I7
i
CONTENTS
1.1 Installed Power Generation Capacity 05 1.2 Power Balances
05
1.2.1 NTDC System 05 1.2.2 K-Electric Limited System 06
1.3 Issues of Power Generation Additions 07 1.3.1 Capacity and
Energy Mix 07 1.3.2 Impact of Capacity Additions 09
1.4 National Electricity Policy and Plan 11 1.5 Performance of
Generation Sector 11
1.5.1 Public Sector (GENCOs and Hydel) 11 1.5.2 Private Sector
(Independent Power Producers) 13
1.6 Transmission System 13 1.6.1 Outages on NTDC Transmission Lines
(500 kV and 220 kV) 13
1.7 Overloading in DISCOs’ System 14 1.7.1 Loading Position of
Power Transformers 14 1.7.2 Loading Position of 11 kV Feeders 14
1.7.3 Loading Position of Distribution Transformers 15 1.7.4
Province-wise Loading Positions 15
1.8 Transmission and Distribution Losses of DISCOs 16 1.9 Recovery
Position of DISCOs 17
1.9.1 Recovery Position of Main Categories of Consumers 17 1.10
Performance of K-Electric Limited 18
1.10.1 Loading Position of Power Transformers, 11 kV Feeders and
Distribution Transformers 19
1.10.2 Recovery Position of K-Electric Limited 19 1.11 The
Regulation of Generation, Transmission and Distribution of Electric
Power
(Amendment) Act, 2018 20
1.11.1 Major Amendments 20 1.11.2 Challenges 20
1.12 Energy, Environment and Sustainable Development 21 1.13
Comprehensive Reduction and Elimination of Polychlorinated
Biphenyls 21 1.14 Rationalization of Generation Tariff Parameters
22 1.15 Review of Rate of Return 23 1.16 Industry – Academia
Collaboration 23 1.17 Conclusions 23 1.18 Recommendations 24
2 PERFORMANCE OF GENERATION SECTOR 29 2.1 General 29 2.2 Installed
Capacity and Electricity Generation 29 2.3 Hydropower 30
2.3.1 Power Purchase Agreements/Energy Purchase Agreements 30 2.3.2
Competitive Bidding of Hydropower Projects 30
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2.3.3 Performance Monitoring of Hydropower Projects 30 2.3.4
Implementations of Authority’s Direction 31
2.4 Overview of Public Sector GENCOs 31 2.4.1 Jamshoro Power
Company Limited 31 2.4.2 Central Power Generation Company Limited
31 2.4.3 Northern Power Generation Company Limited 32 2.4.4 Lakhra
Power Generation Company Limited 32
2.5 Independent Power Producers 32 2.6 Nuclear (CHASNUPP-I, II
& III and KANUPP) 32 2.7 Renewables 33
2.7.1 Wind 33 2.7.2 Solar 33 2.7.3 Bagasse 33 2.7.4 Bagasse/Coal
33
2.8 K-Electric Limited 33 2.9 Electricity Purchases from
SPPs/CPPs/N-CPPs 33 2.10 Future Capacity Mix 35 2.11 Performance of
Generation Facilities 35
2.11.1 Availability of GENCOs’ Power Plants 35 2.11.2 Performance
of Generation Facilities under NEPRA Performance Standards
(Generation) Rules, 2009 37
2.11.3 Performance of Independent Power Producers 39 2.11.4
Performance of K-Electric Limited 49
3 PERFORMANCE OF TRANSMISSION SECTOR 53 3.1 General 53 3.2 Power
Balances of NTDC System 53 3.3 Loading Position of NTDC’s 500 kV
and 220 kV Grid Stations 54 3.4 Constraints in NTDC System 57
3.4.1 Current Status of Interconnection Arrangements 57 3.4.2
Project-wise Cost Over-run 57 3.4.3 Commitment Charges 58
3.5 NTDC Power Evacuation Projects 59 3.6 Investment Plans of NTDC
60 3.7 Outages on Transmission Lines of NTDC (500 kV and 220 kV) 64
3.8 Power Balances of K-Electric Limited Transmission System 64 3.9
Loading Position of Power Transformers in K-Electric Limited System
64 3.10 K-Electric Limited Transmission Outage Statistics 66 3.11
NEPRA Performance Standards (Transmission) Rules, 2005 66
3.11.1 National Transmission and Despatch Company Limited 67 3.11.2
K-Electric Limited 67
4 PERFORMANCE OF DISTRIBUTION SECTOR 75 4.1 General 75 4.2 Circular
Debt 75 4.3 T&D Losses 75
4.3.1 Transmission and Distribution Losses Overall Perspective 75
4.3.2 T&D Losses (Actual) of DISCOs for FY 2015-16 and FY
2016-17 76 4.3.3 T&D Losses Requested by DISCOs and Allowed by
NEPRA (2015-16) 76 4.3.4 Re-Determination of T&D Loss Targets
77
4.4 Recovery Position of DISCOs 80 4.4.1 Recovery Position of Main
Categories of Consumers 81
4.5 Receivables of DISCOs 81
iii
4.6 Overloading in DISCOs System 83 4.6.1 Loading Position of Power
Transformers 83 4.6.2 Loading Position of 11 kV Feeders 83 4.6.3
Loading Position of Distribution Transformers 84 4.6.4
Province-wise Loading Positions 84
4.7 Fuel Price Adjustment of DISCOs 85 4.8 Status of Digitized
Mapping of Distribution Network of DISCOs and K-Electric Limited
85
4.9 Loading Position of Power Transformers, 11 kV Feeders and
Distribution Transformers in K-Electric Limited System 85
4.10 Recovery Position of K-Electric Limited 86 4.11 T&D Losses
under Multi-Year Tariff Regime 86 4.12 Investment Details of
Distribution Sector 86 4.13 Performance under NEPRA Standards
87
4.13.1 DISCOs’ Performance under NEPRA Standards 87 4.13.2
Performance of K-Electric Limited under NEPRA Standards 93
5 MONITORING OF THE SECTOR 97 5.1 General 97 5.2 Performance
Evaluation Reports of GENCOs (2012, 2013 and 2014) 98
5.2.1 Auxiliary Consumption 98 5.2.2 Standby Mode 98
5.3 Performance Evaluation Report of GENCOs (2014-15 and 2015-16)
98 5.3.1 Auxiliary Consumption 98 5.3.2 Standby Mode 99 5.3.3
Planned and Unplanned Outages 99
5.4 Performance of K-Electric Limited 99 5.5 Monitoring of
Transmission Sector 100
5.5.1 Performance Standards (Transmission) Rules, 2005 100 5.5.2
Initiation of Legal Action against NTDC for Extending Completion
Dates of
Projects 100
5.6 Monitoring of Distribution Sector 100 5.6.1 Data Analysis and
Reporting 100 5.6.2 Monitoring of Performance Standards
(Distribution) Rules, 2005 101 5.6.3 Monitoring of PESCO 102 5.6.4
Key Findings by Monitoring Teams about PESCO 105 5.6.5 Monitoring
of K-Electric Limited 106
5.7 Review of Reliability Standards of DISCOs and Linkage with
Investments 107 5.8 Initiation of Legal Proceedings against
Distribution Licensees 107
5.8.1 Legal Proceeding against the Licensees for the Violations of
the NEPRA Act, Rules and Regulations and the Applicable Documents
107
5.8.2 Inability of PESCO to Remove System Constraints of
Transmission and Distribution Network 107
5.8.3 Un-Announced and Prolonged Hours of Load-Shedding by HESCO
108 5.8.4 Un-Announced and Prolonged Hours of Load-Shedding by
K-Electric Limited 108
6 INITIATIVES BY NEPRA 111 6.1 Rationalization of Generation Tariff
Parameters 111 6.2 Review of Rate of Return 111 6.3 Energy,
Environment and Sustainable Development 111 6.4 Comprehensive
Reduction and Elimination of Polychlorinated Biphenyls 112 6.5
Formats for Submission of Information for Generation Company 113
6.6 Industry – Academia Collaboration 113 6.7 Coal Pricing – Hiring
of Consultant 113 6.8 Wind Power Generation 114
6.8.1 Competitive Bidding Tariff 114
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6.8.2 Competitive Bidding Tariff Review Motion for Wind Power
Projects 115 6.9 Solar PV Power Generation 115
6.9.1 Competitive Bidding Tariff 115 6.9.2 Competitive Bidding
Tariff Review Motion for Solar PV Power Projects 115
6.10 Tariff for Bagasse-Based Power Projects 115 6.10.1 Bagasse
Upfront Tariff, 2013 115 6.10.2 Bagasse Upfront Tariff, 2017
116
7 INITIATIVES BY STAKEHOLDERS 117
7.1 The Regulation of Generation, Transmission and Distribution of
Electric Power (Amendment) Act, 2018 119
7.1.1 NEPRA Structural and Operational Reforms 119 7.1.2 Conflict
of Interest 120 7.1.3 National Electricity Policy and Plan 120
7.1.4 Market Reforms 120 7.1.5 Tariff Determination 121 7.1.6
Appellate Tribunal 121 7.1.7 Offices of Complaints 123 7.1.8
Expansion of Regulatory Powers 123
7.2 Progress on Grid Code Review Panel 123 7.3 Progress on
Distribution Code Review Panel 123 7.4 PPIB Role, Planned
Activities, Progress and Achievements 124 7.5 AEDB efforts in
Supporting Renewable Energy Projects 126 7.6 PEDO efforts in
Supporting Hydel and Renewable Energy Projects 126 7.7 Functions of
the PPDB Board 130 8 MISCELLANEOUS 133
8.1 Summary of Activities during 2016-17 133 8.1.1 Promulgation of
New Rules/Regulations/Guidelines 133 8.1.2 Amendments in NEPRA
Rules/Regulations/Guidelines/Codes 133 8.1.3 Advisories issued by
NEPRA to the Government of Pakistan 134
8.2 Consumer Affairs 134 8.2.1 Status of Consumer Complaints
(2016-17) (Head Office) 134 8.2.2 Status of Consumer Complaints
(2016-17) (Regional Offices) 134 8.2.3 Major
Activities/Developments 135
8.3 DISCOs’ Board of Directors Meetings 135 8.3.1 Attendance of
Members and Main Agenda Items of PESCO 135 8.3.2 Attendance of
Members and Main Agenda Items of IESCO 136 8.3.3 Attendance of
Members and Main Agenda Items of GEPCO 137 8.3.4 Attendance of
Members and Main Agenda Items of FESCO 138 8.3.5 Attendance of
Members and Main Agenda Items of MEPCO 139 8.3.6 Attendance of
Members and Main Agenda Items of HESCO 139 8.3.7 Attendance of
Members and Main Agenda Items of SEPCO 140
8.4 K-Electric’s Board of Director (BODs) Meeting STATISTICAL DATA
ABOUT ENERGY AND ELECTRICITY SECTOR
9 ENERGY SECTOR OVERVIEW 143 9.1 General 143 9.2 Oil Reserves 143
9.3 Gas Reserves 143 9.4 Coal Reserves 143 9.5 Primary Energy
Supplies 143 9.6 Final Energy Consumption 145 9.7 Fuel Consumption
in Power Sector 146 10 ELECTRICITY SECTOR OVERVIEW 149
10.1 Installed Capacity 149
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10.2 Electricity Generation 154 10.3 Cost of Generation, Fuel Cost
and Fuel Consumption 161 10.4 Auxiliary Consumption and Other
Factors, Heat Rate and Plant Efficiency 167 10.5 Load Pattern and
Peak Load Hours 178 10.6 Energy Sales and Consumer-Wise Electricity
Consumption 179 10.7 Pattern of Electricity Consumption 182 10.8
Surplus/Deficit in Demand and Supply during Peak Hours 183 11
ELECTRICITY GENERATION 187
11.1 General 187 11.2 Thermal Power Generation 187 11.3 Thermal
Power Generation and Fuel Consumption 187 11.4 Hydel Power
Generation 188 11.5 Nuclear Power Generation 190 11.6 Renewable
Energy Generation (Wind, Solar and Bagasse) 190 11.7 Investment
Plan for Power Generation Projects 191 11.8 Economic Load Despatch
System 197 11.9 Licenses Granted 199 12 ELECTRICITY TRANSMISSION
211
12.1 General 211 12.2 Transmission Lines and Grid Stations with
NTDC 211 12.3 Transmission Losses 212 12.4 Utilization of
Transmission Lines and Power Transformers 212 12.5 Transmission
Lines Tripping in PEPCO System 212 12.6 Loading Position of NTDC’s
500 kV and 220 kV Grid Stations 213 12.7 Investment Plan - NTDC
System 216 12.8 Transmission Lines and Grid Stations with
K-Electric 218 12.9 Transmission Lines Tripping in K-Electric
System 219 13 ELECTRICITY DISTRIBUTION 223
13.1 General 223 13.2 Role of Distribution Companies 224 13.3
Distribution System Performance 235 14 ELECTRICITY TARIFF 251
14.1 General 251 14.2 Tariff Setting 251 14.3 Tariff Standards
251
List of Tables 281 Acronyms and Abbreviations 284 Source of
Information 287
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1
FOREWORD
The generation sector of Pakistan has witnessed a major
transformation over the last five years (2013-2018), by moving
towards a reliable supply system through large base-load power
plants using indigenous and imported coal and through highly
efficient gas-based plants. A number of large hydropower plants
have also achieved completion, whereas till date around 1,500 MW of
solar and wind power plants, have also been inducted to encourage
clean energy. Furnace Oil-based power generation plants which
remained face of Pakistan power sector for over three decades, have
been planned to be phased out over next few years and it is
expected that the share of furnace oil-based energy will decline
from around 30% to a negligible level in the overall mix in the
coming years.
