Difference between revisions of "Jordan Energy Situation"

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= Overview<br> =
+
{{CES Country|CES Country Name=Jordan
 +
|CES Country Capital=Amman
 +
|CES Country Region Middle East and North Africa = Middle East & North Africa
 +
|CES Country Coordinates=31.9500° N, 35.9333° E
 +
}}
 +
= Introduction<br/> =
  
{| width="400" cellspacing="0" cellpadding="0" border="1" style="float: right;"
+
The Hashemite Kingdom of Jordan covers an area of 89,342 km² on the northern Arabian Peninsula. It borders with Syria, Israel, Iraq, Saudi Arabia and the West Bank (Palestine) as well as the Red Sea, with only 1.5% of its surface being arable land.<ref>GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.</ref> The climate is semi-dry in summer and cool in winter.<br/><br/>
|-
+
 
| align="center" colspan="4" | '''Hashemite Kingdom of Jordan'''
+
= Energy Situation<br/> =
|-
 
| &nbsp; [[Image:Jordan Flag.png|border|center|150x100px|Jordan Flag.png]]<br>  
 
| &nbsp; [[Image:Jordan Location.png|border|center|160x100px|Jordan Location.png]]<br>
 
|-
 
|
 
Capital<br>  
 
  
|
+
== Energy Data<br/> ==
Amman ([http://toolserver.org/~geohack/geohack.php?pagename=Jordan&params=31_57_N_35_56_E_type:country 31°57′N 35°56′E])
 
  
|-
+
=== Primary Energy Supply<br/> ===
|
 
Official language(s)<br>  
 
  
|
+
Jordan has two main challenges regarding its energy situation: the growing energy demand on the one hand and the very limited domestic resources to fulfill this demand on the other hand. In 2012, the local production of energy – including crude oil, natural gas and renewable energy – was 272 ktoe (thousand tonnes of oil equivalent)<ref>http://www.iea.org/statistics/statisticssearch/report/?country=JORDAN&product=balances&year=2012</ref>, which was enough to cover only about 5% of the energy consumption. Including imports, the primary energy supply was 7,624 ktoe in 2012.<ref>http://www.iea.org/statistics/statisticssearch/report/?country=JORDAN&product=balances&year=2012</ref><br/>
Arabic<br>  
 
  
|-
+
<br/>
|
 
Government<br>  
 
  
|
+
=== Consumption<br/> ===
Constitutional monarch<br>  
 
  
 +
Final energy consumption in Jordan in 2012 added up to 5,013 ktoe. The share of the individual sectors is shown in table 1.<br/>
 +
<p style="text-align: center;"><u>Table 1: Final energy consumption in Jordan in 2012 by sector (ktoe)</u><ref>http://www.iea.org/statistics/statisticssearch/report/?country=JORDAN&product=balances&year=2012</ref><br/></p>
 +
{| style="width: 100%;" border="1" cellspacing="1" cellpadding="1"
 +
|-
 +
| colspan="2" | '''Sector<br/>'''
 +
| '''in ktoe'''<br/>
 +
| '''&nbsp;in %'''<br/>
 
|-
 
|-
|  
+
| colspan="2" | Industry sector
King of Jordan
+
| 692
 
+
| 13.80
|  
 
Abdullah II
 
 
 
 
|-
 
|-
|  
+
| colspan="2" | Transport sector
Prime Minister<br>
+
| 2,289
 
+
| 45.66
|  
 
Marouf al-Bakhit<br>
 
 
 
 
|-
 
|-
|  
+
| colspan="2" | Other sectors
Total area<br>
+
| 1,903
 
+
| 37.96
|  
 
92,300 km<sup>2</sup>
 
 
 
 
|-
 
|-
|  
+
| of which
Population<br>
+
| Residential
 
+
| 1,200
|  
+
| 23.94
6,407,085 (2010 estimate)
 
 
 
 
|-
 
|-
|  
+
| <br/>
GDP (nominal)<br>  
+
| Commericial and public services
 
+
| 369
|  
+
| 7.36
$99.129 billion
 
 
 
 
|-
 
|-
|  
+
| <br/>
GDP Per capita <br>  
+
| Agriculture/ Forestry
 
+
| 168
|  
+
| 3.35
$4,435
 
 
 
 
|-
 
|-
|  
+
| <br/>
Currency<br>  
+
| Non-specified
 
+
| 166
|  
+
| 3.31
Jordanian dinar (JOD)<br>
 
 
 
 
|-
 
|-
|  
+
| colspan="2" | Non-energy use
Time zone<br>
+
| 130
 
+
| 2.59
|  
 
UTC+01<br>
 
 
 
