Annex I, projects of European interest have priority for the granting of Community funding
under the TEN-E budget and particular attention is given to their funding under other
Community budgets.
A favorable framework for the development of TEN-E
The Community guidelines for TEN-E stress the importance of facilitating and speeding up the
completion of projects, in particular projects of European interest.
The Member States must take all measures necessary to minimize delays while complying with
environmental rules. The authorization procedures must be completed rapidly. The third
countries involved must also facilitate the completion of projects partly situated on their territory
in accordance with the Energy Charter Treaty.
The new guidelines also establish a framework for closer cooperation, in particular for projects
of European interest. They provide for an exchange of information and the organization of
coordination meetings between the Member States for implementing the cross-border sections of
networks.


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9.     Communication COM (2006) 846 on Priority Interconnection Plan
SUMMARY
Interconnection of networks allows the transmission of electricity and gas between markets
usually organized on a national basis, and is a key element in setting up trans-European gas and
electricity networks.
Interconnected networks are vital to the development of healthy competition and constitute a
prerequisite to successfully creating an internal energy market. They also prevent the risk of
short supply by diversifying sources, for example for electricity, by facilitating the introduction
of a "green network" based on renewable energies.
Development of energy structures in Europe
The trans-European networks are currently underdeveloped as a result of insufficient funding.
Certain malfunctions demonstrate the lack of coordination between the national energy networks
and of a genuine separation of production, transport and distribution functions. System operators
belonging to vertically-integrated companies have no incentive to develop their interconnections
with other networks and expose themselves to competition from new producers and suppliers in
the sector.
The infrastructures are increasingly operated at the limit of their physical capacities which
hampers the integration of additional energy resources necessary for market growth. Thus the
large-scale production of electricity from renewable sources could be compromised in certain
regions. The saturation of the networks also threatens to generate temporary breakdowns in
supply and an increase in energy prices. Numerous regions remain "energy islands" with poor
interconnections, or none at all, with the rest of the internal market.
The Priority Interconnection Plan (PIP) details the progress of the 42 projects of European
interest listed in the Guidelines for trans-European energy networks (TEN-E) adopted in 2006.
Sixty percent of electricity network projects are behind schedule, largely due to the complexity
and lack of harmonization in planning and authorization procedures. Funding problems and
environmental or health objections also constitute obstacles.
Although the gas projects of European interest are progressing more satisfactorily, the
completion of terminals and storage facilities for liquefied natural gas (LNG) sometimes
encounter major problems in some Member States where a number of projects have been
abandoned or frozen. External interconnections require particular attention since they are
responsible for more than 50% of our supplies and are becoming increasingly political.
10.    Regulation 1228/2003 on conditions for access to the network for cross -border
       exchanges in electricity
SUMMARY
The purpose of the Regulation is to stimulate cross-border exchanges in electricity by
establishing a compensation mechanism for transit flows of electricity and by introducing
harmonized principles on cross-border transmission charges and the allocation of available
interconnection capacities between national transmission systems.
Compensation mechanism between operators of transmission systems


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Transmission system operators (TSOs) receive compensation for costs incurred as a result of
hosting cross-border flows of electricity on their network. This compensation is paid by the
operators of national transmission systems from which the cross-border flows originate.
Compensation received by TSOs for hosting cross-border flows will be calculated based on the
costs of the infrastructure "used" for the flows.
Charges applied by network-operators for access to networks are transparent and take into
account the need for network security and reflect actual costs incurred.
Information on interconnection capacities
TSOs install coordination and information exchange mechanisms to ensure security of the
networks in the context of congestion management. Network congestion problems are addressed
with non-discriminatory solutions, i.e. methods that do not involve a selection between contracts
of individual market participants.
General principles of congestion management
Market participants must inform the transmission system operators concerned whether they
intend to use allocated capacity a reasonable time ahead of the relevant operational period. Any
allocated capacity that will not be used is reattributed to the market in an open, transparent and
non-discriminatory manner.
New interconnectors
New direct current interconnectors may, under certain strict conditions, benefit from exemptions.
In this context, the Commission has to monitor Member States' decisions regarding exemptions
and the restrictive way these measures are to be interpreted.
Guidelines
The guidelines specify in particular:
   -   details of methods for determining the quantity of cross-border flows hosted and the
       magnitudes of such flows;
   -   details of the treatment in the context of the inter-TSO compensation mechanism of
       electricity flows originating or ending in countries outside the European Economic Area
       (EEA);
Provision of information and confidentiality
Member States and the regulatory authorities provide the Commission, on request, with all
necessary information. The Commission fixes a reasonable time limit, taking into account the
complexity of the information required and the urgency with which the information is needed.
The Commission does not disclose this information which is covered by the obligation of
professional secrecy.
Penalties
The Member States lay down the rules on penalties applicable to infringements of the provisions
of this Regulation and take all measures necessary to ensure that they are implemented. The
Member States notify those provisions to the Commission by 1 July 2004 at the latest.



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11.    Regulation 714/2009 of 13 July 2009 on conditions for access to the network for
cross- border exchanges in electricity and repealing Regulation 1228/2003
SUMMARY
This Regulation aims at laying down rules for cross-border exchanges in electricity with a view
to improving competition and harmonization in the internal market for electricity.
Certification of transmission system operators
National regulatory authorities shall send the European Commission notification of decisions
concerning the certification of a transmission system operator. The Commission then has a
period of two months to deliver its opinion to the national regulatory authority. The authority
then adopts the final decision concerning the certification of the transmission system operator.
This decision and the Commission’s opinion are published.
European Network of Transmission System Operators (ENTSO) for electricity
Creation of the ENTSO for Electricity
The European Network of Transmission System Operators (ENTSO) for electricity is
responsible for managing the electricity transmission system and for allowing the trading and
supplying of electricity across borders in the Community. By 3 March 2011, the transmission
system operators for electricity shall submit to the Commission and to the Agency for the
Cooperation of Energy Regulators the draft statutes for the ENTSO for electricity, a list of
members and draft rules of procedure.
Tasks of the ENTSO concerning network codes
The Commission shall consult the Agency for the Cooperation of Energy Regulators and the
ENTSO for Electricity in order to establish an annual list of the priorities which are to contribute
to developing network codes. These codes shall be developed using a non-binding framework
guideline submitted to the Commission by the Agency. The codes include rules and procedures
relating in particular to:
      network security and reliability;
      data interexchange;
      technical and operational exchanges;
      transparency rules;
      harmonized transmission tariff structures;
      energy efficiency.
Tasks of the ENTSO for Electricity
The ENTSO for Electricity is responsible for adopting:
      common network operation tools;
      a ten-year network development plan;
      recommendations relating to the coordination of technical cooperation between
       Community transmission system operators;


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      an annual work program;
      an annual report;
      annual summer and winter generation supply outlooks.
Costs and financing
The costs related to the activities of the ENTSO for electricity shall be borne by the transmission
system operators. They shall establish regional cooperation within the ENTSO for electricity and
publish a regional investment plan every two years, on which investments may be based.
Transmission system operators shall receive compensation for costs incurred as a result of
hosting cross-border flows of electricity on their networks. The compensation shall be paid by
the operators of national transmission systems from which cross-border flows originate. The
costs shall be established on the basis of forecasted costs.
Charges for access to networks shall also be applied by operators.
Information and congestion management
Transmission system operators shall put in place information exchange mechanisms to ensure the
security of networks in the context of congestion management.
Network congestion problems shall be addressed with non-discriminatory market-based
solutions which give economic signals to the market participants and transmission system
operators.
New interconnectors may, upon request, be exempted, for a limited period of time, from the
general provisions governing congestion management on condition that:
      their installation increases competition in electricity supply;
      the level of risk necessitates the exemption;
      the interconnection must be owned by a natural or legal person;
      charges are levied on users of the interconnection;
      the exemption must not be to the detriment of competition in the internal market.
This Regulation repeals Regulation (EC) No 1228/2003 as from 3 March 2011.
III.   Taxation
12.    Council Directive 2003/96 of 27 October 2003 on taxation of energy products and
       electricity
SUMMARY
Energy products and electricity are only taxed when they are used as motor or heating fuel, and
not when they are used as raw materials or for the purposes of chemical reduction or in
electrolytic and metallurgical processes.
On the basis of this principle, the Directive sets minimum rates of taxation for motor fuel, motor
fuel for industrial or commercial use, heating fuel and electricity. The "levels of taxation" *
applied by the Member States may not be lower than the minimum rates set in the Directive.
The minimum levels of taxation applicable to heating fuels and electricity are the following:

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                                                              Minimum excise rates from   Minimum excise rates from
-                            Current minimum excise rates     1.1.2004 (business use)     1.1.2004 (non-business use)

Diesel (/1000 l.)                         18                               21                           21

Heavy fuel oil (/1000 kg.)                13                               15                           15

Kerosene (/1000 l.)                        0                                0                            0

LPG (/1000 kg.)                            0                                0                            0

Natural gas (/gigajoule)                   -                              0.15                          0.3

Coal and coke (/gigajoule)                 -                              0.15                          0.3

Electricity (/MWh)                         -                               0.5                          1.0


(The volumes are measured at a temperature of 15° C).
The Member States which on 1 January 2003 were authorized to apply a monitoring charge for
heating gas-oil may continue to apply a reduced rate of EUR 10 per 1000 liters for that product.
This authorization will be repealed on 1 January 2007 if the Council, acting unanimously on the
basis of a report and a proposal from the Commission, so decides, having noted that the level of
the reduced rate is too low to avoid problems of trade distortion between the Member States.
Differentiated rates of taxation
Provided that they comply with the minimum levels of taxation prescribed by the Directive and
are compatible with Community law, differentiated rates of taxation may be applied by Member
States, under fiscal control, in the following cases:
          when the differentiated rates are directly linked to product quality;
          when the differentiated rates depend on quantitative consumption levels for electricity
           and energy products used for heating purposes;
          for the following uses: local public passenger transport (including taxis), waste
           collection, armed forces and public administration, disabled people, ambulances;
          between business and non-business use, for the energy products and electricity referred to
above.
Exemptions and reductions
The following are exempt from taxation:
          energy products and electricity used to produce electricity and electricity used to maintain
           the ability to produce electricity. However, Member States may, for reasons of
           environmental policy, subject these products to taxation;
          energy products supplied for use as fuel for the purpose of air navigation other than in
           private pleasure-flying;
          energy products supplied for use as fuel for the purposes of navigation within
           Community waters, including fishing, other than private pleasure craft, and electricity
           produced on board a craft.