The challenges however, are immense, the addition of generation
facilities have put added pressure for a strong transmission and
distribution infrastructure to make the delivery of electricity to
end-consumers possible. Over the years, the regulator has been
stressing the need for strong and robust networks for a reliable
power supply, however it is the concerted and urgent efforts of
National Transmission and Despatch Company Limited (NTDC) and
Distribution Companies (DISCOs) which can ensure sustainable
reliable power supply to end-consumers.
Taking a holistic view of the transmission and distribution
sectors, it is noted that (39%)1 transformers at 500/220 kV level
were loaded above 80% of their rated capacity on June, 2017. At
220/132 kV level, (55%)2 transformers are overloaded. In
distribution sector, at the end of June 2017, about 37% of high
capacity transformers (power transformers) were over-loaded (above
80% of their capacity). Similarly 29% of the 11 kV feeders, used
for bulk transmission of electricity at distribution level, were
found over-loaded, whereas more than 12% of the distribution
transformers are loaded above 80% of their capacity. It is also
noted that on an overall basis, the overloading of equipment has
slightly improved over the last year i.e. 2015-16 when the supply
of electricity was constrained. With more supply available now, the
system is expected to also meet the suppressed demand, which was
not connected to the network earlier. Therefore a routine
historical pace of improvement and refurbishment in network would
not ensure provision of a reliable electricity supply to
consumers.
The DISCOs on one hand, would have to strive to strengthen their
network for providing reliable electricity supply, whereas on the
other, they would be pressed to increase their energy sales, so
that overall impact of increased capacity payments, due to
additional generation capacity is neutralized, through increased
energy sold, and the consumer-end tariff remains at affordable
level.
Over the years the transmission and distribution losses could not
be curtailed by the DISCOs and having taken divergent and
contradictory positions about losses, almost all the DISCOs have
now proposed new and higher loss levels than earlier requested. It
is a matter of concern that DISCOs could not take such measures to
bring improvement in this critical area. Ministry of Energy (Power
Division) is also required to assign due priority to this major
impediment in sustainability of the power sector in Pakistan. It
may be noted that all efforts to bring efficiency in the sector
would be defeated if the DISCOs do not improve their Transmission
and Distribution (T&D) loss position.
The Regulator has noted inconsistent positions of the Ministry of
Energy (Power Division), especially 1 13 out of 33 2 79 out of
143
2
in respect of introduction of renewable energy based generation
facilities including wind, solar and small hydropower plants. For
fuel diversity and reducing dependence on imported fuels, the
Ministry of Energy is required to be consistent for achieving
overall objectives outlined in policies of the Federal
Government.
Recently approved Amendment Act, 2018 has brought major changes in
the existing regulatory regime. The distribution function has been
separated into wire and sale businesses. In addition concepts of
“trader” and “supplier” have been introduced which are entirely new
for all the stakeholders. The Federal Government has also enhanced
its role in policy and rule making for the regulator. The Amendment
Act, 2018 provides for a major shift from the existing regime and
it is observed that extensive discussions and consultations among
stakeholders are required to identify gaps and resolve issues for
making smooth transition to the new regime.
It is also noted that a number of entities with very specific roles
have been defined in the Amendment Act. It appears that these
entities are not well prepared to take over their assigned roles as
human resource readiness, software and hardware availability and
other skills essential for such roles are not available. It is
urged to initiate dialogue at all levels to make regulatory regime
through Amendment Act a success.
STATE OF INDUSTRY REPORT 2017
EXECUTIVE SUMMARY
EXECUTIVE SUMMARY
Over the past few years the policy makers in Pakistan have
recognized it and made concerted efforts for development in the
power sector in general and generation sector in particular.
Sufficient generation capacity has already been added in the system
resulting in considerable improvement in load-shedding position all
over the country. As per records, further generation capacity at
different stages of implementation, will also be added over the
next three years, (leading to a capacity surplus scenario in view
of the available demand forecasts). Evacuation of power from these
facilities has put extra burden on transmission and distribution
sectors. Infrastructure deficit and absence of performance
improvement in these sectors may hamper the economic benefits
foreseen due to huge investment in the generation facilities.
1.1 INSTALLED POWER GENERATION CAPACITY Installed power generation
capacity of Pakistan as of 30th June, 2017 stands at 28,399 MW of
which 26,186 MW is connected with NTDC system whereas 2,213 MW is
connected with K-Electric Limited (KEL) system. Since 2013 till
date, more than 7,000 MW has been added to the generation
facilities connected to NTDC system. Based on recent information by
NTDC, and analysis by NEPRA, generation capacity additions in NTDC
system over a period up to the FY 2024-25 are as shown in the
following table. It may be noted that the final installed capacity
of more than 62,000 MW may not be achieved as some of the power
projects including hydro-based projects indicated to be inducted
from 2022 to 2025 require extensive technical and financial
prerequisites to complete.
NTDC System (MW)
2017
ADDITIONS
2017-18 2018-19 2019-20 2020-21 2021-22 2022-23 2023-24 2024-25
Total*
Oil 6,785 0 0 0 0 0 0 0 0 0 Coal 810 1,980 1,320 823 3,300 2,610
1,320 0 0 11,353
Gas/RLNG 8,868 2,508 830 420 0 0 0 0 0 3,758 Wind 785 149 299 0
1,224 0 0 0 0 1,672 Solar 400 12 600 600 0 0 0 0 0 1,212
Bagasse 280 77 583 144 0 0 0 0 0 804 Hydro 7,116 2,709 41 201 177
824 3,080 4,325 2,203 13,560
Nuclear 1,142 340 0 0 1,100 1,100 0 0 1,100 3,640 Year-wise
Addition --- 7,775 3,673 2,188 5,801 4,534 4,400 4,325 3,303
35,999
Total Cap. after Additions
26,186 33,961 37,634 39,822 45,623 50,157 54,557 58,882 62,185
62,185
* Technology-wise Installed Capacity Additions from FY 2017-18 till
FY 2024-25 Note: Import not shown of 1,000 MW CASA in year 2021-22
and 96 MW existing from Iran. Source: NTDC
1.2 POWER BALANCES
1.2.1 NTDC System: The generation capability of generation
facilities connected with NTDC system will be less than the
installed capacity as shown in the above table due to various
factors like auxiliary consumption, impact of site reference
conditions and seasonality effects on the renewables and large
hydropower plants. The generation capability is effectively the
capacity for meeting the electricity demand in
01
6
NTDC system. The data about generation capability and future demand
as reported by NTDC is shown in the following table. It may be
noted that sufficient generation capability would be available in
the NTDC system to meet future demand at peak times representing
power surplus scenario. It is also to be noted that the capacity
surplus in the later years i.e. 2022 to 2025 may not be available
due to multiple issues and resulting uncertainties in completion of
large hydro-based power projects.