 
|-
 
|-
|  
+
| colspan="2" | Total
Calling code<br>
+
| 5,013
 +
| 100
 +
|}
  
|
+
<br/>
+962<br>  
 
  
|}
+
=== Import and Export<br/> ===
  
{| width="350" cellspacing="1" cellpadding="1" border="0" align="left" class="FCK__ShowTableBorders"
+
The limited domestic resources meant that Jordan had to import 7,656 ktoe (thousand tonnes of oil equivalent) of energy to meet its demands. This means that the cost of the consumed energy amounts to as much as 17% of the GDP.<ref>http://www.memr.gov.jo/LinkClick.aspx?fileticket=B495BBqcNs4%3d&tabid=111</ref><br/>In the past, one of the main sources of the imported energy was Egypt, from where Jordan imported natural gas. However, there have been problems of the service being disrupted, which caused enormous problems with regards to the energy security in Jordan. Therefore, Jordan has increased efforts to diversify its energy supply.<br/>
|-
 
| __TOC__
 
|}
 
<div style="clear: both;"></div>  
 
= Energy Market<br> =
 
  
== Overview Energy Market  ==
+
=== Subsidies<br/> ===
  
The primary energy production in Egypt has been steadily rising and in 2006 reached 62 501 ktoe which translates to 2 617 PJ or 726 887 GWh. While natural gas production is rising steadily and export capacities increase, the production of petroleum products is declining. At the same time, demand for petroleum is further increasing, partly caused by high domestic subsidies. Recently, major natural gas resources have been discovered. For the foreseeable future, natural gas is likely to be the primary growth engine of Egypt’s energy sector.
+
In 2012, the government of Jordan eliminated all fuel subsidies.<ref>http://www.economist.com/news/finance-and-economics/21639589-few-countries-are-taking-advantage-lower-oil-prices-cut-subsidies-pump</ref>&nbsp;In 2014, Jordan’s finance minister stated that electricity subsidies will be eliminated by 2017.<ref>http://www.aawsat.net/2014/05/article55332275/jordans-finance-minister-we-will-eliminate-electricity-subsidies-by-2017</ref><br/><br/>[[Jordan_Energy_Situation#toc|►Go to Top]]<br/>
  
The primary energy production has developed fast in the past; starting from around 8 000 ktoe in 1971, it developed quite linear to the current level. Main growth has been seen in the oil and gas sectors, whereas coal and peat show a more static development on a low level. Shares of renewable energies have not increased to a significant extent and continue to play a minor role in the energy supply structure. Owing to the vast resource base, the energy sector is important for Egypt’s economy and will continue to play a major role in coming years. Egypt is a net exporter of crude oil and natural gas. In addition, it has a strategic position in oil transfer because of its operation of the Suez Canal and Sumed (Suez-Mediterranean) Pipeline, two major routes for the transfer of Persian Gulf oil. In terms of coal and peat, Egypt is a net importer.
+
== Renewable Energy<br/> ==
  
Final energy consumption in 2006 added up to 43 072 ktoe (equal to 500 927 GWh or 1 803 PJ).<br>  
+
The use in Jordan of renewable energy sources has until now been marginal, accounting for a share of less than 1% of electricity generation. In 2012, of the 16.5 MW generated by renewable energy resources, 60.4% were hydropower, 21.1% biomass, 9.7% PV and 8.8% wind<ref name="RCREEE (2013): Jordan 2012. Renewable Energy Country Profile.">http://www.rcreee.org/sites/default/files/jordan_fact_sheet_re_print.pdf</ref>. Potentials for generating power from renewable energy resources in the country are to be found primarily in the areas of wind and solar energy.<br/>
  
{| width="100%" cellspacing="1" cellpadding="1" border="1"
+
=== Wind Energy<br/> ===
|+ '''FINAL ENERGY CONSUMPTION IN EGYPT, 2006, IN PJ'''
 