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IV.    Security of supply
13.    Directive 2005/89 concerning measures to safeguard security of electricity supply
and    infrastructure investment
SUMMARY
Subject matter and scope
This Directive establishes measures aimed at safeguarding security of electricity supply so as to
ensure the proper functioning of the EU internal market for electricity, an adequate level of
interconnection between Member States, an adequate level of generation capacity and balance
between supply and demand.
Member States must define general, transparent and non-discriminatory policies on security of
electricity supply compatible with the requirements of a competitive single market for electricity.
They must define and publish the role and responsibilities of competent authorities and different
players in the market.
When adopting policy implementation measures, Member States must take certain elements into
account, in particular the need to:
              ensure continuity of electricity supplies;
              study the internal market and the possibilities for cross-border cooperation in
               relation to security of electricity supply;
              reduce the long-term effects of growth of electricity demand;
              introduce a degree of diversity in electricity generation in order to ensure a
               reasonable balance between different primary fuels;
              promote energy efficiency and the use of new technologies;
              continuously renew       transmission    and   distribution   networks   to   maintain
               performance.
Operational network security
Transmission network operators must set minimum rules and obligations to ensure continuous
operation of the transmission and, where appropriate, the distribution network under foreseeable
circumstances. Member States may decide that these rules and obligations must be approved by
the competent authorities and, where appropriate, also respected by the transmission network
operators.
The network operators must set and meet quality of supply and network security performance
objectives. Curtailment of supply in emergency situations must be based on predefined criteria
and the relevant measures taken in consultation with other transmission system operators
concerned.
Balancing supply and demand
The Directive provides for specific measures necessary to maintain the balance between
electricity demand and available generation capacity, to avoid Member States taking more
interventionist measures which are incompatible with competition. They will need to have a clear
policy in place to maintain the balance between supply and demand. In particular Member States

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need to encourage the establishment of wholesale markets, require network operators to ensure
that an appropriate level of generation reserve capacity is maintained, facilitate the development
of new generation capacity, or encourage energy conservation and technology for demand
management in real time.
Network investment
Investment is crucial for competition and the future security of electricity supply in the EU.
Member States must lay down a framework for providing information to network operators
which facilitates investment.
V.     EU External dimension
14.    Council Decision 2006/500 on the conclusion by the European Community of the
       Energy Community Treaty
SUMMARY
The Energy Community Treaty provides for the creation of an integrated energy market
(electricity and gas) between the European Community and the contracting parties.
The members of the Energy Community are the European Community, Albania, Bosnia and
Herzegovina, Croatia, the Former Yugoslav Republic of Macedonia, Montenegro, Serbia and the
United Nations Interim Administration Mission in Kosovo pursuant to United Nations Security
Council Resolution 1244. In addition, one or more Member States of the European Union (EU)
may participate in the Energy Community at the request of the Ministerial Council. Third
countries may be accepted as observers.
The Treaty applies to the territory of the contracting parties and the territory under the
jurisdiction of the United Nations Interim Administration Mission in Kosovo.
The Treaty entered into force on 1 July 2006. It is concluded for a term of ten years. Its
application may be extended either for all parties by unanimous decision of the Ministerial
Council, or for the parties who vote for extension (as long as they number at least two thirds of
the number of Energy Community members).
Role of the Energy Community
The objectives of the Energy Community are:
              to create a stable legal and market framework capable of attracting investment in
               order to ensure a stable and continuous energy supply;
              to create a single regulatory space for trade in network energy;
              to enhance security of supply in this space and develop cross-border relations;
              to improve energy efficiency and the environmental situation related to network
               energy and develop renewable energy sources;
              to develop network energy market competition.
Activities of the Energy Community




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An important part of the Energy Community's activities involves the implementation of a part of
Community legislation, or 'acquis communautaire' 112, in all the States parties to the Treaty, on
energy, environment, competition and renewable energies, as well as compliance with certain
general Community standards relating to technical systems, for example on the subject of cross-
border transportation or connection.
In addition, the Treaty establishes a mechanism for operation of regional energy markets which
covers the territory of the parties to the Treaty and the EU Member States involved (Austria,
Bulgaria, Greece, Hungary, Italy, Romania and Slovenia). This system provides a framework of
measures relating to long-distance transportation of network energy, security of supply,
provision of energy to citizens, harmonization, promotion of renewable energy sources and
energy efficiency, as well as in the event of sudden crisis on the network energy market in the
territory of an Energy Community member.
Furthermore, the Treaty creates an energy market without internal frontiers between the parties,
in which customs duties and quantitative energy import and export restrictions, and any measures
having equivalent effect, are prohibited between the parties, unless exceptional circumstances
apply (relating to public order, public safety, protection of human and animal health,
preservation of plants, protection of industrial and commercial property). The Treaty also
contains provisions on relations with third countries and mutual assistance in case of disturbance.
The Commission acts as coordinator of these activities.
Institutions and decision-making
The Ministerial Council, made up of one representative for each party to the Treaty, provides
general policy guidelines, takes measures to meet the Treaty's objectives and adopts procedural
acts such as allocation of tasks, powers or obligations. The presidency is held in turn by each
party for a term of six months and is assisted by one representative of the European Community
and one representative of the incoming presidency. The Council submits an annual report to the
European Parliament and to the parliaments of the contracting parties.
The key mission of the Permanent High Level Group is to prepare the work of the Ministerial
Council. It consists of one representative of each party to the Treaty.
The Regulatory Board's primary role is to advise the other institutions and issue
recommendations in the event of cross-border disputes. It is composed of, for each party to the
Treaty, one representative of the energy regulator, with the European Community being
represented by the European Commission, assisted by one regulator from each participating
Member State, and one representative of the European Regulators Group for Electricity and Gas
(ERGEG).

112
   T he Community acquis is the body of common rights and obligations which bind all the Member States together within the
European Union. It is constantly evolving and comprises:
     the content, principles and political objectives of the T reaties;
     the legislation adopted in application of the treaties and the case law of the Court of Justice;
     the declarations and resolutions adopted by the Union;
     measures relating to the common foreign and security policy;
     measures relating to justice and home affairs;
     international agreements concluded by the Community and those concluded by the Member States between the mselves
         in the field of the Union's activities




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Moreover, the Energy Community is advised by two fora composed of representatives of all
interested parties.
The permanent Secretariat, based in Vienna, provides, amongst other things, administrative
support to the other institutions of the Energy Community and reviews proper fulfillment by the
parties of their obligations.
The Energy Community makes decisions (binding) and recommendations (non-binding). These
steps are taken, as appropriate, either on proposal from the European Commission (application of
the acquis communautaire), or on proposal by a party to the Treaty (other activities), and are
adopted either by a simple majority (application of the acquis communautaire), or by a two-
thirds majority (mechanism for operation of markets), or by unanimity (internal energy market).
In the event of serious and persistent breach by a party of its obligations, the Ministerial Council
may, acting by unanimity, suspend certain rights granted to this party by the Treaty.
VI.    EU Enlargement – Turkey (ongoing)
15.    Commission Report COM (2008) 674 final – SEC (2008) 2699 – not published in the
       Official Journal
SUMMARY
The energy sector in Turkey used to be dominated by State-owned companies. A privatization
program was nevertheless devised with a view to privatizing areas such as coal, oil, electricity
and gas. Turkey had to open up the energy sector to foreign investment in order to meet the
increasing demand for energy consumption. Efforts had to be made to ensure that the sector was
compatible with the Community internal energy market. The European strategy gave high
priority to the approximation of laws in this sector. The first step towards this objective was to
draw up a detailed inventory of the existing legislation.
The 1999 Report emphasized that the objectives of Turkish energy policy were largely in line
with those of the European Union (EU). They were concerned with security and diversification
of sources of supply, market principles, environmental standards and improving efficiency. The
amendment of the Constitution, paving the way for privatization, and international arbitration
procedures were important steps forward in this connection. A list of Turkish and Community
legislation in this field drawn up by Turkey with a view to alignment with the acquis would be
evaluated by the Commission. Much still remained to be done in this area.
In its November 2000 Report , the Commission noted that progress with transposing the
Community acquis in the field of energy had been limited. In total, only 16 out of 120 provisions
on energy were in harmony with EC legislation. The restructuring of the sector was under way
and the ratification of the Energy Charter Treaty and related instruments had been a positive step,
but much remained to be done.
In its November 2001 Report , the Commission confirmed that progress had been made since
the last report, in particular as regards the internal energy market. Turkey had adopted two key
laws concerning the electricity and gas market which concerned in particular the definition of the
new structure of the sectors and the status of the players in the two sectors. However, Turkish
legislation had not been completely aligned with the Community legislation in this field. There
had been no progress as regards security of supply, but Turkey’s total oil reserves were in any
case largely equivalent to the levels required by the Community acquis. Particular attention still