Year ending 30th June
NTDC (MW)
Rate (%)
Hours (MW)
Surplus/ Deficit (MW)
2018 33,961 26,135 4.51 25,227 908 2019 37,633 28,357 4.44 26,348
2,009 2020 39,821 29,314 4.07 27,420 1,894 2021 45,622 34,124 4.31
28,601 5,523 2022 50,156 36,422 4.27 29,822 6,600 2023 54,556
39,345 4.27 31,095 8,250 2024 58,881 41,197 4.29 32,429 8,768 2025
62,184 47,750 4.28 33,816 13,934
Source: NTDC
1.2.2 K-Electric Limited System: Following table shows power supply
and demand position in KEL system based on the investment plans of
KEL. It may be noted that till 2020, KEL can barely meet the
expected demand at peak times and outage of a power plant or even,
outage of a single unit of around 200 MW may result in overall
breakdown of the system. Even the surplus expected in 2021 would
not be enough to operate KEL system with technically prudent
margins:
Year Ending 30th June
KEL (MW)
Rate (%)
Peak hours (MW)
Surplus/ (Deficit) (MW)
2018 3,590 3,046 5.00 3,435 -389 2019 4,430 3,833 5.00 3,601 232
2020 4,520 3,978 5.00 3,791 187 2021 5,220 4,615 6.00 4,011
604
Source: KEL
1.3 ISSUES OF POWER GENERATION ADDITIONS
1.3.1 Capacity and Energy Mix: The Government of Pakistan has been
pursuing broad objectives for the power generation development
including, renewable energy, moving to environmental friendly fuels
and reduced dependence on imported fuels. Also diversification of
fuel resources and security of fuel supply were among its
priorities. The addition of different new generation technologies
shown above will change the power mix of the sector from Furnace
Oil-based to Coal, RLNG and Renewables as no major addition has
been planned on Furnace Oil. The following table shows changes in
installed capacity mix over three representative periods.
Fuel Up to 30th June, 2017 Up to 30th June, 2021 Up to 30th June,
2025
Capacity Mix (MW)
Capacity Mix (%)
Gas/RLNG 8,868 33.87 12,626 27.68 12,626 20.30 Oil 6,785 25.91
6,785 14.87 6,785 10.91
Coal 810 3.09 8,232 18.04 12,163 19.56 Hydro 7,116 27.17 10,244
22.45 20,676* 33.25
Nuclear 1,142 4.36 2,582 5.66 4,782 7.69 Renewables
(Solar/ Wind/ Bagasse)
1,465 5.59 5,153 11.29 5,153 8.29
Total 26,186 100.00 45,622 100.00 62,185 100.00 * Slippage in
hydropower projects may delay some of these. Source: NTDC
Clear trends may be noted in respect of different fuels. In the FY
2016-17 about 9,000 MW is based on Gas/RLNG, which increases to
12,626 MW by the FY 2020-21, however no further addition is
foreseen till the FY 2024-25. Oil based power generation plants
have not been planned throughout the period and share of oil based
generation capacity declines from 25.91% in the FY 2016-17 to
10.91% in the FY 2024-25. Share of coal-based generation increases
from 3.09% in the FY 2016- 17 to 19.56% in the FY 2024-25 mainly on
Thar Coal based projects. Hydro-based generation capacity also
increases from about 7,000 MW in the FY 2016-17 to 20,676 MW in the
FY 2024-25 representing a share of more than 33% in the overall
installed generation capacity.
Regarding future energy pattern, based on future projections, it is
expected that the energy from Furnace Oil and High Speed Diesel
based power plants will reduce from around 32,000 GWh in the FY
2016-17 representing about 31% of the energy generation in NTDC
system, to around 17,000 GWh in the FY 2017-18 (14% of the total)
to a negligible level in the coming years. Indigenous gas and LNG
based energy though a fossil fuel, however being a relatively clean
fuel, is expected to account for around 40% of total energy
generated in the FY 2019-20 compared to 29% in the FY
2016-17.
1.3.1.1 Induction of Renewable Energy: Although prices of solar and
wind technologies have plummeted over the pasts years, the growth
of generation facilities based on these has not been witnessed as
expected. The generation plans over next three years also, do not
include major additions of solar and wind. Initially some technical
issues like absence of relevant studies required to establish
limits for the induction of wind and solar generation facilities
for a safe and reliable operation of the overall National Grid,
prevented their development on a large scale. Lately however, the
Ministry of Energy (Power Division) could not provide a clear
policy about the induction of renewable energy based projects,
although a number of solar and wind based power generation projects
had completed all procedural
8
requirements for implementation.
Similarly small hydropower plants which also represent a renewable
energy based source, could not be built as the Ministry of Energy
(Power Division) did not provide a clear policy about their
induction. Barring a number of issues like continuity of power
supply throughout the year in case of small hydropower generation
plants and intermittent nature of power supply in case of wind and
solar, the advantages of these technologies make them the priority
source of power generation in the long term scenario of any country
in the world. These not only provide clean energy but help in fuel
security while reducing dependence on imported fuels. Small
hydropower plants may appear to be relatively expensive than solar
and wind at this stage, however their economic and financial
benefits are far greater if their extremely long operational life
is considered in the analysis.
In order to encourage renewable energy while also capturing the
benefits of declining prices of wind and solar, NEPRA announced a
series of upfront tariff rounds, which allowed shorter processing
times for the development of projects in addition to lower tariffs,
consistent with the international trends. To have more attractive
tariffs for the sector, lately, NEPRA has recommended to follow
competitive bidding regime, which has been successfully used in
different countries to have most competitive prices. In this
respect, the role of Alternative Energy Development Board (AEDB)
has become extremely important as being the relevant agency under
the Ministry of Energy for the development of renewable energy
projects. AEDB was required and it publically made a commitment to
develop detailed documents including Request for Proposal (RFP) for
facilitating competitive bidding for inducting renewable energy
based projects. After a lapse of more than year and a half,
however, AEDB has not been able to come up with these documents,
thus creating an overall uncertainty in the sector specifically for
prospective investors in the renewable energy. The Ministry of
Energy (Power Division) is therefore urged to take a clear and
consistent policy about the induction of solar, wind and small
hydropower projects. Accordingly, AEDB should initiate schedule for
competitive bidding in solar and wind power projects at the
earliest.
NEPRA has notified multiple tariffs under the NEPRA Up-front Tariff
(Approval and Procedure) Regulations 2011, including upfront
tariffs for Bagasse and Small Hydropower Generation Plants for
providing an incentivized regime for clean power technologies.
However, the CPPA-G as sole procurer of power on behalf of DISCOs,
has in various cases refused to grant authorization for projects
being implemented under tariffs and licences granted by the
regulator. Moreover, the CPPA-G has continually acted in an ad-hoc
and discriminatory manner towards various IPPs and other power
projects. Ministry of Energy (Power Division) is therefore required
to streamline internal functioning of CPPA-G on these
matters.
1.3.1.2 Dynamics of Fuel: Fuel used for power generation plays a
critical role as the availability of power generation facilities is
directly linked to the fuel availability and its price in the
international market. The exchange rate also impacts the overall
price of fuel and ultimately the consumer-end tariff as fuel price
is treated as a pass through component in final tariff. In medium
term, National Power Policy 2013, focused on reducing the basket
price through cheaper fuels and addition of affordable and
sustainable power generation to the grid. Reducing country’s
reliance on imported oil has been another broad objective. For
achieving these objectives, indigenous coal through Thar mining,
imported coal, LNG based power plants, nuclear, solar and wind
power are under implementation. It is expected that dependence on
furnace oil will sharply come down. In order to reduce dependence
on imported fuels, the Federal Government has decided to put a cap
on the power generation plants based on imported coal. On similar
lines, although LNG is a cleaner fuel, the Federal Government may
look
9
into replacing it by construction of large and small hydropower
projects through public-private partnership. A preliminary working
shows that any slippage of 1 Rupee against US$ would add, roughly
Rs. 4 billion annually, to the imported fuel bill for the planned
generation facilities in near future.
1.3.2 Impact of Capacity Additions: From an overall perspective,
addition of new power generation capacity to reduce and totally
eliminate power shortages in the country makes economic sense, as
the unserved energy impacts negatively to the economy of the
country as a whole. At the same time however, one must be cognizant
of different issues which also need to be addressed simultaneously,
to optimize benefits of additional energy supply to the sector. It
is noted that the Federal Government efforts to lower the overall
consumer-end tariff may suffer if in addition to lowering fuel
costs, the capacity cost is not kept at an affordable level.
1.3.2.1 Adequacy of Transmission System: According to the
information by NTDC, its transformation capacity of 18,624 MVA at
500 kV level at June, 2017 is expected to increase to 21,150 MVA by
June, 2018. NTDC plans to add another 11,700 MVA over next four
years. At 220 kV level NTDC plans to add more than 21,000 MVA over
the June, 2017 level of 25,660 MVA. The adequacy of transmission
system is mainly dependent on the 220 kV level transformation
capacity as it is the interconnection voltage level between NTDC
and DISCOs. It may be noted that by May and June 2018, the
transmission system will be sufficient at the margin to meet demand
at the peak time. Therefore transmission congestions may be
experienced in certain pockets of the system. However it is
important that NTDC meets its project schedules and delays are not
encountered. Addition of matching transmission lines are also
critical for the evacuation of upcoming generation projects, as
prudent utility practices and criteria are required to be followed
for a reliable transmission network. NTDC is advised to ensure
implementation of its transmission line projects according to the
scheduled dates.
Year Transformation Capacity (500 kV) Transformation Capacity (220
kV) (MVA) (MW) (MVA) (MW)
January, 2018 19,650 16,703 26,880 22,848 2017-18 21,150 17,978
29,810 25,339 2018-19 22,950 19,508 34,180 29,053 2019-20 22,950
19,508 39,490 33,567 2020-21 26,850 22,823 41,980 35,683 2021-22
32,850 27,923 46,980 39,933
Source: NTDC
10
The transformation capacity of NTDC system at 220 kV level is
charted against the projected demand of NTDC system as shown here.
The planned transformation capacity would be adequate over next
four year forecast, to pass the demand of the system if the planned
implementation schedules of different projects are met.
1.3.2.2 Capacity Payments: An analysis, only for the capacity
payments corresponding to generation facilities in NTDC system,
shows that such payments which were around Rs. 280 billion in the
FY 2015-16 and reached more than Rs. 350 billion in the FY 2016-17,
would be close to Rs. 490 billion in the FY 2017-18. A preliminary
working in relation to the energy sold, after addition of new power
generation plants, shows that capacity cost per unit of energy sold
which was slightly higher than Rs. 3.4 in the FY 2015-16 would be
around Rs. 4.1 in the FY 2016-17; an increase of Rs. 0.7/unit
corresponding to a 6.2% growth in energy sold in the FY 2016-17
over the FY 2015-16. For the first six months of the FY 2017-18, a
growth in energy sold of more than 12.31% over the same period of
the FY 2016-17 has been recorded. It is however noted that this
growth rate would not be enough to keep the capacity cost component
at the same level i.e. Rs. 4.1, as the expected cost components
would be close to Rs. 5/unit. In order to keep the capacity cost
component at the FY 2016-17 level, the energy sold would be
required to increase by at least 30% from the FY 2017-18 to the FY
2018-19. Further analysis shows that in order to keep the capacity
payment per unit of energy sold, at the level of the FY 2015-16, at
least 57% increase in energy sold would be required in the FY 2018-
19 over the FY 2017-18. It is understood that the suppressed demand
would also be connected to the system as the electricity is made
available, however, in all likelihood, an increase of more than 30%
will not be achievable. Various factors including the presence of
high loss feeders, in foreseeable future would not let the energy
sold, to be increased beyond say 9% to 10% annually, over coming
years. With such level of increases in energy sold, the capacity
payment close to Rs. 5/unit of energy sold may be expected making
the overall energy cost expensive, necessitating increased
sustained efforts for cheaper fuels to keep overall tariff at
affordable levels.
1.3.2.3 Need for Increasing Energy Sold: Since increasing the level
of energy sold is the most critical parameter which can impact
positively on the capacity cost per unit sold, therefore all
possible means should be explored in this respect. It is noted that
power is not supplied by DISCOs to consumers due to multiple
reasons including constraints in the transmission and distribution
systems, non-availability of generation due to fuel constraints and
other unspecified factors. In addition the Ministry of Energy
(Power Division) as a policy has decided not to supply electricity
on high-loss feeders which add to the overall load being shed. It
is therefore required to address these factors on war-footing for
improvement in the system, so that, additional energy is made
available through the same power generation capacity.
11
1.3.2.4 Need for Local Manufacturing for Power Sector Equipment:
Pakistan as a country has become a consumer market, and it is also
true for power sector machinery and equipment, all of which is
invariably imported. Although recently there have been a number of
very attractive low cost agreements for power equipment,
specifically for RLNG based projects, overall it has been noted to
be a supplier’s choice. In order to lower the overall cost of power
sector, it is imperative that plant and machinery in generation,
transmission and distribution sectors is acquired at competitive
prices, prevalent in the regional countries like India. Over the
years, local manufacturing of power sector plant and machinery has
remained as a low priority for the policy makers. It is however
stressed that in order to have affordable consumer-end tariffs,
local manufacturing of all major equipment used in power sector be
undertaken. Steps in this respect be initiated forthwith.
1.4 NATIONAL ELECTRICITY POLICY AND PLAN The Federal Government has
rightly decided to formulate an overall National Electricity Policy
and National Electricity Plan for future development of electricity
generation, transmission and distribution sectors. The National
Electricity Policy would also provide road map for the market
structure. The Authority considers that formulation of National
Electricity Plans should be a regular activity by relevant
agencies, as the plans should be evolving and reflect technological
and financial changes in the sector. The Authority also notes that
National Electricity Plans should be adopted in letter and spirit
as earlier such plans, though quite comprehensive, were never
formed the basis of power sector development. Consequently roller
coaster development of sector continued as occasional surpluses and
long periods of electricity shortages were witnessed.
1.5 PERFORMANCE OF GENERATION SECTOR
1.5.1 Public Sector (GENCOs and Hydel):
1.5.1.1 Jamshoro Power Company Limited (GENCO-I): The energy
generated by GENCO-I during the FY 2016-17 was 3,593 GWh, while, it
was 3,828 GWh in the FY 2015-16; a decrease of 235 GWh or 6.14%,
over last year. Net efficiency of GENCO-I during 2016-17 stood at
28.42% for TPS Jamshoro and 27.05% for GTPS Kotri. With a capacity
utilization of 58.04% for TPS Jamshoro and 33.51% for GTPS Kotri
due to forced outages and various maintenance issues, the overall
performance of GENCO-I has not been satisfactory.
1.5.1.2 Central Power Generation Company Limited (GENCO-II): Total
installed capacity of GENCO-II, up to 30th June, 2017 has been
noted as 2,402 MW. No new generation plant was inducted during the
year under review for GENCO-II. The energy generated by GENCO-II
during the FY 2016-17 has been recorded at 8,079 GWh, while, it was
6,031 GWh during the FY 2015-16; an increase of 33.97%, compared
with that of the last year. It is observed that various units of
GENCO-II have remained off-bar for several years due to maintenance
issues, forced outages, fuel constraints and rehabilitation
activities etc. and are not being fully utilized. With reduced
annual efficiency and reduced capacity utilization factor, the
overall performance of GENCO-II has been unsatisfactory.
1.5.1.3 Northern Power Generation Company Limited (GENCO-III):
Total installed capacity of GENCO-III, up to 30th June, 2017 has
been noted as 2,293 MW. During the FY 2016-17, the installed
capacity of GENCO-III remained same as compared with that of the
year 2015-16. The energy generated by GENCO-III during the FY
2016-17 was 6,861 GWh, while
12
it was 6,273 GWh during the FY 2015-16 showing an increase of 588
GWh or 9.37%, compared with the last year. It is observed that the
overall net efficiency of TPS Muzaffargarh, SPS Faisalabad, GTPS
Faisalabad and Nandipur remained very low. Reportedly, due to
various maintenance issues, forced outages and fuel constraints
etc. resulting in annual capacity utilization of 48.21% for TPS
Muzaffargarh, 14.52% for SPS Faisalabad, 12.27% for GTPS Faisalabad
and 38.52% for Nandipur Power Plant, the overall performance of
GENCO-III cannot be termed as satisfactory.
1.5.1.4 Lakhra Power Generation Company Limited (GENCO-IV): Total
installed capacity of GENCO-IV, up to 30th June, 2017 has been
noted as 150 MW. GENCO-IV had three units of 50 MW and during the
FY 2016-17, generated 124 GWh as compared to 148 GWh produced
during the FY 2015-16. It may be noted that, against the installed
capacity of 150 MW, approximately, two third capacity of GENCO-IV
is available for generation, which is also not being fully utilized
due to forced outages etc. With utilization factor of 22.68% for
the FY 2016-17, the overall performance of GENCO-IV has remained
unsatisfactory.
As a whole GENCOs continued to operate at very low efficiencies
than their design values, mostly on expensive furnace oil. It is
also noted that these power plants are also not being operated
according to prudent utility practices. GENCOs have low utilization
factors and have also been operated in standby mode, where they
incur costs without contributing energy to the National Grid, as
they are ranked very low in the dispatch merit order. It is noted
that during the FY 2016-17 about Rs. 39 billion has been paid to
GENCOs on account of capacity payments, while around Rs. 156
billion were charged on account of energy payments. Ministry of
Energy (Power Division) is therefore urged to phase out these
facilities in view of their inefficient and uneconomic role in the
sector. Due to their high operating costs, some of these plants may
be totally closed down even if their capacity costs are continued
to be paid, to minimize economic loss to the sector.
1.5.1.5 Hydropower: The installed capacity of WAPDA Hydropower
remained at 6,902 MW in the years 2015, 2016 and 2017; however, the
31,091 GWh generated in the FY 2016-17, shows a decrease of 2,342
GWh from the last year. The decrease in energy production may be
attributed to water availability and irrigation releases from large
reservoir based power plants. Similarly, the Hydel IPPs also
contributed 133 GWh less in the system during the FY 2016-17 with
the same installed capacity as in the FY 2015-16. As for
performance of major public sector hydropower plants including
Tarbela, and Mangla, that is comparable with international
standards of efficiency, availability and auxiliary consumption
levels. The hydropower energy production pattern over the year
remained consistent with the historical trends.
1.5.1.5.1 Power Purchase Agreements/Energy Purchase Agreements:
NEPRA has approved the PPAs of two large hydropower projects under
Section 5 of “NEPRA Interim Power Procurement (Procedure and
Standards) Regulations, 2005”. Details of these projects are given
below:
S. No. Project Name Capacity (MW) Power Purchaser 1 Karot
Hydropower Project 720 CPPA-G 2 Suki Kinari Hydropower Project 870
CPPA-G
1.5.1.5.2 Competitive Bidding of Hydropower Projects: NEPRA has
approved the Request for Proposal (RFP) of Taunsa Hydropower
Project and six other projects identified by PEDO under the
Competitive Bidding Tariff (Approval Procedure) Regulations
13
(CBTR), 2014. Subsequently, the bidding under CBTR-2014 for Taunsa
Hydropower Project was successfully completed and the Authority has
accordingly notified the lowest successful bidder. This was the
first power generation project whose tariff has been determined
through Competitive Bidding in Pakistan’s power sector.
1.5.1.5.3 Performance Monitoring of Hydropower Projects: The
monitoring of different hydropower projects was carried out in the
year 2017 to check their performance according to the terms and
conditions set in Licence, PPA, Tariff Determination and other
relevant rules and regulations.
NEPRA has noted the unsatisfactory performance of Malakand-III (81
MW), Jinnah (96 MW) and Khan Khwar (72 MW) Hydropower Plants. The
sponsors and the power purchaser have been directed to improve the
operation and maintenance of these plants.
1.5.1.5.4 Implementations of Authority’s Directions: The Authority
noted that a number of holders of LOIs for hydropower project sites
were inordinately delaying the development of these sites.
Accordingly, directions were issued to the relevant agencies to
cancel all those LOI/LOS of projects which have been inordinately
delayed by the sponsors. As a result, a number of LOIs and LOSs of
hydropower sites were cancelled by implementing agencies and the
process for their speedy development was initiated. These include
the following large hydropower projects:
S. No. Project Name Capacity (MW)
1 Sehara Hydropower Project 130 2 Madian Hydropower Project 157 3
Asrit Kedam Hydropower Project 215 4 Chakothi Hattian Hydropower
Project 500
Advisories were also issued to CPPA-G/Power Purchaser to expedite
process of implementation of small hydropower projects and signing
of PPAs. 1.5.2 Private Sector (Independent Power Producers):
Performance of thermal Independent Power Producers (IPPs) remained
satisfactory during the FY 2016-17, with respect to the NEPRA
Performance Standards (Generation) Rules, 2009. Further details may
be found in subsequent chapters of the report.
1.6 TRANSMISSION SYSTEM As of 30th June 2017, NTDC is maintaining
14 (fourteen) 500 kV grid stations with a transformation capacity
of 18,624 MVA. There are 33 (thirty three) 500/220 kV transformers
and 35 (thirty five) 220/132 kV transformers installed at these
grid stations. At 220 kV level there are 38 grid stations with a
transformation capacity of 25,660 MVA. There are 108 (one hundred
eight) 220/132 kV transformers installed at 220 kV grid
stations.
Out of 33 transformers at 500/220 kV level, 13 transformers (39%)
are loaded above 80% of their rated capacity. Similarly, out of 143
(one hundred forty three) 220/132 kV transformers, 79 transformers
are overloaded, representing around 55% overloading in the
system.
1.6.1 Outages on NTDC Transmission Lines (500 kV and 220 kV): As
reported by NTDC the number of planned and unplanned outages in the
FY 2016-17 have increased as compared to the FY 2015-16 at 500 kV
and 220 kV levels. As for duration of outages
14
the total duration of planned outages increased in the FY 2016-17
as compared to the FY 2015-16, for both 500 kV and 220 kV levels.