                                                225
needed to be paid to energy efficiency since there had been no progress in this connection since
the last report.
The October 2002 Report emphasized that Turkey had made significant progress in further
aligning its legislation with the acquis in this area, particularly in the internal energy market.
The 2003 Report noted that Turkey had continued to make progress with aligning its energy
legislation, notably by adopting implementing legislation in the last year which made the internal
energy market more competitive by opening up the gas market, among other things. Some
progress had also been achieved in the field of energy efficiency and renewables.
The 2004 Report noted that overall alignment remained limited and uneven across the different
areas of energy policy. Further efforts were necessary, throughout the sector, to align with the
acquis and to ensure effective implementation and enforcement of the legislation.
The November 2005 Report noted the continuation of efforts to align Turkey’s energy laws.
However, legislation needed to be implemented more effectively, especially as regards the
opening up of the energy market. A reasonable and ambitious timetable needed to be adopted on
energy efficiency and renewables. The various administrative bodies needed to be strengthened,
especially in the field of nuclear energy.
The November 2006 Report noted that alignment in the energy sector was uneven and that
progress was still needed in some areas, particularly as regards energy efficiency.
In its November 2007 Report, the Commission emphasized that some progress has been made,
particularly in terms of energy efficiency. It encouraged Turkey to continue alignment with the
acquis, to promote the adoption of ambitious targets for renewable energy and to reinforce the
independence and capacity of the regulatory authorities.
The 2008 report notes uneven progress in implementing the acquis. Competition is still limited
and there are delays in the implementation of a transparent pricing scheme. Moreover, national
objectives in terms of energy efficiency and renewable energy are still to be set.
Body of EU law (Community Acquis) (according to the Commission)
Community energy policy objectives include the improvement of competitiveness, security of
energy supplies and the protection of the environment. The energy acquis consists of rules and
policies, notably regarding competition and State aid (including in the coal sector), the internal
energy market (for example, opening up of the electricity and gas markets, promotion of
renewable energy sources, crisis management and oil stock security obligations), energy
efficiency and nuclear energy.
EVALUATION
Turkey has made progress in aligning with the acquis and in its preparations for the internal
energy market through the adoption of two major framework laws for the electricity and gas
sectors concerning in particular restructuring and the players in the sectors. Those two laws
should, however, be aligned to a greater extent with the two key Community directives
concerning the internal energy market. Following the adoption of the 2002 Electricity Market
Law, around 20% of the electricity market was opened up in 2002. The aim is to complete the
opening up of the market by 2011. Five new implementing regulations have been adopted since
the last report. The threshold for eligible consumers has moreover been reduced to 3 GWh. In
July 2008, a cost-based pricing mechanism entered into force to enable enterprises operating in

                                               226
the field of energy to reflect changes in production costs in their sale prices. The 2008 report also
notes that the privatization of electricity distribution has been successful in four regions and that
the market share of autonomous electricity producers has increased from 30 to 50 %.
Turkey has also set up an Energy Regulatory Board to monitor the energy sector. It should be
noted that the adoption of the two key laws and the establishment of an Energy Regulatory Board
were conditions for IMF (International Monetary Fund) support for Turkey. In general, Turkey’s
priority in restructuring the energy sector is to attract investment and reduce State control. The
two laws have paved the way for this but much remains to be done.
On security of supply, Turkey has already introduced major measures and its oil reserves are
more or less at the level of the 90 days required by the acquis. Turkey also has an important role
to play in the EU’s security of supply since it is a transit country for oil and gas from the Caspian
Sea, the Black Sea and Central Asia. The construction of the Blue Stream gas pipeline to bring
natural gas from Russia to Turkey is continuing. In 2002, Turkey took steps to further diversify
its supply resources and to strengthen its role as a transit country for the transportation of oil and
gas.
Implementing legislation on gas market licensing was adopted in September 2002. In 2003
Turkey and Greece signed an agreement on the construction of a gas interconnector between the
two countries. The new Petroleum Law of 2004 is a step forward in terms of alignment with the
oil stocks acquis. However, oil stocks are still not calculated according to EU methodology. The
2008 report notes that the natural gas pipeline between Turkey and Greece is now operational.
With regard to energy efficiency, Turkey has made some progress by adopting a framework law
on energy efficiency, in order to reduce the high energy intensity of the Turkish economy. The
law does not, however, contain any objectives and the provisions on high-efficiency
cogeneration do not comply with the acquis. The 2008 report describes the adoption of a
regulation implementing the Framework Law on energy efficiency for the transport sector. 2008
was declared the year of energy efficiency and an action plan was adopted to coordinate action in
this field.
In the area of renewable energy sources, Turkey had already adopted a Law on the use of
renewable energy sources for energy production and an implementing regulation on the
guarantee of origin. The framework law also increases the potential for promoting the production
of electricity from renewable energy sources. This legal framework still needs to be
supplemented by ambitious objectives in order to exploit the vast unused potential of renewable
energy sources in Turkey.
VII.   Renewable energy
16.   Directive 2009/28 of 23 April 2009 on the promotion of the use of energy from
renewable sources
SUMMARY
Background
In January 2007, the EU Commission published a Renewable Energy Roadmap outlining a long-
term strategy. It called for a mandatory target of a 20% share of renewable energies in the EU's
energy mix by 2020. The target was endorsed by EU leaders in March 2007.



                                                 227
To achieve this objective, the EU adopted a new Renewables Directive in April 2009 (RES
Directive 2009/28), which set individual targets for each member state.
EU Member states' targets
A new EU directive on renewable energies, agreed in December 2008, requires each member
state to increase its share of renewable energies - such as solar, wind or hydro - in the bloc's
energy mix to raise the overall share from 8.5% today to 20% by 2020. A 10% share of 'green
fuels' in transport is also included within the overall EU target.
To achieve the objective, every nation in the 27-member bloc is required to increase its share of
renewables by 5.5% from 2005 levels, with the remaining increase calculated on the basis of per
capita gross domestic product (GDP).
Member State       Share of renewables in 2005         Share required by 2020
Austria            23.3%                               34%
Belgium            2.2%                                13%
Bulgaria           9.4%                                16%
Cyprus             2.9%                                13%
Czech Republic     6.1%                                13%
Denmark            17%                                 30%
Estonia            18%                                 25%
Finland            28.5%                               38%
France             10.3%                               23%
Germany            5.8%                                18%
Greece             6.9%                                18%
Hungary            4.3%                                13%
Ireland            3.1%                                16%
Italy              5.2%                                17%
Latvia             32.6%                               40%
Lithuania          15%                                 23%
Luxembourg         0.9%                                11%
Malta              0%                                  10%
The Netherlands    2.4%                                14%
Poland             7.2%                                15%
Portugal           20.5%                               31%
Romania            17.8%                               24%
Slovak Republic    6.7%                                14%
Slovenia           16%                                 25%
Spain              8.7%                                20%
Sweden             39.8%                               49%
United Kingdom     1.3%                                15%

Interim targets
The directive set a series of interim targets, known as 'indicative trajectories', in order to ensure
steady progress towards the 2020 targets.
- 20% average between 2011 and 2012;
- 30% average between 2013 and 2014;
- 45% average between 2015 and 2016, and;

                                                 228
- 65% average between 2017 and 2018.
EU countries are free to decide their own preferred 'mix' of renewables, allowing them to take
account of their different potentials. They must present national action plans (NAPs) based on
the indicative trajectories to the European Commission by 30 June 2010, followed by progress
reports submitted every two years. The plans will need to be defined across three sectors:
electricity, heating and cooling, and transport.
The compromise agreement eventually rejected a regime whereby member states would have
faced financial penalties for failing to reach interim targets towards the 2020 goal. Member states
are, however, required to submit amended NAPs, setting out measures for rejoining the
indicative trajectories.
Brussels reserves the right to enact infringement proceedings if states do not take 'appropriate
measures' towards their targets, meaning the decision to take legal action will be at the
Commission's discretion rather than based on strict criteria.
Flexibility with EU national support schemes
Member states will be permitted to link their national support schemes to those of other EU
states, and will be allowed under certain conditions to import 'physical' renewable energy from
third-country sources, such as large solar farms in North Africa (see "Cooperation between
Member States" below). However, so-called 'virtual' imports, based on renewable energy
investments in third countries, cannot be counted towards national targets.
A system of open trading in renewable energy certificates between EU member states, favored
by electricity market traders and large electricity utilities, was rejected in favor of a system
whereby one member state can sell or trade excess renewables credits to another, based on
statistical values.
These so-called 'statistical transfers', which can only take place if the selling member state has
reached its interim renewables targets, can also be applied in cases where member states
cooperate on joint projects.
Cooperation between EU Member States
 Member States can “exchange” an amount of energy from renewable sources using a statistical
 transfer, and set up joint projects concerning the production of electricity and heating from
 renewable sources.
 It is also possible to establish cooperation with third countries (Art. 9 of RES Directive
 attached). The following conditions must be met:
      the electricity must be consumed in the Community;
      the electricity must be produced by a newly constructed installation (after June 2009);
      the quantity of electricity produced and exported must not benefit from any other support.
Grid access
Many smaller producers of renewable energy argue that a lack of transparency and blocked
access to energy grids are preventing them from competing on the market.



                                               229
The text seeks to address the problem by requesting member states to ensure that transmission
and distribution system operators provide "either priority access or guaranteed access to the grid
system of electricity produced from renewable energy sources".




                                               230
             Attachment 3.B




Prospects of Synchronizing the Power Grids
          of EIJLLPST Countries
             with ENTSO-E




                    231
Contents
Background     233
Lessons from advanced synchronous systems 234
The emergence of ENTSO-E 237
  ENTSO-E’s Ten-Year Network Development Plan (TYNDP) .................................................... 239
   TYNDP versus National and Regional Investment Plans ........................................................... 240
   New Network Codes ............................................................................................................ 240
About EIJLLPST Countries         241
Status of EIJLLPST Regional Initiatives 241
Barriers to Moving Forward       242
  Physical Infrastructure Barriers ............................................................................................. 243
      Lack of Generation Capacity ............................................................................................. 243
   Organizational Inflexibility ................................................................................................... 244
      Transmission Network Access ........................................................................................... 244
   Economic Constraints .......................................................................................................... 244
      Non-binding Trading Arrangements:................................................................................... 244
Lessons from Synchronization Schemes with the UCTE 244
  Case of Turkey ................................................................................................................... 244
   Case of IPS/UPS ................................................................................................................. 245
   Case of Ukraine and Moldova ............................................................................................... 246
Status of the EU Internal Electricity Market          246
Prospects for EIJLLPST Synchronization with ENTSO-E                          247
  Readiness for synchronization ............................................................................................... 248
   Synchronization Prospects .................................................................................................... 249
Prerequisites for EIJLLPST Synchronization with ENTSO-E    251
  Successful Synchronization of Turkey and Libya with ENTSO-E ............................................... 251
   Inevitable Technological measures......................................................................................... 252




                                                                 232
Background
A synchronized power system is an advanced level of system integration which consists of multi
system operators synchronously interconnecting their power grids during normal operation.
Operators could be within a country, regional/cross-border, or beyond. Under the synchronized
system, operators are obliged to maintain a common system frequency at the steady state.
Operators are mutually dependent and coordinate with a central control center that oversees the
system operations. Generally, a common coordinating body is created to assure the adherence to
agreed technical rules and standards by the operators. Such body normally supports a close
coordination between the operators to maintain system stability during normal and abnormal
operating conditions.
The common rules in a synchronized power system cover energy exchange rules; system security
standards (voltage control, frequency control and reserve/capacity requirement) and procedures
for maintaining system stability; scheduling and settlement rules; coordination of planning rules.
An example is the Union for the Co-ordination of Transmission of Electricity (UCTE) in
continental Europe 113. It consists of a very large area of synchronized systems which has been
developing since its establishment in 1951. The UCTE created an Operation Handbook as a
thorough set of operation principles and rules to support the TSOs in the technical operation of
the UCTE’s synchronized system.             The handbook provides the technical rules for
interconnection to secure the interoperability between all the TSOs in the UCTE’s synchronized
system.
The Purpose of this annex is to discuss the prospects of advancing regional integration initiatives
between EIJLLPST courtiers and the European Network of Transmission System Operators for
Electricity (ENTSO-E).
In a synchronized power system resources can be exploited between its participants. The
foremost advantage is that it provides a medium for more efficient system operation and energy
resource use within the synchronized area.        The following is an outline of the main
advantages/benefits of synchronized systems:
         Investment Planning: it can be coordinated at the synchronized system level (with
          sufficient national collaboration) to justify the elimination (or deferring) any excessive
          investments in generation and/or transmission. The common coordinating body is
          authorized to oversee the development and expansion in the synchronized area. This
          requires a very high level of cooperation between the system operators. However, in
          regionally synchronized systems (e.g. UCTE), the full delegation of powers to enforce
          regional investment plans has been a complex task and not fully achieved yet because of
          their over-riding nature on national plans.
         Operational Planning: key operational tasks can be jointly managed between the
          operators of the synchronized system to achieve mutually desired system reliability levels
          (adequacy of supply to meet demand and system security) and quality of supply. These
          tasks include maintenance planning, capacity and energy balancing arrangements,
          frequency and voltage controls, reserve provisions, congestion management, and
          management of system operating conditions.
113
  UCT E was wound up on July 01, 2009 and all of its operational tasks were transferred to ENT SO-E. Any description for
UCT E in this review reflects its operations before that.



                                                         233
      Cost Reduction : an overall cost reduction could be achieved through the utilization of low
       cost generation sources to meet demand (using the approach of economic dispatch), and
       joint contribution of reserves by system operators.
      Electricity Trade facilitations : the autonomous operation of the synchronized system,
       which is carefully coordinated between system operators, facilitates the electricity trade
       (capacity and energy) through several market mechanisms such as spot market, day
       ahead, auctions, etc. These mechanisms enable competition in cross-border trade and
       could enable energy swap between system operators or beyond. However, realizing these
       benefits requires high level of trade volumes which entails complex transactions and
       settlement arrangements.
      Harmonization : it is about creating consistency and minimizing differences between
       regulations and practices of system operators. In a synchronized system, harmonization
       of technical standards is required to maintain system reliability and efficient market
       operations. Besides, harmonization would significantly contribute in facilitating
       competitive cross-border trade in a synchronized system, and in streamlining the flow of
       private sector investments in national and regional projects. The most relevant areas of
       harmonization that need to be realized through the synchronization development process
       are technical standards, operational procedures ( including grid access) , pricing and
       balancing arrangements, and legal procedures.
The process of synchronizing different power grids is lengthy and requires high level of
commitments to manage its costs and mitigate associated risks. The costs are driven by
infrastructure reinforcements, technical rules development and execution, organizational capacity
improvements (technical and operational), and legal arrangements. Significant resources would
be required to set the sufficient task forces to manage the overall process and execute the agreed
projects for system synchronization.
Regarding the synchronization risks, the dominating risk is the likelihood of cascading failure
due to an outage that leads to over-loadings in some parts of the system and subsequence
failures. Such failure could jeopardize any part of the synchronized system, and thus, require
explicit commitment by all system operators to adhere to technical standards and procedures.
This is enforced through legally binding agreements among the system operators. Another risk
could be the reluctance of system operators to forgo the autonomy of their systems by joining a
synchronized area at high implementation costs.
Benefits, costs, and risks are shared by operators of the synchronized system to protect its
security and assure efficient market practices. That requires the willingness of system operators
(and governments) to support the synchronization process through taking the necessary actions to
(1) develop their networks and generation capacities (2) develop markets in a transparent manner
(3) enhance institutional framework, and (4) advocate electricity trade.
Lessons from advanced synchronous systems
The purpose of regionally synchronized system varies among the participating countries. It can
be greatly influenced by governments’ desire toward integration and trade, inconsistencies of
regulations, incompatibilities of markets’ rules, readiness of national and/or regional institutions,


                                                234
and availability of reliable national and regional transmission capacities. These factors could
hinder the development of fully synchronized system at the regional level.
Alignment of national and regional initiatives is one of the utmost enablers to achieve common
objectives and transparent governance in a synchronized system. The objectives of
synchronization evolve over time and require consistent cooperation among the participants. The
evolution of objectives is associated with the different stages of the synchronization process.
Transparency in governance (roles and responsibilities) would support the participants in
achieving the objectives and overseeing the factors described above.
The following is an overview of some synchronized power systems- their objectives and market
data are summarized (exhibit 2 illustrates a snapshot of these systems). These systems played a
major role in establishing the ENTSO-E. Later in this section, a description of the association of
ENTSO-E will be presented. 114
UCTE: is the Union for the Coordination of Transmission of Electricity in Continental Europe.
Since its establishment in 1951, it used to be the Union for the Coordination of Production and
Transmission of Electricity (UCPTE) to coordinate the operation and development of
transmission networks and generation. In 1999, UCTE has been re-defined as the association of
Transmission System Operators (TSOs) with a primary objective of committing to technical and
operation coordination of a synchronous system to ensure reliable electricity supply across
Continental Europe. In addition, the Association of European Transmission System Operators
(ETSO) was created in the same year to concentrate on market-related issues within the
synchronous system.
A major network failure in 2003, affecting Italy in particular, highlighted deficiencies in TSOs’
coordination, leading to a need for better-quality harmonization of operational practice within
UCTE. Thus, in 2005, UCTE turned to make its technical standards more enforced through an
Operation Handbook and legally binding Multi-Lateral Agreement between its members. By the
end of 2008, the installed capacity within the UCTE was 671.5GW with an annual generation of
2,643TWh; serving about 500 million consumers with an annual consumption of 2,603TWh of
which 285.2TWh (10%) was traded. The UCTE synchronous area comprised 29 TSOs operating
across 24 member countries, in addition to other non-member countries that are synchronized
with the UCTE region (exhibit 1).




114
   All the sources of the ENT SO-E and its members (former associations) discussed in this annex are from www.entsoe-eu and
former associations reports



                                                           235
                             Exhibit 1 UCTE Synchronous Area




ETSO: is the association of European Transmission System Operators that was created in 1999
to work in parallel with UCTE but on market-related initiatives to advance cross-border
electricity trade. The founding members of the ETSO are the associations of UCTE, NORDEL,
UKTROA, and ATSOI. The main motives, objectives, of creating the ETSO were to focus on
harmonizing network access rules to market players for better network operations and system
security, and facilitate the development of the European electricity market that is supported by
the European Union. ETSO represented 40 TSOs member companies before transferring its
activities to ENTSO-E.
NORDEL: is the organization of the Transmission System Operators (TSOs) of Denmark,
Finland, Iceland, Norway, and Sweden. NORDEL was established in 1963 which has developed
over time through interconnections between the NORDEL countries and other European
countries (e.g. Germany, Netherlands, Russia, and Estonia). The objective of NORDEL was
focused on ensuring system security, maintaining supply-demand balance through adequate
transmission to maintain at all times, and supporting efficient electricity market. In 2008, the
installed capacity reached 97.2GW, annual generation of 414TWh, 25.2 consumers with annual
consumption of 412.7TWh of which 66.3TWh (16%) was traded.


                                              236
    BALTSO – is Baltic Transmission System Operators that was founded in 2006 as the
    cooperation organization of Estonian, Latvian and Lithuanian TSOs. BALTSO’s objectives were
    concentrated on creating conditions to ensure reliable system operations and protection of the
    electricity market, develop the necessary network interconnections, and initiate cooperation and
    build relationships with its members and other institutions in the Baltic States, Europe and
    beyond. In 2008, BALTSO’s installed capacity was 9.3GW and annual generation of 28TWh;
    serving 6.9 million consumers with a total annual consumption of 27.1TWh of which 8.9TWh
    (32%) was traded.
                   Exhibit 2 A snapshot of the advanced synchronous system schemes
 Market      Years of        Number of     Population     Installed      Peak load      Annual           Annual        Sum of
             operation       countries     (million)      capacity       (GW)           generation       Consumption   exports
             (from-to)       (#TSOs)                      (GW)115                       (TWh)            (TWh)         (TWh)
UCTE-2008    1951-2009          24 (29)    over 500            671.5          392             2,643            2,603         285.2
                                                                                            (net)            (net)

ETSO         1999-2009           ? (40)         ?              ?              ?                  ?              ?                ?