For unplanned or forced outages, the total duration reduced in the
FY 2016-17 compared to the FY 2015-16:
Ye ar Description
Planned Outages Forced Outages 500 kV 220 kV 500 kV 220 kV
20 15
Total duration in minutes 275191 406952 1885661 243431
Maximum duration of any single outage (Minutes) 10289 1057 133045
61028
20 16
Total duration in minutes 286623 498620 29463 141619
Maximum duration of any single outage (Minutes) 16019 15285 2935
12833
Source: NTDC
1.7 OVERLOADING IN DISCOs’ SYSTEM Power delivery through DISCOs’
networks mainly depends on the adequacy of three major components
including power transformers (mostly 132/11 kV transformers), 11 kV
feeders and finally the distribution transformers. The following
tables provide a comparison of overloaded components in all DISCOs
for the FY 2015-16 and the FY 2016-17.
1.7.1 Loading Position of Power Transformers: On an overall country
basis overloading on power transformers has slightly reduced in the
FY 2016- 17 from that of the FY 2015-16 but it is still very high,
as 36.82% of the total power transformers in the DISCOs are
overloaded, pointing to potential problems. On DISCO to DISCO
comparison, FESCO and QESCO have more than their 50% power
transformers overloaded above 80%, followed by HESCO, PESCO and
SEPCO having more than 40% of their transformers overloaded.
DISCO Total No. of Power
Transformers* Total No. of Over-Loaded Power
Transformers (above 80%) Percentage of Total Over-Loaded Power
Transformers (above 80%)
2015-16 2016-17 2015-16 2016-17 2015-16 2016-17 PESCO 220 230 124
113 56.36 49.13 TESCO 35 38 14 13 40.00 34.21 IESCO 194 202 37 24
19.07 11.88 GEPCO 154 160 63 34 40.91 21.25 LESCO 333 351 151 127
45.35 36.18 FESCO 188 195 107 100 56.91 51.28 MEPCO 269 282 118 75
43.87 26.60 HESCO 109 119 74 59 67.89 49.58 SEPCO 116 118 33 53
28.45 44.92 QESCO 125 133 66 75 52.80 56.39 Total 1,743 1,828 787
673 45.15 36.82
* Power Transformers include 132 kV, 66 kV and 33 kV voltage level.
Source: DISCOs
1.7.2 Loading Position of 11 kV Feeders: Country-wise overloading
on 11 kV feeders has slightly increased, as 29.00% of the total
feeders are loaded above 80% compared to 28.14% last year. On DISCO
level, PESCO and TESCO have the highest percentage (more than 50%)
of overloaded feeders, followed by QESCO, SEPCO, MEPCO and LESCO
(more than 30%).
15
Feeders Total No. of Over-Loaded
11 kV Feeders (above 80%) Percentage of Total Over-Loaded
11 kV Feeders (above 80%) 2015-16 2016-17 2015-16 2016-17 2015-16
2016-17
PESCO 907 946 396 485 43.66 51.27 TESCO 195 203 174 191 89.23 94.09
IESCO 1,036 1,058 72 27 6.95 2.55 GEPCO 779 805 167 88 21.44 10.93
LESCO 1,580 1,650 350 548 22.15 33.21 FESCO 936 998 189 159 20.19
15.93 MEPCO 1,165 1,241 428 433 36.74 34.89 HESCO 435 463 103 121
23.68 26.13 SEPCO 453 462 179 167 39.51 36.15 QESCO 613 628 221 233
36.05 37.10 Total 8,099 8,454 2,279 2,452 28.14 29.00
Source: DISCOs
1.7.3 Loading Position of Distribution Transformers: Overloading of
distribution transformers in case of LESCO at 30.13% is the highest
among DISCOs, followed by PESCO and SEPCO.
DISCO
Total No. of Over-Loaded Distribution Transformers
(above 80%)
Percentage of Total Over-Loaded Distribution Transformers (above
80%)
2015-16 2016-17 2015-16 2016-17 2015-16 2016-17 PESCO 60,365 72,078
19,311 21,033 31.99 29.18 TESCO 15,634 16,612 174 191 1.11 1.15
IESCO 45,438 46,359 3,105 2,868 6.83 6.19 GEPCO 60,080 61,661 1,548
1,475 2.58 2.39 LESCO 97,048 100,718 41,952 30,350 43.23 30.13
FESCO 97,761 100,276 3,285 1,843 3.36 1.84 MEPCO 152,806 156,460
7,105 8,128 4.65 5.19 HESCO 35,334 35,996 8,336 3,340 23.59 9.28
SEPCO 35,029 35,875 6,443 7,424 18.39 20.69 QESCO 53,646 55,770
8,743 8,873 16.30 15.91 Total 653,141 681,805 100,002 85,525 15.31
12.54
Source: DISCOs
From above it is noted that although PESCO, SEPCO, TESCO and QESCO
have generally been accepted as those DISCOs, which have
consistently shown poor performance levels, what is more worrying
however, is that according to the above statistics, the so called
better performers like LESCO and MEPCO have a poor record for 11 kV
overloaded feeders. LESCO has the worst record of overloading of
distribution transformers. Similarly FESCO has very serious issues
to tackle with the overloading of its power transformers.
Considering the share of these DISCOs in the overall energy
consumption, further delays in overcoming these issues will be
disastrous for the power sector.
1.7.4 Province-wise Loading Positions: Province-wise statistics of
overloading position (above 80%) for June, 2017 is shown in the
following table:
Description Punjab Sindh Khyber Pakhtunkhwa Balochistan Total
No. of 132 kV Grid Stations (including consumer owned) 490 120 86
64 760
Total No. of Power Transformers* 1,190 237 268 133 1,828
16
Over-Loaded Power Transformers (Nos.)* 360 112 126 75 673
Over-Loaded Power Transformers (%)* 30.25 47.26 47.01 56.39 36.82
Total No. of 11 kV Feeders 5,752 925 1,149 628 8,454 Over-loaded 11
kV Feeders (Nos.) 1,255 288 676 233 2,452 Over-loaded 11 kV Feeders
(%) 21.82 31.13 58.83 37.10 29.00 Total No. of Distribution
Transformers 465,474 71,871 88,690 55,770 681,805 Over-loaded
Distribution Transformers (Nos.) 44,664 10,764 21,224 8,873 85,525
Over-loaded Distribution Transformers (%) 9.60 14.98 23.93 15.91
12.54
* Power Transformers include 132 kV, 66 kV and 33 kV voltage level.
Source: DISCOs
1.8 TRANSMISSION AND DISTRIBUTION LOSSES OF DISCOs The following
table gives actual T&D losses of DISCOs for the FY 2016-17 and
a comparison between the actual T&D losses for the two years
i.e. FY 2015-16 and FY 2016-17:
DISCO 2016-17 (Units in GWh) Losses (%) Purchased Sold Lost 2015-16
2016-17 Inc./(Dec.)
PESCO 12,511.08 8,432.10 4,078.98 33.76 32.60 (1.16) TESCO 1,450.49
1,227.13 223.36 18.96 15.40 (3.56) IESCO 10,582.64 9,627.52 955.12
9.09 9.03 (0.06) GEPCO 9,778.56 8,777.79 1,000.77 10.58 10.23
(0.35) LESCO 20,621.54 17,782.81 2,838.73 13.94 13.77 (0.17) FESCO
12,857.80 11,498.74 1,359.06 10.24 10.57 0.33 MEPCO 15,951.27
13,253.19 2,698.08 16.45 16.91 0.46 HESCO 5,359.58 3,711.72
1,647.86 26.46 30.75 4.29 SEPCO 4,489.04 2,787.73 1,701.31 37.87
37.90 0.03 QESCO 5,788.76 4,452.57 1,336.19 23.92 23.08
(0.84)
Overall Average 99,390.76 81,551.30 17,839.46 17.95 17.95 0.00
Source: PEPCO
It may be noted that as a whole, DISCOs did not show any
improvement in transmission and distribution losses, as their
overall losses have been recorded as 17.95% for both the years. The
losses in HESCO increased by 4.29% in the FY 2016-17 over those of
the FY 2015-16. SEPCO also showed slight increase in its losses.
Losses of MEPCO also increased by 0.46%; however it is a matter of
concern that one of better DISCOs i.e. FESCO could not reduce or
even maintain its losses at the FY 2015-16 level of 10.24%, as its
losses in the FY 2016-17 increased to 10.57%. As discussed earlier
DISCOs need to improve their operational performance to take
advantage of the improved electricity supply availability,
otherwise financial position of the power sector and the overall
economy will have a huge negative impact. The T&D losses of
DISCOs are among the most discussed and debated issues in the
context of power sector. The Regulator has also been advising and
directing the DISCOs for taking operational and managerial steps to
control their losses and bring those, closer to prudent levels.
NEPRA has also allowed huge investment funds every year to DISCOs,
so that new and critical projects are initiated and completed on
time. Since all DISCOs are owned and controlled by the Ministry of
Energy (Power Division), therefore, the Regulator has always been
pointing out this critical issue to relevant quarters at all fora.
It is however observed, that DISCOs’ performance in this area
remained unsatisfactory throughout. Except for one or two
companies, the others have remained oblivious to gravity of the
matter. It is also noted that the DISCOs have obvious, lack of
managerial capacity and skills, mindset to not go for such projects
which may bring improvements in this area; for instance increasing
metering at all levels to trace flow of electricity top-down,
automatic metering and centralized monitoring. Long standing
efforts for passing on the actual losses without any apparent
desire to lower losses, have in fact encouraged DISCOs to conceal
their inefficiencies under this head. DISCOs seem contended with
their performance levels, and that approach at this cross-road
where the Federal Government has
17
inducted a large generation capacity to the system may drag the
whole sector down if immediate steps to correct this position are
not taken.
(%)
Year PESCO TESCO IESCO GEPCO LESCO FESCO MEPCO HESCO SEPCO QESCO
Overall DISCO
2015-16 88.49 436.97* 91.14 99.41 99.20 100.06 99.99 72.09 55.18
71.62 94.48 2016-17 89.29 82.90 91.87 95.99 99.20 97.24 96.21 93.68
109.98 43.55 92.65
* Source payment received against billing of Private Domestic TESCO
consumers for Rs. 18,955.61 million in 2015-16 from Federal
Government. Source: DISCOs
1.9.1 Recovery Position of Main Categories of Consumers (%): To
narrow down the areas of interest, following charts show
performance of all the DISCOs in the four major categories of
consumers. It may be noted that IESCO was able to maintain quite a
consistent and satisfactory recovery ratios for all the consumer
categories. GEPCO managed satisfactory ratios for domestic and
commercial consumers however for industrial and agricultural
consumers, it needs to improve its recovery to come closer to
IESCO. LESCO needs to focus more on agricultural consumers for
improving its recovery position for this category. FESCO also
achieved quite satisfactory recovery ratios except for industrial
consumers for which recovery position can be improved through
better managerial efforts. Similarly, MEPCO also needs to address
recovery issues with the industrial sector to improve its position.