NORDEL-      1963-2009           5 (4)          25.2           97.2           61                414           412.7          66.3
2008
BALTSO-          2006-2009       3 (3)          6.9            9.3            4.7             28 (net)         27.1              8.9
2008                                                                                                        (net)

    It can be noted that there are common characteristics among the development of the above
    described synchronous schemes. The following is a list of the main features:
             ▫     Protecting system reliability (adequacy and security) and network access to market
                   players (mainly electricity trade) are among the common objectives in synchronous
                   power grids;
             ▫     Synchronizing power grids is a long-process process with an evolving technical and
                   economic objectives that require consistent and close cooperation;
             ▫     Separating the roles of technical operation and electricity trade could facilitate the
                   development of electricity market, and improve the levels of system reliability;
             ▫     Expanding the synchronous area beyond the boundaries of the participating countries
                   can be done with an assurance of maintaining system reliability and transparent
                   electricity trade; and
             ▫     TSOs work independently from other electricity functions (generation and
                   distribution) but must comply with strict network access rules and security of supply.
    The emergence of ENTSO-E
    In September 2007, the European Commission adopted the Third Legislative Package in which
    included a proposal for establishing a new European Network for Transmission System
    Operators for electricity (ENTSO-E), and another proposal for establishing the Agency for the
    Cooperation of Energy Regulators (ACER) that was needed to strengthen the powers of the
    national regulatory authorities. The latter will be effective in March 2011 and will play a major
    role in assuring cooperation and consistency at the European level. In June 2008, the leaders of

    115
      Installed capacity comprises renewables and other sources but the actual available capacity is much less due to unusable
    capacity, planned outages, forced outages, and system reserve



                                                              237
the existing European TSOs signed a declaration of intent to establish ENTSO-E association.
This showed the TSOs’ commitment and level of cooperation to facilitate the development of an
internal electricity market at the European level.
In December 2008, ENTSO-E was founded as a voluntary association- as of 1 July 2009,
ENTSO-E became fully operational through 42 European member TSOs in 34 countries.
ENTSO-E replaced all formerly existing TSOs’ associations: ATSOI, BA LTSO, NORDEL,
UCTE, ETSO and UKTSOA, and took new mandates under the Third Legislative Package. That
is follow by the Third Legislative Package for the Internal Energy Market (IEM) being adopted
by the European Commission on 3 September 2009. Exhibit 3 illustrates the synchronous areas
of the ENTSO-E member countries.
                         Exhibit 3 ENTSO-E Synchronous Areas




ENTSO-E comprises of 828GW installed capacity, 305,000km of transmission lines operated by
the member TSOs to serve 525 million citizens with a consumption of 3,400 TWh/year of which
400 TWh of energy exchanges annually. The TSOs cooperate regionally and at a European level
through ENTSO-E as one common organization. ENTSO-E’s activities are organized into three
committees: System Development in charge of TSO cooperation regarding the network
development and planning; System Operations in charge of technical and operational

                                            238
cooperation of the TSOs; and Market in charge of facilitating competitive markets. The
committees are supported by a Legal & Regulatory Group (Exhibit 4).
ENTSO-E activities are determined by its three principal objectives 116:
          1. “Ensuring the secure and reliable operation of the European power transmission system
             in an increasingly complex pan-European electricity transmission network.
          2. Facilitating the secure integration of renewable energy sources and thus the
             achievement of the EU’s greenhouse gases reduction goals.
          3. Enhancing the integration of the Internal Energy Market (IEM) by proposing and
             implementing standardized market integration and transparency frameworks.”
                                Exhibit 4 ENTSO-E organizational structure




ENTSO-E’s Ten-Year Network De velopment Plan (TYNDP)
The Third Legislative Package required ENTSO-E to prepare a Ten-Year Network Development
Plan (TYNDP), a consolidated R & D Plan, and measures for improved operational coordination.
The TYNDP is a non-binding plan with the objectives of ensuring transparency in developing the
electricity transmission networks and supporting decision-making processes at regional and
European level. The first release of the TYNDP was in June 2010, it put forward a total of more
than 500 transmission investment projects. These projects are expected to help in realizing the
three pillars of the EU energy policy, namely (1) ensuring Security of Supply (SoS) and system
reliability (2) increasing the use of renewable energy sources (RES) to 20% of production in

116
      ENT SO-E 2009 annual report



                                                   239
2020, and (3) advancing the development of the Internal Electricity Market (IEM) by eliminating
congestion in the transmission networks. The projects are seen as pre-requisites for achieving
highly efficient cross-border trade and competitive internal electricity market across Europe. The
TYNDP underlined over 42,000km, about 14% of existing transmission lines, of new
transmission projects to be constructed, of which about 35,000km of new transmission lines and
7,000 km of existing line upgrades (exhibit 5). Furthermore, the new transmission projects
support the three pillars of the EU energy policy as follows: 28,500 of new transmission lines are
driven by IEM, 26,000km by the SoS, and 20,000 km by RES 117. This demonstrates that several
individual projects could be driven by more than one pillar.
                      Exhibit 5 Transmission Investment Projects in the TYNDP




TYNDP versus National and Regional Investment Plans
As stated above, the TYNDP is non-binding but has to be updated every two years with take into
consideration the national development plans. At the national level, investment plans are
binding, updated annually, and are anticipated to build national generation adequacy outlook and
investment plans to meet national consumption and potential exchanges. Regional investment
plans are non-binding and have to be updated every two years with consideration to the TYNDP
and national investment plans.
New Network Codes
The Third Legislative Package requires ENTSO-E to develop new Network codes that overcome
the limitations of the Operation Handbook. These limitations are relevant to inability of
establishing binding rules (e.g. network access and economic rules) for grid users at the national
level such as power plants, consumers, and distribution that could be potential affected by the
grid operations. Such limitations can be addressed at the national level (e.g. grid codes, laws) as
the scope of Operation Handbook is only binding for TSOs. Thus, Article 8 (6) of Regulation

117
      T YNDP report



                                                240
(EC) 714 / 2009 empowers ENTSO-E’s network codes to be binding to all those affected by the
grid to ensure secure system operation in the synchronous areas and efficient market integration
towards a successful IEM. The mentioned Article defines 12 specific areas of network codes that
falls under three categories (1) Operations-related code topics, (2) Development-related code
topics, and (3) Market-related code topics.
About EIJLLPST Countries
EIJLLPST countries have undertaken tremendous efforts to improve the security of electricity
supply and meet the remarkable demand growth118. However, most of the endeavors were
primarily concentrated within the confines of each country’s power system. Nearly all initiatives
of cross-border interconnections were limited to emergency operations instead of energy
exchange at normal system operations. Recently, the peak demand growth in most of the
EIJLLPST countries had surpassed the generation capacity expansion. The accumulated effect of
that phenomenon was an additional pressure on generation capacity and aggressive load
shedding. The latter was a measure that most of the utilities had to take to maintain an acceptable
level of system reliability which is needed for two main reasons; first, to assure the availability
of sufficient supply to instantaneously meet the demand requirements; and second, to achieve
high level of system security at normal and abnormal operations. Therefore, EIJLLPST
countries’ investments were dedicated to maintain and develop their domestic power grids.
Reserve margin remains an issue in most of the countries and will continue in the foreseeable
future because of the accumulated deficiency in generation capacity and rapid demand growth
(see exhibit 6). Besides, the recent financial crisis brought on additional burden on the
governments of EIJLLPST countries. Major infrastructure projects (generation, transmission, and
distribution) have been postponed due to the lack of financing sources. The limited means of
private sector access to the power sector had also added more constraints to developing the
power grids. However, these factors did not harness the demand growth which has been mostly
driven by changes in the residential demand behavior (e.g. increasing use of air-conditioning).
      Exhibit 6 Key indicators of the power systems in the EIJLLPST 1 countries in 2008
          Indicators              Egypt       Iraq          Jordan      Syria      Lebanon     Palestine      Libya
      Population (million)        83.0            26.1        5.9           21.2        4.1         3.9       6.3
      Installed Capacity
                                  22.8           6.1          2.5           7.7         2.3         .14       6.0
      (GW)119
      Peak Demand (GW)            19.7           10.9         2.2           6.7         2.1         0.8       5.8
      Reserve Margin (%)120       16             -44          14            15          8           -83       4
      Consumption (TWh)           125.4          66.8         13.4          38.4        11.2        3.9       32.5

Status of EIJLLPST Regional Initiatives
Electricity cross-border interconnection projects between the EIJLLPST countries started in ad
hoc approach since early seventies. The main purpose of these interconnections was the security
of supply in abnormal operations and/or critical emergency conditions. Thus, the benefits of


118
    EIJLLPST countries are located on the South East of Mediterranean, namely: Egypt, Iraq, Jordan, Syria, Lebanon, and
Palestine. Libya is also a member of EIJLLPST , but has been excluded from this analysis.
119
    T he available capacity during peak demand would be the installed capacity minus planned outages, forced outages, and
unusable capacity (mainly from renewables and industries)
120
    Reserve margin is based on installed capacity, which would be much lower after considering the available capacity as
described in footnote 5



                                                          241
these projects were not fully exploited as operations were not continuous and in most cases
below the designed voltage and capacity of the interconnections.
Economic growth and rapid increase in population of EIJLLPST countries encouraged the
governments to consider potential areas for collaboration at the regional level. Electricity cross-
border interconnections were among the major areas to exploit for several reasons such as
reducing generation investment costs, enhancing system reliability, sharing reserves, improving
generation efficiency, and exploiting other benefits of economies of scale.
In 1988, five countries, namely: Jordan, Syria, Egypt, Turkey and Iraq, agreed to construct a cross -border
interconnection between their power grids. Turkey was included because its potential role that could play
in future electricity trade with Europe. A major part of the agreement was the commitment by each
country to upgrade its power grid to meet regional requirements. The project was extended to eight
countries with the addition of Lebanon, Libya and Palestine. The project feasibility studies concluded
that the interconnection project voltage is AC at levels of 400kV and 500kV that will be
completed in different stages 121. Exhibit 7 presents a list of existing cross-border interconnections
between the EIJLLPST countries and Turkey.
      Exhibit 7 Existing cross-border interconnections between EIJLLPST countries and Turkey
       Countries                 Circuits/Voltage            Capacity          Year of Operation       Sum of exports
                                                                                                       (GWh) in 2007
       Turkey – Syria               1 x 400 kV              1135 MVA                 2007
       Syria – Jordan               1 x 230 kV               55 MVA                 1977?
       Syria – Jordan               1 x 230 kV              267 MVA                 1980?
       Syria – Jordan               1 x 400 kV              1135 MVA                 2000                   167
       Syria – Lebanon               2 x 66 kV              110 MVA                  1972
       Syria – Lebanon              1 x 230 kV              267 MVA                  1977
       Syria – Lebanon              1 x 400 kV              1135 MVA               April 2010
       Syria – Iraq                 1 x 230 kV              267 MVA                  2000
       Jordan – Egypt               1 x 400 kV              550 MVA                  1998                   212.6
       Jordan – West Bank           2 x 132 kV               20 MW                   2007
                                (operated on 33 kV)
       Egypt – Libya                1 x 220 kV              120 MVA                  1998                    6.6
                             (to be upgraded to 400kV
                                      on 2012)
       Egypt – Gaza                  1 x 22 kV                17 MW                  2006                     ?
       Iraq – Turkey                1 x 400 kV               200 MW                  2002                     ?
                               (operated on 154 kV)

Barriers to Moving Forward
Nearly all stages of the eight-country interconnection project were completed but only the grids
of Egypt, Jordan, and Syria are synchronized122. Yet, there is no bulk electricity trade between
the three grids, instead a moderate exchange to overcome critical system operations. Thus, the
true merits of synchronization are not realized and energy trade benefits (technical and
economic) are under-exploited. On Syria-Turkey 400kV interconnection, it is either operated in
islanded-mode or not operational. The current status of the eight-country project underlines the
level of readiness of EIJLLPST countries to move for full synchronization within their power
grids and/or beyond. The following is an overview of the observed barriers to moving forward.


121
    T he interconnection project was divided into six stages: Egypt-Jordan-Syria, Egypt -Libya, Syria-T urkey, Syria-Lebanon,
Syria- Iraq-T urkey, and Jordan-Palestine
122
    Libya is synchronized with Egypt on the 220kV but there is not sufficient information on the continuity of synchronization per
year.



                                                              242
Physical Infrastructure Barriers
Lack of Generation Capacity
As noted above, the majority of EIJLLPST countries are facing the challenge of balancing
supply and demand. There is a lack of surplus generating capacity which creates inadequate
reserve margin that could lead to critical system operations. Despite of higher installed capacity
values, available capacity to meet the peak demand and maintain a sufficient reserve margin
remains the key factor. Thus, during peak time systems would be under enormous pressure as
they run under very thin reserve margins (negative in most countries) which could lead to
inefficient operations and an unstable system performance. The following is an overview of the
possible implications of inadequate generating capacity on system operations:
         Reliability risk : it is triggered when the system is unable to meet demand (peak and
          energy) at any point of time with consideration of different types of system outages
          and/or when it does not safely handle any sudden disturbances. The latter is a system
          security issue. Therefore, operators of power grids in EIJLLPST countries could be
          forced to apply rigorous load shedding actions and to disconnect cross-border
          interconnections to maintain the security of supply at the national level.
         Stability risk : it is about maintaining system synchronism during normal and abnormal
          operations. System operators have to control voltage and frequency to maintain the
          stability of the synchronized power grids. Therefore, a double equilibrium must be
          achieved (1) active power equilibrium to maintain frequency, and (2) reactive power
          equilibrium to maintain voltage. In the case of EIJLLPST power grids, the lack of
          sufficient reserve margin (mainly spinning reserve) is likely to create an imbalance
          between system generation and demand. This would lead to non-equilibrium in active
          power which results in deviations from nominal frequency (50Hz in EIJLLPST power
          grids). For the currently synchronized systems ( Egypt, Jordan, and Syria), coordination
          to share extra power to boost spinning reserve that is needed for maintaining an active
          power equilibrium is limited due to the lack of available generating capacity in mostly all
          of these systems123. Moreover, the lack of generating capacity would require intensive
          frequency control measures (primary and secondary) to maintain nominal system
          frequency within the synchronized systems of EIJLLPST countries 124.
          On voltage control (reactive power equilibrium), there is no sufficient information to
          raise the issue of voltage. However, the long distance of the AC interconnection between
          EIJLLPST power grids may require voltage control measures (e.g. static var
          compensators-SVCs) at the regional level to assure voltage stability and close
          compensation of inductive loads.
         Low system inertia: the larger number of synchronized machines the higher system
          inertia. As system is never at steady state due to the changing nature of consumption
          behavior and its exposure to different types of disruptions. If the imbalances between

123
    T he nominal frequency in the synchronized power grids of Egypt, Jordan, and Syria is the frequency of Egypt’s system. T his
is due to the size of the Egyptian power system (i.e. higher system inertia)
124
    Primary control is operated by a governor control that is fast and local at the generator. Secondary control is operated by the
control center (system operators) but it is slow and over the whole system to maintain steady -state frequency; it is maintained by
Automatic Generation Control (AGC) or Load Frequen cy Control (LFC).



                                                               243
            generation and demand are relatively small to the inertia of the total rotational mass of all
            machines, synchronism can be maintained. Some of EIJLLPST power grids are likely to
            have very low system inertia which makes synchronization to high inertia system very
            complex due to potential deviation from nominal frequency. This situation would require
            significant reinforcement to secondary frequency control at the generation side before full
            synchronization of the entire EIJLLPST power grids.
Organizational Inflexibility
Transmission Network Access
Transmission function is still managed as part of a vertically integrated system under a ministry
in most of the power grids in EIJLLPST countries. The organizational attachment (mainly in
decision making) of the transmission and the unavailability of regulatory rules are blocking the
means for third party access to power grids. Therefore, attracting market players (such as IPPs,
industrial consumers, traders) would require non-discriminatory and transparent market rules.
This situation of organizational inflexibility contributes to the slow development of EIJLLPST
countries’ electricity market. In contrast, the independence of the transmission as a function (so-
called: transmission system operator (TSO)) with defined responsibilities and decision-making
authority over system operations would facilitate the synchronization process and market
development
Economic Constraints
Non-binding Trading Arrangements:
The current trading arrangements between the system operators of the synchronized power grids
are bilateral. Each agreement is signed at the ministerial level but does not include binding
articles for trading electricity in bulk amounts. Instead, most of the agreements seem to limit
electricity trade to exchanges during emergency operations. Thus, the attractiveness of electricity
trade in EIJLLPST countries would be very limited by the current trading arrangements.
Lessons from Synchronization Schemes with the UCTE
Prior to the formation of ENTSO-E, several synchronization schemes with the UCTE were
initiated. They aimed at exploiting the benefits of full synchronization with the UCTE. The
experiences of these schemes varied in terms of process and timeline but all have a common
condition they have to comply with in order to be fully synchronized with the UCTE. The
condition requires any country (or group of countries) under each scheme to permanently
disconnect its interconnections with neighboring countries. Once this condition is met, the
synchronization must meet the technical standard terms described in the Operation Handbook.
The following is a brief on these synchronization schemes125.
Case of Turkey
It started with a request from Turkish Electricity Transmission Corporation (TEIAS) to UCTE
for synchronization and membership. The technical objective of the scheme is to improve the
security of supply and stable system performance. A dedicated project group was established to
oversee project studies, preliminary tests, and interconnection options. In 2007, the feasibility

125
      All these schemes are currently handled through the ENT SO-E



                                                             244
study concluded the feasible interconnection of Turkish power system to the UCTE. However,
the study identified two prerequisites for reliable synchronism:
      1. Enhancing the performance of primary and secondary frequency control of the Turkish
         power system; and
      2. Improving the damping performance of the generation units regarding low inter-area
         oscillations
In 2008, TEIAS launched the project of “Rehabilitation of the Frequency Control Performance of
the Turkish Power System for Synchronous Operation with UCTE”. The scope of this project
addresses several tasks on power and frequency control, steady state, and transient stability that
should be taken by the Turkish power system for synchronous operations with the UCTE. This
included a preliminary monitoring of the dynamic performances was made possible by the
installation of Wide Area Monitoring System (WAMS) in five substations in Turkey.
The net transfer capacity (NTC) for import to Turkey is within the range of 800– 1300MW, while
the NTC for export from Turkey is within the range of 1000– 1100MW (Exhibit 8). Studies
identified the maximum NTC for export not exceeding 500MW during the trial operations. The
first isolated tests were started early 2010. After a successful completion of these tests, the one
year trial period for synchronous parallel operation of the interconnection was started in
September 2010. During the trial period, the synchronized systems will be closely monitored to
assure a secure and stable performance.
                   Exhibit 8 Existing Interconnections of Turkey with UCTE 126
                        Interconnection       Type                             Voltage      Capacity
                                                                               (kV)         (MVA)
                        Bulgaria-Turkey       AC single                               400        1000

                        Bulgaria-Turkey       AC single circuit                      400         1500
                                                                         127
                        Greece-Turkey         AC single/double circuit               400         1510


The contractual agreement is a legally binding document to TEIAS and UCTE (currently
ENTSO-E). The signature of the agreement means the beginning of an official synchronous
operation and energy exchange between the two systems. The agreement includes different
clauses to cover technical (including grid code), institutional, regulatory, and legal aspects. As
the trial parallel operation started in September 18, 2010, it means that the agreement has been
signed or at least the technical sections were signed.
Case of IPS/UPS
The project scope is very ambitious as it would serve over 700 million consumers in 36 countries
spanning more than ten time zones. The project is driven by various factors (political,
economical, energy security, and efficient operation and control). A feasibility study was
completed in 2004-2008 through a consortium representing the UCTE and another for the
IPS/UPS. The study investigated the feasibility of a possible synchronous coupling of the power
systems of the IPS/ UPS with the UCTE. The study evaluated all the technical, organizational,
and legal issues with consideration of maintaining the current levels of the two systems with
126
     MEDRING UPDAT E Study: Analysis and Proposals of Solutions for the Closure of the Ring and North -South Electrical
Corridors”, Volume II, April, 2010.
127
    It interconnects three substations through double-circuit in one side and single-circuit in the other side.