PESCO has shown an overall improvement in this area, however its
recovery in domestic category is close to 84% which requires
sustained efforts by the company management to target above 90%
recovery in this category. It is observed that HESCO and SEPCO
require hectic efforts to improve their recovery position in
domestic sector. QESCO’s inferior performance is mainly due to poor
recovery position of agricultural and domestic consumers.
18
1.10 PERFORMANCE OF K-ELECTRIC LIMITED By March 2018, KEL had
installed capacity of 2,261 MW through its own power plants whereas
IPPs and CPPs add another 442 MW to KEL system. In addition to 137
MW KANUPP power plant, NTDC is also providing 650 MW to KEL system.
Due to aging and deterioration in generation facilities, KEL’s
present capacity is reported as 1,973 MW. Since KEL is responsible
for maintaining integrated systems of generation, transmission and
distribution, therefore it is required to look for other sources to
meet the supply and demand gap. Inability of KEL to effectively
increase its generation capacity has made it dependent on external
power sources, including the import from NTDC system. During the FY
2016-17 also, in addition to purchasing power from IPPs, KEL
imported around 650 MW of power from NTDC on regular basis.
Although the agreement between NTDC and KEL for power purchase has
already expired, the power is still being supplied to meet the
requirement of KEL consumers.
The energy generated during the FY 2016-17 through KEL own power
plants is noted as 10,147 GWh which shows a decrease of 176 GWh as
compared to the previous year figure i.e. 10,323 GWh; a decrease of
1.7%.
During the year KEL continued to underutilize its own generation
power plants and it was also noted to ignore merit order operation
of its power plants. The Authority initiated relevant proceedings
under its law to address the matter.
KEL reportedly faced gas supply issues which added to problems of
the utility, as the KEL power plants during the FY 2016-17 used
55,016 MMCFT of gas, which is lower by 11,867 MMCFT as compared to
its gas consumption during the FY 2015-16.
It may be noted that KEL was able to improve the average efficiency
of its generation fleet from 30.4% in 2009 to present levels of 37%
in 2017. The design thermal efficiency of some units of BQPS-I on
oil and gas were 37.5% and 36% respectively. Owing to lack of
proper O&M practices, the current average efficiency of BQPS-I
is hovering around 33.64% which although is better than GENCOs’
similar plants, having efficiencies in the range of 24% to 32% but
when compared to the efficiency of 38.60% as allowed to private
power plants under 1994 Power Policy, the efficiency and
availability levels of KEL are not satisfactory.
1.10.1 Loading Position of Power Transformers, 11 kV Feeders and
Distribution Transformers: The following table provides overloading
positions (above 80%) of overloaded components in KEL for the FY
2015-16 and the FY 2016-17:
Description 2015-16 2016-17 Total No. of Over-Loaded Power
Transformers (above 80%) 31 59 Percentage of Total Over-Loaded
Power Transformers (above 80%) 22.63 42.75 Total No. of Over-Loaded
11 kV Feeders (above 80%) 104 91 Percentage of Total Over-Loaded 11
kV Feeders (above 80%) 6.82 5.51 Total No. of Over-Loaded
Distribution Transformers (above 80%) 648 551 Percentage of Total
Over-Loaded Distribution Transformers (above 80%) 2.78 2.15
Source: KEL
It is noted that more than 40% power transformers of KEL are
overloaded in the FY 2016-17, whereas in the FY 2015-16
approximately 22% transformers were noted to be operating above
80%
19
of their rated capacity. It may be concluded that KEL has not added
enough power transformers in its network to maintain at least the
same ratio of overloaded transformers as of last year, whereas it
was required to maintain a system capable of providing a reliable
supply at all times for consumers. KEL’s failure to add adequate
number of power transformers was among the major reasons for
frequent tripping and prolonged load shed hours during the FY
2016-17.
1.10.2 Recovery Position of K-Electric Limited:
KEL’s position is also not satisfactory although its’ recovery
position has slightly improved than the last year. It is noted that
the domestic consumers have a 51% share in total energy billed by
KEL however; it could recover only 82% of the amount corresponding
to that energy. Unless KEL takes effective measures in this
category, it would be quite difficult to improve the overall
financial health of the company. Being a private sector entity,
NEPRA requires that innovative measures be taken by KEL to show its
commitment for meeting the overall objectives of a prudent
utility.
Category Amount of Billed Units
(Rs. in Million) Amount Realized and %age Recovery to Billed
Amount
(Rs. in Million) (%) Domestic 98,081 80,477 82.05 Commercial 42,156
39,786 94.38 Industrial 58,224 60,479 103.87 Agricultural 1,419 351
24.74 Public Lighting 3,482 1,045 30.01 Bulk Supply 8,418 8,532
101.35 Others 170 172 101.18 Total 211,950 190,842 90.04
Source: KEL 1.11 THE REGULATION OF GENERATION, TRANSMISSION AND
DISTRIBUTION OF
ELECTRIC POWER (AMENDMENT) ACT, 2018 The Parliament has recently
passed the Regulation of Generation, Transmission and Distribution
of Electric Power (Amendment) Act, 2018 [Act No. XII of 2018]. The
Amendment Act has restructured and evolved the energy sector in
material respects and overhauled the role and responsibilities of
NEPRA. The material changes to the law introduced vide the
Amendment Act are as follows:
1.11.1 Major Amendments: The qualifying experience of the Chairman
and members of the Authority have been reduced from 20 years to 12
years respectively, and the retirement ages of Members and the
Chairman from 65 years to 60 years.
The concepts of the National Electricity Policy (formulated by the
Federal Government and approved by the CCI) and National
Electricity Plan (formulated by the Federal Government in
consultation with Provincial Governments) have been introduced in
the law. The Authority has to
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exercise its mandate in accordance with both the Policy and
Plan.
The law has further introduced frameworks for establishment and
functioning of an Appellate Tribunal, under which all orders and
determinations of the Authority shall be appealable.
The major focus of the Amendment Act has been to introduce various
market-based frameworks in the energy sector, to create a
competitive market regime. The law has introduced new entities,
such as the Energy Supplier and Energy Trader, and revised the
regulatory regime for existing entities, by introducing the new
Market Operator and System Operator Licences. Traditional elements
of the energy sector have also been reformed under this spirit, by
the provision of a cessation mechanism for all Generation Licences
and removal of exclusivity for Distribution Companies.
Flowing from the above, NEPRA’s role in the forthcoming energy
sector has also been revised, with a major focus on the regulator’s
enforcement powers. The Authority has been granted new enforcement
powers of investigation, prohibition orders, issuance of directions
and indemnity. In addition, the function of NEPRA as a
regulation-making body has also been bolstered, with numerous
subject matters falling within the purview of regulations to be
exclusively prescribed by the Authority.
With a focus on betterment of end-consumer service, a new consumer
complaints office framework has been introduced in the law, under
which offices are envisioned to be established at a district level
for overseeing complaints relating to overbilling, metering, theft
etc. Concurrently, new penal provisions and offences have been
introduced in statute, including the punishment of
imprisonment.
1.11.2 Challenges: The above discussed reforms represent a
significant departure from the traditional regulatory framework
under which NEPRA has been functioning for the preceding 20 years.
As such, the Authority shall be facing innumerable challenges in
effectuating the reforms introduced vide the Amendment Act.
The most significant revision to NEPRA’s regulatory purview under
the Amendment Act is the introduction of the National Electricity
Policy and Plan, and the Appellate Tribunal. Previously, all
functions of the Authority were executed in an independent,
impartial and unfettered manner. Now all functions are subject and
subservient to both the Policy and Plan, and are directly
appealable before the Appellate Tribunal. These frameworks curtail
the autonomy of the regulator in material respects. As such, the
regulator has to undertake the challenging task of reevaluating and
realigning its regulatory functions in accordance with the new
legal regime.
The establishment of the Appellate Tribunal and district-level
consumer complaint offices present further challenges for the
Authority. The Appellate Tribunal is to be manned by 3 Members with
diverse experiences and expertise, and provided in the law.
However, it will be challenging for the Tribunal to adjudicate on
complex matters that the Authority, with its 100 professionals
holding immeasurable cumulative expertise in the sector, itself
executes. Moreover, the Tribunal represents an additional layer in
the dispensation of justice in an already exhaustive appellate
framework. In addition, the establishment of more than a 100
offices for complaints in each district poses a monumental
logistical and human resource challenge for the Authority.
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Various avant-garde concepts have been introduced in the amended
law without necessary elaboration. For instance, no parameters for
the National Electricity Plan have been specified, the
functions/role of the Electricity Trader Licensee have not been
provided and the statutory provisions do not explicitly provide for
treatment of consumer-end tariffs under the new law. There are also
various inconsistencies found in the law, for instance the
introduction of uniform tariffs (conflicts with provisions relating
to competition) and savings under preceding law (conflict between
provisions of existing saved licences and statutory provisions).
These concerns lay significant challenges before the Authority in
the exercise of its functions going forward.
1.12 ENERGY, ENVIRONMENT AND SUSTAINABLE DEVELOPMENT Cognizant of
its responsibilities towards protection of environment of the
country, in view of planned induction of large coal power plants,
NEPRA organized a seminar about Energy, Environment and Sustainable
Development. The seminar was attended by representatives from
various organizations. The main aim and objectives of the said
seminar were as follows:
(a) Awareness about environment among the stakeholders in
Pakistan’s power sector; especially after the expected changes in
the current energy mix.
(b) Adequacy of existing laws on environment protection and the
role of relevant bodies. (c) NEPRA’s role. (d) Way forward.
During the seminar, representatives of Provincial Environmental
Protection Agencies (EPAs), discussed about procedural aspects of
their departments and showed keen commitment and need for
continuous monitoring of upcoming coal fired power plants.
NEPRA being the regulator of the power sector regularly interacts
with relevant EPAs about compliance of their relevant acts.
Moreover, NEPRA also obtains compliance reports from the project
companies as required under generation licence.