                                                           245
regards to system security and reliability. Considering system security and market issues, the
findings underlined the complexity of the synchronous coupling. If that becomes feasible, it must
be considered as a long-term option. Besides, asynchronous system coupling (through BTB-
HVDC) lines can be considered as alternative in the medium-term. The BTB-HVDC option
would be considered a new separate project.
Case of Ukraine and Moldova
With the objective of enhancing energy security in Europe, the Ukrainian company NPC
Ukrenergo and the Moldovan Company Moldelectrica applied for a separate investigation of the
full synchronous interconnection of the Ukrainian IPS and Power System of Moldova with the
UCTE. This project is related to the IPS/UPS project and is one of the projects of European
significance. The initial estimated cost of the Project is about €4.5 billion and would require
feasibility studies, tests, and trial operation. The assigned working groups will carry out the
steady state and dynamic assessments, and power system control analysis. The curre nt
coordination is through the ENTSO-E’s Continental Europe for the launch of the feasibility
study.
Status of the EU Internal Electricity Market
There are two major issues on the progress towards the Internal Electricity Market in Europe.
The following is a summary of these issues 128:
       1. Increasing renewable energy sources (RES): the future large-scale of intermittent wind
            penetration in the North Sea Region may create new grid constraints. In order to
            overcome such inevitable constraints, the North Sea countries would need to develop
            sufficient interconnections and reinforce their networks through deeper integration in the
            next ten years.
       2. Open grid access and electricity trade: the current grid constraints could lead insecure
            system performance due to high amounts of electricity trade (i.e. an increase in cross-
            border exchanges). In the mid-term, the issue of the need for higher exchange capacity is
            emerging in several interconnections (either between individual countries or regions
            within the ENTSO-E). This applies on the long-term perspective as well.
Therefore, the above issues pose significant challenges before the realization of the Internal
Electricity Market. All the ENTSO-E regions will be facing these challenges except the Baltic
region (see exhibit 9).




128
      Source: T YNDP



                                                   246
                         Exhibit 9 ENTSO-E Synchronous Regions




Prospects for EIJLLPST Synchronization with ENTSO-E
The conclusions of the first feasibility of MEDRING study (conducted in 2001-2003) underlined
the complex operations of using full AC interconnections to close the Mediterranean electricity
ring to enable electricity trade within the Southern and Eastern Mediterranean countries (SEMC)
and between SEMC and Europe. The complexity was illustrated through several system
operation issues relevant to system stability due small and large (transient) disturbances.
Frequency control was clearly a major issue in the AC closure of the ring. The study was
updated in 2010 and raised the need for investigating a combined solution of AC and DC
interconnections. The revisit of study has been triggered by governments, regional institutions
(e.g. Union for the Mediterranean, Mediterranean Solar Plan, Desertec Initiative), and private
companies. The common interest of these parties was driven by realization for potential mutual
benefits from synchronization such as the exploitation of solar and wind power resources in the
EIJLLPST and Maghreb countries.

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The learned lessons from the early described synchronization schemes illustrate the lengthy and
complex process of synchronization that addresses technical (including grid code), institutional,
regulatory, and legal aspects. Besides, it requires complete feasibility studies, isolated tests, and
trial parallel operations. Other lessons can be observed in the case of synchronizing Libya and
Tunis that was agreed between UCTE and countries of Maghreb and EIJLLPST in 2003. The
synchronization attempt between Libya and Tunisia failed in 2005 due to deficiencies in power
grid, system protection, power-frequency control, and high normal load deviations.
Readiness for synchronization
The potential for synchronizing the entire EIJLLPST countries with ENTSO-E is not likely to
occur in the foreseeable future. Considering the current conditions in the EIJLLPST power grids,
a complete synchronization of ENTSO-E with these grids should be a long-term goal and
through a gradual approach. Over the short and medium timeframes, systems operators in
EIJLLPST countries need to address physical infrastructure and technical issues (as noted earlier,
stability issues concerning frequency, voltage, and dynamic [also called rotor angle]). Besides, a
very important issue that requires the attention of EIJLLPST countries is the condition of
permanently disconnecting neighboring systems before synchronization with the ENTSO-E. This
could lead to critical decisions by EIJLLPST’s systems operators on the approach and type of
synchronization.
In regard to the physical infrastructure status of each country in EIJLLPST and its readiness for
cross-border synchronization, exhibit 10 highlights the required system improvements by each
country according to its progress in the current eight-country project.
                Exhibit 10 Required System improvements for synchronization
Country     Transmission system improvements                  Readiness                for    Readiness for synchronization (or
                                                              synchronization         with    asynchrnoization) with ENTSO-E
                                                              Mashreq/eight        country
            National                Cross-border              project

Egypt       Strengthening the       Upgrade from 220kV to     Currently synchronized with     likely in the medium- to long-term
            500kV transmission      500kV in the Egyptian     Jordan and Syria
            networks                side of Libya
                                    interconnection
Jordan      Strengthening the                                 Currently synchronized with     likely in the medium- to long-term
            400kV network                                     Egypt and Syria
Syria       Completing the                                    Currently synchronized with     likely in the medium- to long-term
            Upgrade of                                        Egypt and Jordan
            transmission
            networks to 400kV
Iraq        System rehabilitation   Completing the            -                               Potential and partially in the long-term-
            (includes generation)   interconnection project                                   after 2020
                                    with Syria and Turkey
Lebanon     System rehabilitation   -                         Islanded mode with Syria        Potential and partially in the long-term,
            (includes generation)                                                             after 2020
Palestine   System rehabilitation   Upgrading the operation   Islanded mode with Egypt        Potential and partially in the long-term,
            (includes generation)   with Jordan to 132kV      and Jordan                      after 2025
Turkey      -                                                 Islanded mode with Syria and    Under one year trial period
                                                              Iraq                            Synchronization started in September
                                                                                              2010
Libya       Completing the                                    Synchronized with Egypt but     Likely in the medium- term
            Upgrade of                                        type of synchronization (full
            transmission                                      or islanded) is unclear
            networks to 400kV

The above matrix illustrates the readiness of each country for synchronization (or
asynchrnization) with any of EIJLLPST countries and/or ENTSO-E. The readiness is estimated

                                                              248
based on the under-construction or planned physical infrastructure development in generation
and transmission. The characterization of that readiness means identifying which countries in the
EIJLLPST could be ready for synchronization as such. Thus, a country could synchronize with
ENTSO-E but not EIJLLPST countries. However, any country plans to approach EMTSO-E for
synchronization assessment should prepare to fulfill the condition of permanently isolating its
system from neighboring countries. Notably, synchronization with ENTSO-E could impact the
full AC synchronization within EIJLLPST.
The matrix shows that a full AC synchronization within the EIJLLPST countries is not likely to
happen before 2020. Moreover, Egypt, Jordan, and Syria are the only EIJLLPST countries with
recognizable potential to start the preparatory work for synchronization with the ENTSO-E in the
medium- to long-term. However, time and likelihood for accomplishing such a goal can be
determined after conducting the main assessment steps (feasibility studies, isolated tests, trial
parallel operations, etc.) which could be different from one country to another.
The above described readiness addresses synchronization from the physical infrastructure
perspective. Yet, the feasibility studies will assess the technical readiness and required measures
(physical and operational) for each country or a group of countries in EIJLLPST to synchronize
(or asynchronize) with ENTSO-E. Furthermore, the entire synchronization process would be
influenced by other aspects than physical and technical such as political will, regulatory,
institutional, and legal aspects. In this document, these aspects are not covered in the
assessment of prospects for synchronizing EIJLLPST countries with ENTSO-E. Thus, in
addition to the discussion or prospects in the following sections, the influence and
requirements of these aspects should be added to complement the overall assessment.
Synchronization Prospects
The exploitation of synchronization prospects between individual countries (or a group of
countries) in EIJLLPST and the ENTSO-E would require devoted feasibility study (ies) to
investigate the operations over HVAC and HVDC transmission technologies. There is a need to
address all possible synchronization solutions to ensure overcoming the constraints of technical
and physical readiness in the power systems of EIJLLPST countries and the long distances for
trading bulk electricity with ENTSO-E.
In regard to EU commitments to renewables, the 20% renewable energy sources (RES) in 2020
(one of the EU energy policy pillars) could create new prospect for direct interconnections with
the ENTSO-E for EIJLLPST countries that are endowed with renewable sources. Egypt could
be the main potential among EIJLLPST countries for exploiting its renewable resources (solar
and wind) for direct exports to the EU. Directive 2009/28/EC “on the promotion of the use of
energy from renewable sources” reaffirmed that “the European Council endorsed a mandatory
target of a 20 % share of energy from renewable sources in overall Community energy
consumption by 2020”. The Directive states that “the third country (i.e. non-EU member)
concerned should be encouraged by the Commission and Member States to develop a renewable
energy policy, including ambitious targets”. The updated MEDRING study identified three
issues of exporting bulk electricity from RES in EIJLLPST countries to ENTSO-E. They are (1)
weak transmission grid in SEMC and potential design constraints to accommodate large RES
production (2) complex morphology of the Mediterranean Sea and possible impact on the
technical limits of submarine cables (3) technical and design limitations to import bulk electricity
through the existing EU transmission grid at the Northern Mediterranean.