1.13 COMPREHENSIVE REDUCTION AND ELIMINATION OF POLYCHLORINATED
BIPHENYLS (PCBs)
Another project to protect environment is in shape of NEPRA’s
support to Ministry of Climate Change (MOCC). The objective of MOCC
project is to reduce risks for the human health and the environment
by avoiding the release of Persistent Organic Pollutants (POPs) in
the environment and preventing human exposure to these. POPs can be
defined in a number of ways including the following:
(a) Chemicals with high toxicity originated through anthropogenic
activities. (b) Organic chemicals containing carbon and hydrogen
are characterized by adverse
effects on life. (c) Bio-accumulation, persistence and long range
transport pose a threat to humans
and the environment. (d) POPs are widely used as pesticides and/or
industrial chemicals.
The project has been arranged in four components:
(a) Development and Implementation of a Regulatory Policy and
Enforcement System to reduce POPs releases.
(b) Capacity building of local communities and public and private
sector stakeholders
22
to reduce exposure to and releases of POPs. (c) Collection,
Transport and Disposal of PCBs and POPs Pesticides. (d) Monitoring
and Evaluation.
NEPRA has been coordinating with the power sector entities and
MOCC, essentially for identification of PCBs, present in power
equipment.
1.14 RATIONALIZATION OF GENERATION TARIFF PARAMETERS As part of its
regulatory process, NEPRA has reviewed various tariff components
for necessary changes needed therein. This aims to ensure that the
power sector tariffs approved and awarded are consistent and
reflective of prevailing economic and financial circumstances that
implicate power generation tariffs approved by NEPRA. After a
comprehensive review and discussion with various stakeholders, the
Authority has decided to revise certain benchmarks and ceilings to
be allowed for tariff components of generation projects. In this
respect, the Authority would like to seek input of all stakeholders
on these recommendations before these are finalized for application
in tariffs. Following heads have been identified for review by the
Authority:
(a) Banking Spread (b) Debt and Equity Ratios (c) IDC and ROEDC (d)
Financing Fee (e) Insurance (f) Withholding Tax on dividends (g)
Availability
The Authority in principle continues to move towards promoting the
competitive mode in generation tariffs. However, for the specific
projects to be considered under cost plus regime and for certain
parameters to be used in upfront tariffs, these benchmarks will be
used accordingly. 1.15 REVIEW OF RATE OF RETURN NEPRA has decided
to review the returns offered in the power sector and prepared a
concept paper for determination of the rates of return for the
power companies which provided a basis for determining Internal
Rate of Return (IRR) for various technologies, value chain of power
sector i.e. generation, transmission and distribution and tariff
regimes (cost plus, upfront). The basic objective is that the IRR
now needs to be effectively reflective of specific risk and return
matrix and its adjustment for a particular technology. The document
was uploaded on NEPRA website for comments from the
stakeholders.
1.16 INDUSTRY – ACADEMIA COLLABORATION National University of
Sciences and Technology (NUST) is working closely with NEPRA on a
research proposal namely “Modeling and Simulation of Pakistan’s
Electric Power Sector to develop a Road Map for Transition from the
Current Single Buyer Model to a Competitive Whole Sale Power
Market”.
23
1.17 CONCLUSIONS 1.17.1 It is concluded that with the current
implementation and planned generation
additions, the country would have generation capacity surplus
position for next five to six years; ensuring sufficient margins
for a reliable power supply.
1.17.2 The question of dependence on dirty imported fuels has been
partly addressed, as no new power plants have been planned on
furnace oil and relatively clean fuel of RLNG has been introduced.
Similarly, Federal Government has also put a cap on power
generation plants using imported coal. However more than 12,000 MW
RLNG/ Gas based power plants will be expected to use imported RLNG
by the FY 2020-21, therefore the power sector consumers will not
get any reprieve from the international price uncertainties.
1.17.3 The prices of solar and wind based technology have fallen
over past three years, and now their resulting tariffs are quite
attractive in comparison with other technologies. Induction of
clean energy based projects however, could not take place due to
absence of clear policies of the Ministry of Energy (Power
Division).
1.17.4 Similarly the induction of small hydropower plants could not
take place due to different procedural issues. Due to their robust
nature, these plants have useful operating life of more than fifty
years. Therefore after the initial years of debt repayment, these
plants provide a very cheap energy without any dependence on
fuel.
1.17.5 With the induction of new generation capacity in the system,
it is imperative that every MW of it is optimally used.
Transmission and distribution infrastructure must be capable of
receiving all available electricity and delivering it to
end-consumers. NEPRA notes that networks in NTDC and in most of the
DISCOs are not adequate to transmit electricity under different
system conditions.
1.17.6 With the addition of new generation facilities over a short
span of time, the capacity payments are bound to increase. In order
to minimize the impact of increased capacity component in the
consumer-end tariff, multi-pronged strategies are needed to be
followed.
1.17.7 KEL continued to under-utilize its generation facilities,
whereas it failed to add sufficient transformation capacity in its
network which resulted in an unreliable system operation, frequent
tripping of networks and prolonged load shed hours during the FY
2016-17.
1.17.8 The role of provincial bodies has become more important in
overcoming power sector issues. The role of Provincial Government
is critical in supporting transmission and distribution licensees
in implementation of infrastructural projects. On the development
of generation facilities however, NEPRA has observed that some of
the provincial agencies lack management and procedural capacity and
necessary skills for developing generation resources
efficiently.
24
1.17.9 NEPRA has introduced Net-Metering regime since 2016. 108
consumers for 2,346 kW have been noted to participate in it upto
June, 2017. Consumers and other stakeholders have been showing a
lot of interest by proposing improvements in this regime.
1.17.10 Federal Government has recently approved Amendment Act,
2018 which provides for a complete shift in the existing regulatory
regime. The distribution business has now been bifurcated into
separate wire and sale businesses. At the same time concepts of
“trader” and “supplier” have been introduced which in a way set the
direction of a future market model. It is felt that by including
framework for a future market in the Act, an inflexible approach
has been adopted instead of conducting detailed deliberation for
recommending a solution.
1.18 RECOMMENDATIONS 1.18.1 For continued reliability in the
system, long term plans would be required to be
developed taking into consideration clear policies and supply and
demand position.
1.18.2 In order to reduce dependence on imported fuel, new
explorations and induction of indigenous gas should be
encouraged.
1.18.3 Since solar and wind provide environmentally clean energy,
without using fuel, therefore the Ministry of Energy (Power
Division) is urged to resolve policy level ambiguities and
technical issues for promotion of these technologies.
1.18.4 For long-term sustainability of the sector, small hydropower
plants must be encouraged.
1.18.5 Ministry of Energy (Power Division) being owner of NTDC and
DISCOs, is required to take extra ordinary steps for ensuring
availability of strong transmission and distribution infrastructure
to provide a reliable electricity supply.
1.18.6 Increase energy sold by reduction in T&D losses in
DISCOs. DISCOs’ management must focus on specific high loss feeders
and set clear targets for loss reduction.
1.18.7 DISCOs must adopt all measures, which help in tracking
electricity flow from high voltage grids to end-consumers.
Automatic metering systems, remote metering devices and centralized
monitoring systems are to be installed immediately.
1.18.8 Recovery ratios in DISCOs need to be 100%. DISCOs having
lower recovery ratios must take immediate measures to close the
gap.
1.18.9 For improved management, large DISCOs may be considered for
bifurcation.
25
1.18.10 KEL must add efficient power generation plants in its
system to reduce dependence on external sources. Further, KEL needs
to add power transformation capacity on urgent basis for a reliable
power supply to consumers.
1.18.11 The provincial bodies responsible for power development,
need capacity building and improved human resource skill
level.
1.18.12 It is recommended to let Net-Metering regime continue so
that burden on constrained networks of DISCOs may be reduced.
1.18.13 In order to reduce capital costs of major equipment in
generation, transmission and distribution sectors, it is
recommended to initiate and encourage local manufacturing.
1.18.14 After the approval of Amendment Act 2018, extensive
consultations are required among stakeholders for the success of a
new regulatory regime.
STATE OF INDUSTRY REPORT 2017
PERFORMANCE OF GENERATION SECTOR
PERFORMANCE OF GENERATION SECTOR
2.1 GENERAL The total installed generation capacity of Pakistan as
on 30th June, 2017 stands at 28,399 MW, against 25,421 MW on 30th
June, 2016, recording an increase of 2,978 MW or 11.71% over the
last year. The power plants connected with NTDC and KEL’s system
generated 120,621 GWh during the FY 2016-17 as compared to 114,093
GWh units produced during the FY 2015-16. During the FY 2016-17,
the major additions to the system are thermal, nuclear and
renewable based power projects.
2.2 INSTALLED CAPACITY AND ELECTRICITY GENERATION The following
tables give additional details of source-wise installed capacity
and electricity generation by different power plants connected with
NTDC and KEL system along with a comparison of last two
years:
Source-wise Installed Capacity by Type (MW)
As on 30th June 2016 2017 Variation
Capacity % HYDEL WAPDA Hydel 6,902 6,902 - - IPPs Hydel 214 214 - -
THERMAL GENCOs with PEPCO 5,897 5,897 - - KEL Own 1,874 1,874 -
-
IPPs Connected with PEPCO 8,643 10,566 1,923 22.25 Connected with
KEL 252 252 - -
CPPs/SPPs connected with KEL 35 87 52 148.57 NUCLEAR CHASNUPP (I,
II and III) 615 1,005 390* 63.41 KANUPP 137 137 - - RENEWABLE
ENERGY (WIND, SOLAR AND BAGASSE) RE Power Plants connected with
PEPCO 852 1,465 613 71.94
Total Installed Capacity of the Country 25,421 28,399 2,978 11.71 *
Trued up the net capacities indicated earlier to Name Plate
Capacities. Source: NTDC/KEL
Source-wise Electricity Generation by Type (GWh)
As on 30th June 2015-16 2016-17 Variation Energy %
HYDEL WAPDA Hydel 33,433 31,091 (2,342) (07.00) IPPs Hydel 1,121
988 (133) (11.86) THERMAL GENCOs with PEPCO 16,392 18,710 2,318
14.14 KEL Own 10,323 10,147 (176) (1.70)
IPPs Connected with PEPCO 45,146 47,972 2,826 6.26 Connected with
KEL 1,421 1,531 110 7.74
CPPs/SPPs connected with PEPCO 251 271 20 7.97 CPPs/SPPs connected
with KEL 139 187 48 34.53
As on 30th June 2015-16 2016-17 Variation
Energy % NUCLEAR
02
30
CHASNUPP (I, II and III) 3,854 5,868 2,014 52.26 KANUPP 362 410 48
13.26 IMPORT Import from Iran 463 496 33 7.13 RENEWABLE ENERGY
(WIND, SOLAR AND BAGASSE) RE Power Plants connected with PEPCO
1,187 2,950 1,763 148.53 Total Electricity Generation of the
Country 114,093 120,621 6,528 5.72
Source: NTDC/KEL
2.3 HYDROPOWER It may be noted that while the installed capacity of
WAPDA Hydropower remained at 6,902 MW in the years 2015, 2016 and
2017, the 31,091 GWh generated in the FY 2016-17 shows a decrease
of 2,342 GWh from the last year. Similarly, the Hydel IPPs also
contributed 133 GWh less in the system during the FY 2016-17 with
the same installed capacity as in the FY 2015-16. The hydropower
energy production pattern over the year remained consistent with
the historical trends. The availability and overall performance of
major hydropower plants including Tarbela and Mangla has also
remained satisfactory during the FY 2016-17.