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In the medium- to long-term period, as noted above, Egypt, Jordan, and Syria are the potential
EIJLLPST countries to start preparing the synchronization schemes with ENTSO-E. There are
different scenarios for synchronizing (or asynchronizing) these countries (1) individually: for
Egypt and Syria, (2) two countries: Egypt-Jordan or Syria-Jordan, or (3) all the three countries.
Exhibit 11 depicts the possible scenarios for synchronizing these countries with ENTSO-E
associated requirements and impacts for each scenario.
    Exhibit 11 Scenarios of prospects for synchronization (or asynchrnonization) with ENTSO -E
#     Scenario                      Possible solutions           Physical Requirements                Impacts
Turkey is the interfacing system with ENTSO-E

1      Syria- ENTSO-E               Syria-Turkey - ENTSO-E       Depend on the results of             1-An assessment of converting the
                                    (HVAC and/or HVDC            Turkey’s trial Synchronization       existing HVAC to HVDC or Back-to-
                                    should be assessed)          period- one from September 2010      Back HVDC could be conducted
                                                                                                      2-if HVAC synchronization, Syrian
                                                                                                      power grid has to be isolated from
                                                                                                      neighboring countries
2      Jordan-Syria- ENTSO-E        Jordan-Syria-Turkey -        refer to scenario 1                  1-An assessment of converting the
                                    ENTSO-E                                                           existing HVAC to HVDC or Back-to-
                                    (HVAC and/or HVDC                                                 Back HVDC could be conducted
                                    should be assessed)                                               2-if HVAC synchronization, Syrian
                                                                                                      and Jordanian power grids has to
                                                                                                      isolated from neighboring countries
3      Egypt-Jordan-Syria-          Egypt-Jordan-Syria-          1-Depend on the results of           1-As described in scenarios 1 and 2.
       ENTSO-E                      Turkey-ENTSO-E               Turkey’s trial Synchronization       2-In addition to the possibility of
                                    (HVAC and/or HVDC            period- one from September 2010      permanent isolation of Egypt from
                                    should be assessed)          2-may require dedicated HVDC         Libya
                                                                 lines for RES (wind and solar)
                                                                 and/ or redesigning of existing
                                                                 transmission grid in Egypt
Libya is the interfacing system with ENTSO-E
4      Egypt-Libya-ENTSO-E           Egypt-Libya- Maghreb-       1-may require dedicated HVDC         1-HVAC synchronization with
                                     ENTSO-E                     lines for RES (wind and solar)       ENTSO-E requires isolation from
                                     (HVAC and/or HVDC           and/ or redesigning of existing      neighboring countries.
                                     should be assessed)         transmission grid in Egypt           2-Considering the high number of
                                                                 2-requires a successful              solutions, long distances between the
                                                                 synchronization of Libya with        possible interconnection countries
                                                                 ENTSO-E through Tunisia              with ENTSO-E a hybrid solution of
                                                                 3- requires upgrading the existing   HVDC and HVAC is likely to happen
                                                                 interconnection from 220kV to
                                                                 500kV at the Egyptian grid
5      Jordan-Egypt-Libya-         Jordan-Egypt-Libya            1-refer to scenario 4                Refer to scenario 4
       ENTSO-E                     Maghreb-ENTSO-E               2- may require a reinforcement of
                                   (HVAC and/or HVDC             the existing Jordan-Egypt 400kV
                                   should be assessed)           HVAC
6     Syria-Jordan-Egypt-Libya-    Syria- Jordan-Egypt-Libya
      ENTSO-E                      - Maghreb-ENTSO-E
                                   (HVAC and/or HVDC
                                   should be assessed)
Turkey and Libya are the interfacing systems with ENTSO-E

       Egypt-Jordan-Syria-          Combination of the           Refer to scenarios 1,2,3,4,5, and    Refer to scenarios 1,2,3,4,5, and 6 for
       ENTSO-E                      solutions described in all   6 for each relevant combination      each relevant combination of solutions
                                    the above scenarios          of solutions

There are three possible interconnecting countries with ENTSO-E synchronous grid; they are
Turkey, Egypt, and Libya. There is a mixture of possible solutions for synchronizing (or
asynchronizing) the three potential EIJLLPST countries with ENTSO-E through these
interconnecting countries. As Egypt, Jordan, and Syria did not initiate the process for
synchronization with the ENTSO-E, it would be feasible to consider the assessment of
interconnection with ENTSO-E through HVAC and/or HVDC solutions.



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Considering HVDC as part of the solution(s) for synchronizing with ENTSO-E would be
effective for these countries because HVDC: (1) minimizes measures for addressing stability
issues (frequency, voltage, and dynamic); (2) boosts the net transfer capacity and energy trade;
(3) strengthens weaknesses in the transmission networks; (4) brings more certainty to
interconnecting with ENTSO-E; (5) overcomes the condition that grids from neighboring
countries must be permanently isolated; (6) allows greater control over cross-border flows; and
(6) enables interconnecting synchronous areas with different operating rules. HVDC provides
safeguards while enabling most of the benefits from AC synchronization to be met. Most of the
above benefits of using HVDC were discussed in the updated MEDRING study for closing the
Mediterranean ring on the DC mode. However, for the case of synchronizing Egypt Jordan, and
Syria with ENTSO-E, broader assessment of potential hybrid solutions of HVAC and HVDC
need to be conducted to identify the technically and financially viable solutions to trade energy
produced from different generation sources (conventional and RES) in the three countries.
In summary, Egypt, Jordan, and Syria have the greatest potential among EIJLLPST countries to
start working on the synchronization process with the ENTSO-E. This would entail several
requirements to be completed by the relevant ministries and utilities. Timing for completing the
synchronization process could be envisaged around 2018-2020. For the other EIJLLPST
countries, a successful synchronization with ENTSO-E of any or all the three potential countries
would a major milestone in determining the prospects for the other countries.
Prerequisites for EIJLLPST Synchronization with ENTSO-E
Dedicated feasibility studies need to be conducted for the scenarios and possible solutions
described above. As Egypt, Jordan, and Syria are currently synchronized, a close coordination
between them should take place at an early stage to decide on the scenarios of synchronization
with ENTSO-E. Such coordination would entail the ministries of electricity and utilities
(generation and transmission) of each country to be involved. Once an agreement is reached
between the three countries, a request with a synchronization proposal could be sent to the
ENTSO-E. The following as an outline of the main prerequisites for synchronizing
Successful Synchronization of Turkey and Libya with ENTSO-E
For Turkey, the successful completion of the one year trial period of synchronization with
ENTSO-E over HVAC will determine the decision of commercial operation. Thus, the current
islanded operation between Syria and Turkey will remain until the completion of the trial period.
If Turkey starts the commercial operation with ENTSO-E, Syria has to remain connected in an
islanded-mode and cannot be synchronized with Turkey unless it fulfills ENTSO-E
requirements. This, HVDC or HVDC BtB with Turkey could be an option to assess in the
feasibility studies that could be conducted before the completion of the trial period.
As for Libya, the synchronization with the ENTSO-E could be through the Maghreb (Tunisia)
countries or any future HVDC between Libya and Northern Mediterranean countries. The failure
of synchronizing Libya and Tunisia in 2005 led to defining a certain measures as prerequisites
for the second attempt for synchronization. These measures include: Load-frequency control
improvements in Algeria and Libya, structural changes of the transmission network in Morocco
and between Algeria and Morocco, and set up the new defense plans mainly on cross-border
lines. The first measure has been completed while the remaining measures are still in progress.
Once Libya-Tunisia are successfully synchronized and passed through a minimum of one year


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trial period with ENTSO-E, an investigation could be conducted to synchronizing Libya with
Egypt could start. Other requirements and possible impacts are described earlier in exhibit 10.
Therefore, a successful synchronization of ENTOS-E with Turkey and Libya over HVAC would
determine the prospects for Egypt, Jordan, and Syria to synchronize with ENTSO-E. Thus, as
noted earlier, investigating HVDC solutions could identify the prospects for asynchronization
with ENTSO-E in a shorter period of time without the condition of successful synchronization of
ENTSO-E with Turkey and Libya.
Inevitable Technological measures
Technical measures need to be taken by Egypt, Jordan, and Syria either separately from or in line
with the scenarios and solutions for synchronization with ENTSO-E. The current operation of the
existing cross-border interconnections in EIJLLPST entails several stability issues. An
assessment would be required to identify the exact technical measures that have to be taken by
each country. It could be more effective to incorporate the assessment in the feasibility studies
for synchronization with ENTSO-E. If the three countries agreed to include the assessment of
technical measures in the feasibility studies, technical measures can be defined for each scenario
and associated solutions for synchronization. Exhibit 12 demonstrates the main assessments to
identify the technical measures to be taken by each country. The assessments would differ
according to the analyzed solutions (HVAC and/or HVDC).
 Exhibit 12required assessment to identify the technical measures for the power grids in
                               Egypt, Jordan, and Syria
   Assessment area                  Sub-criteria                             description
   Stability Analysis               Frequency stability (to manage real      Define defense plans and devices to be
                                    power)                                   installed to maintain nominal frequency in
                                                                             the case of large disturbances
                                    Voltage stability (to manage reactive    Define defense plans and devices to be
                                    power)                                   installed to maintain voltage level in the
                                                                             case of small and large disturbances
                                    Dynamic (rotor angle) stability          Define defense plans and devices to be
                                                                             installed to maintain synchronism of
                                                                             generating units (i.e. maintain
                                                                             synchronous speed) in the case of small
                                                                             and transient disturbances
   Generation capacity adequacy     Analyze the required amounts of          A consideration of 20% EU targets of
                                    generation to meet domestic demand and   imports from RES should be counted. A
                                    trade for both conventional and RES      focus should be made on efficient
                                    generation                               generation plants
   Congestion management Analysis   Power flow with bulk power export        Identify main bottlenecks of electricity
                                    between EIJLLPST countries and           trade and required reinforcements either
                                    ENTSO-E                                  by HVAC and/or HVDC. Identify any
                                                                             dedicated transmission lines for RES.




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