2.3.1 Power Purchase Agreements/Energy Purchase Agreements: NEPRA
has approved the PPAs of two large hydropower projects under
Section 5 of “NEPRA Interim Power Procurement (Procedure and
Standards) Regulations, 2005”. Details of these projects are given
below:
S. No. Project Name Capacity (MW) Power Purchaser 1 Karot
Hydropower Project 720 CPPA-G 2 Suki Kinari Hydropower Project 870
CPPA-G
2.3.2 Competitive Bidding of Hydropower Projects: NEPRA has
approved the Request for Proposal (RFP) of Taunsa Hydropower
Project and six other projects identified by PEDO under the
Competitive Bidding Tariff (Approval Procedure) Regulations (CBTR),
2014. Subsequently, the bidding under CBTR-2014 for Taunsa
Hydropower Project was successfully completed and the Authority has
accordingly notified the lowest successful bidder. This was the
first power generation project whose tariff has been determined
through Competitive Bidding in Pakistan’s power sector.
2.3.3 Performance Monitoring of Hydropower Projects: The monitoring
of different hydropower projects was carried out in the year 2017
to check their performance according to the terms and conditions
set in Licence, PPA, Tariff Determination and other relevant rules
and regulations.
NEPRA has noted the unsatisfactory performance of Malakand-III (81
MW), Jinnah (96 MW) and Khan Khwar (72 MW) Hydropower Plants. The
sponsors and the power purchaser have been directed to improve the
operation and maintenance of these plants.
2.3.4 Implementations of Authority’s Directions: The Authority
noted that a number of holders of LOIs for hydropower project sites
were inordinately delaying the development of these sites.
Accordingly, directions were issued to the relevant agencies to
cancel all those LOI/LOS of projects which have been inordinately
delayed
31
by the sponsors. As a result, a number of LOIs and LOSs of
hydropower sites were cancelled by implementing agencies and the
process for their speedy development was initiated. These include
the following large hydropower projects:
S. No. Project Name Capacity (MW) 1 Sehara Hydropower Project 130 2
Madian Hydropower Project 157 3 Asrit Kedam Hydropower Project 215
4 Chakothi Hattian Hydropower Project 500
Advisories were also issued to CPPA-G/Power Purchaser to expedite
process of implementation of small hydropower projects and signing
of PPAs.
2.4 OVERVIEW OF PUBLIC SECTOR GENCOs
2.4.1 Jamshoro Power Company Limited (GENCO-I): There has been no
increase in the installed capacity of 1,024 MW GENCO-I Power
Stations at the end of June, 2017 over that of the year 2016. The
energy generated by GENCO-I during the FY 2016-17 was 3,593 GWh,
while, it was 3,828 GWh in the FY 2015-16; a decrease of 235 GWh or
6.14%, over last year. Net efficiency of GENCO-I during FY 2016-17
stood at 28.42% for TPS Jamshoro and 27.05% for GTPS Kotri. With a
capacity utilization of 58.04% for TPS Jamshoro and 33.51% for GTPS
Kotri due to forced outages and various maintenance issues, the
overall performance of GENCO-I has not been satisfactory.
NEPRA in its tariff determination in respect of TPS Jamshoro
approved part load adjustments for its power plants. GENCO-I
approached NEPRA through CPPA-G (in its fuel price adjustments) and
claimed Rs. 1,090.688 million owing to part load operation of its
units for ten months period (July, 2015 to April, 2016). NEPRA,
keeping in view the net electric output of the plant as provided
and verified by CPPA-G, fuel cost component and part load
adjustment factors based on actual loading of the units, approved
Rs. 284.974 million.
2.4.2 Central Power Generation Company Limited (GENCO-II): Total
installed capacity of GENCO-II, up to 30th June, 2017 has been
noted as 2,402 MW. No new generation plant was inducted during the
year under review for GENCO-II. The energy generated by GENCO-II
during the FY 2016-17 has been recorded at 8,079 GWh, while, it was
6,031 GWh during the FY 2015-16. The energy generated by GENCO-II
during the FY 2016-17, has increased by 2,048 GWh or 33.97%,
compared with that of the last year.
It is observed that various units of GENCO-II have remained off-bar
for several years due to maintenance issues, forced outages, fuel
constraints and rehabilitation activities etc. and are not being
fully utilized. With reduced annual efficiency and reduced capacity
utilization factor, the overall performance of GENCO-II has been
unsatisfactory.
2.4.3 Northern Power Generation Company Limited (GENCO-III): Total
installed capacity of GENCO-III, up to 30th June, 2017 has been
noted as 2,293 MW. During the FY 2016-17, the installed capacity of
GENCO-III remained the same as compared with that of the year
2015-16. The energy generated by GENCO-III during the FY 2016-17
was 6,861 GWh, while it
32
was 6,273 GWh during the FY 2015-16 showing an increase of 588 GWh
or 9.37%, compared with the last year.
It is observed that the overall net efficiencies of TPS
Muzaffargarh, SPS Faisalabad, GTPS Faisalabad and Nandipur remained
very low. Due to various maintenance issues, forced outages and
fuel constraints etc. considerably low annual capacity utilization
of 48.21% for TPS Muzaffargarh, 14.52% for SPS Faisalabad, 12.27%
for GTPS Faisalabad and 38.52% for Nandipur Power Plants have been
reported. The overall performance of GENCO-III has been
unsatisfactory.
2.4.4 Lakhra Power Generation Company Limited (GENCO-IV): Total
installed capacity of GENCO-IV, up to 30th June, 2017 has been
noted as 150 MW. GENCO-IV had three units of 50 MW and during the
FY 2016-17 generated 124 GWh as compared to 148 GWh produced during
the FY 2015-16.
It may be noted that, against the installed capacity of 150 MW,
approximately, two third capacity of GENCO-IV is available for
generation, which is also not being fully utilized due to forced
outages etc. With utilization factor of 22.68% for the FY 2016-17
the overall performance of GENCO-IV has remained
unsatisfactory.
2.5 INDEPENDENT POWER PRODUCERS (IPPs) Total installed capacities
of thermal IPPs connected with NTDC system at the end of June, 2017
are noted as 10,566 MW; 1,923 MW higher as compared to the FY
2015-16. The enhancement in capacity has been recorded owing to
induction of coal fired Sahiwal Power Plant and RLNG fired Bhikki
and Haveli Bahadur Shah Power Plant. The energy generated by
thermal IPPs connected with NTDC system during the year 2016-17 is
noted as 47,972 GWh, against 45,146 GWh during the year
2015-16.
It is also noted that due to disputes with NTDC/WAPDA, two IPPs
namely Japan Power Generation and Southern Electric Power Company
are not contributing power to the grid and if these issues are
properly addressed, approximately 270 MW will be added to the close
proximity of load centre, to help reduce the demand and supply gap
of the system.
2.6 NUCLEAR (CHASNUPP-I, II & III AND KANUPP) During the year
2016-17, owing to addition of CHASNUPP-III, total installed and
dependable capacity of Nuclear Power Plants connected with NTDC’s
system, are noted as 1,142 MW, higher by 390 MW (340 MW has been
actually added in the system, whereas 50 MW is added on account of
corrections made to previous year numbers which reflected net
capacities, instead of name plate capacities) than the year
2015-16. The energy generated by Nuclear Power Plants during the
year 2016-17 stands at 6,278 GWh which is an increase by 2,062 GWh
over the energy during the year 2015-16. The overall performance of
Nuclear Power Plants connected with NTDC’s system has remained
satisfactory during the year 2016-17 as no major outage is noted.
2.7 RENEWABLES
2.7.1 Wind: During the FY 2016-17, 479 MW of wind power has been
added to the NTDC’s system, for a total wind based power of about
785 MW in the system. The energy generated by wind based
power
33
plants during the FY 2016-17 has been noted as 1,387 GWh.
2.7.2 Solar: During the FY 2016-17, no new solar energy project has
been added to NTDC’s network. The total energy through solar has
been recorded at 635 GWh for an increase of 410 GWh over the energy
generated through solar during the FY 2015-16.
2.7.3 Bagasse: During the FY 2016-17, there is an increase of about
15 MW in the installed generation capacity of bagasse based power
plants for a total of about 161 MW in the NTDC’s system. The energy
generated by bagasse based power plants during the FY 2016-17 has
been noted as 785 GWh.
2.7.4 Bagasse/Coal: During the FY 2016-17, a bagasse/coal fired
project namely Fatima Energy Limited started its operations having
capacity of 119 MW. The project generated 143 GWh during the FY
2016-17.
2.8 K-ELECTRIC LIMITED The installed capacity of KEL’s own
generation fleet at 30th June, 2017 has been noted as 1,874 MW,
same as at 30th June, 2016. Since KEL is responsible for
maintaining integrated systems of generation, transmission and
distribution, therefore KEL is required to look for other sources
to meet the supply and demand gap. Inability of KEL to effectively
increase its generation capacity has made it dependent on external
power sources, including the import from NTDC system. During the FY
2016-17, in addition to purchasing power from IPPs including
PASMIC, Anoud Power, International Steel Limited, Tapal Energy, Gul
Ahmed, KANUPP, International Industries Limited and FPCL Power, KEL
also imported around 650 MW of power from NTDC on regular
basis.
KEL generated 10,147 GWh during the FY 2016-17 which shows a
decrease of 176 GWh from the last year. Owing to reduction in own
generation, KEL imported 17,352 GWh which shows an increase of 48
GWh from the last year. It is noted while reviewing operational
trend of KEL’s own power plants that KEL consumed more furnace oil
and less gas for electricity production during the FY 2016-17 as
compared to last year. With higher auxiliary consumption and
reduced capacity utilization factor over the last year, the overall
performance of KEL own power plants cannot be termed as
satisfactory.
KEL also provided its investment plan for the period from the FY
2016-17 till the FY 2020-21 for new capacity additions along with
estimated cost and expected commissioning years as reported in the
next sections.
2.9 ELECTRICITY PURCHASES FROM SPPs/CPPs/N-CPPs During the FY
2016-17, the surplus installed capacity available with Sugar Mills,
Textile Mills and Chemical units et