|-
 
| colspan="4" | Total Final Energy Consumption<br>
 
|-
 
| colspan="2" | <br>
 
| PJ<br>
 
| &nbsp;%<br>
 
|-
 
| colspan="2" | Industry sector<br>
 
| 603<br>
 
| 33<br>
 
|-
 
| colspan="2" | Transport sector<br>
 
| 488<br>
 
| 27<br>
 
|-
 
| colspan="2" | Other sectors<br>
 
| 531<br>
 
| 29<br>
 
|-
 
| of which<br>
 
| Residential<br>
 
| 358<br>
 
| 20<br>
 
|-
 
| <br>
 
| Commercial and public services<br>
 
| 42<br>
 
| 2<br>
 
|-
 
| <br>
 
| Agriculture/ Forestry<br>
 
| 89<br>
 
| 5<br>
 
|-
 
| <br>
 
| Non-Specified<br>
 
| 42<br>
 
| 2<br>
 
|-
 
| colspan="2" | Total<br>
 
| 1622<br>
 
| 100<br>
 
|}
 
  
''Source: IEA 2008''<br>  
+
Jordan has a number of regions that enjoy wind speeds suitable for generating electricity. Those regions with the greatest potential are located in the North and South of the country. A wind atlas, which was drawn up by the Danish Risø research centre in cooperation with the Jordanian authorities, has been available for Jordan since 1989. According to the Ministry of Energy and Mineral Resources, this wind atlas is in the process of being updated with results taken from recent measurements.<br/>So far, two wind farms have been built and connected to the grid in Jordan. One has a generating capacity of 320 kW (4 x 80 kW) and was constructed in 1998, in cooperation with a Danish company, in Ibrahimyya near Hofa, as a pilot project. The second was completed in 1996 in Hofa (financed with funds from the German Eldorado programme) and has a capacity of 1.2 MW (5 x 225 kW). They generated around 3 GWh of electricity in 2012<ref>http://www.iea.org/statistics/statisticssearch/report/?year=2012&country=JORDAN&product=RenewablesandWaste</ref>. The share of electricity from wind is supposed to significantly increase. In 2013, a contract was signed with a consortium of Jordanian and international companies for the 117 MW Tafila wind farm. It is supposed to increase the country's total power capacity by 3%, with commercial operation envisioned to start by mid-2015<ref>http://www.memr.gov.jo/LinkClick.aspx?fileticket=B495BBqcNs4%3d&tabid=111</ref>.<br/>A second contract has been signed on an EPC (Engineering, Procurement and Construction) basis with the Spanish company Elecnor. This wind park in Maan, a city in the South of Jordan, is supposed to produce 33 x 2 MW and to start supplying energy by the end of 2015<ref>http://www.rechargenews.com/wind/1370753/Elecnor-Gamesa-in-Jordan-wind-joy</ref>.<br/>
  
== The Electricity Grid  ==
+
<br/>
  
In 2007 / 2008, the state-owned carrier grid consisted of 39 552 km. The grid is subdivided into six geographical zones, namely Cairo, Canal, Delta, Alexandria and West Delta, Middle Egypt and Upper Egypt. The country’s entire territory is covered.
+
=== Solar Energy ===
  
Medium and low voltage as well as isolated grids are owned and operated by the respective distribution companies. In June 2008, the distribution grid consisted of 142 983 km of medium voltage and 230 187 km of low voltage lines (not including non-energy use).  
+
In Jordan, natural conditions for solar are excellent, with an intensity of direct solar radiation with 5 to7 kWh/m².<ref>http://www.memr.gov.jo/LinkClick.aspx?fileticket=B495BBqcNs4%3d&tabid=111</ref> So far, solar PV has mainly been used for powering off-grid installations such as telecommunication towers, water pumping, and desalination of brackish water, as well as to provide dwellings in remote areas that are not connected to the electricity grid and where desalination had not been installed. Until the publication of the Renewable Energy Law in 2012, an estimated 236.4 kWp had been installed in Jordan.<ref>GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.</ref><br/>In late April 2014, around 3 to 4 MW of PV systems had been installed on a decentralized level, with around 5 MW more under construction, all connected to the distribution grid under the net-metering scheme. It was estimated that more than 400 registered installation companies exist in Jordan, although only around 10 companies are actively doing business in the field for on-grid markets in early 2014. In addition, 12 projects with 170 MWp were to be constructed under the first round of Direct Proposals for PPAs that was initiated in October 2011. By April 2014 none of these projects had been realized yet, but negotiations were in their final stage, with financial closure to be accomplished by autumn 2014.<ref>GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.</ref><br/>In addition, two tendered PV projects, one totaling 2 MWp, financed by Spain in the Azraq area, and another totaling 65 – 75 MWp in Quweirah (Aqaba), financed through a fund of Abu Dhabi, were to be evaluated by the Ministry for Energy and Mining Resources (MEMR) in 2014.<ref>GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.</ref><br/>
  
Since 1998, efforts have been made to interconnect the Egyptian electricity grid internationally. As a result, the five-country interconnection of Egypt’s system with those of Jordan, Syria, Lybia and Turkey has been completed in 2002.<ref>EIA 2008. Energy Information Administration. Country Analysis Briefs – Egypt.</ref> Links to the European electricity market have been established through the sub-marine connection between Morocco and Spain (400 KV) and over the connection Syria –Turkey.
+
=== Hydropower ===
  
In April 2004, the Arab Maghreb countries agreed to repower the national grids of Egypt and Libya in order to upgrade the interconnection.In the fiscal year 2007 / 2008, the Egyptian Electricity Holding Company (EEHC) faced a challenge meeting the unexpectedly high peak demand, reaching 19 738 MW<br>  
+
Jordan has no notable bodies of flowing water suitable for the construction of hydroelectric power stations. The only such plant is at the King Talal dam on the Az Zarqa River, with a capacity of 5 MW. Another hydroelectric generating facility employs a turbine to exploit the head of the cooling water taken from the sea to cool a thermal power station in Aqaba as it flows back to the sea. In 2012, these two stations together generated 61 GWh of electricity and were therefore the source of 0.4% of the electricity generated in the country as a whole.<br/>
  
{| width="100%" cellspacing="1" cellpadding="1" border="1"
+
=== Biogas<br/> ===
|+ '''THE EGYPTIAN TRANSMISSION GRID, KEY FIGURES 2008'''
 
|-
 
| <br>  
 
| 500 kV<br>
 
| 400 kV<br>
 
| 220 kV<br>
 
| 132 kV<br>
 
| 66 kV<br>
 
| 33kv<br>
 
|-
 
| Transformer capacity (MVA)
 
| 7765<br>
 
| n.s.<br>
 
| 28850<br>
 
| 3427<br>
 
| 35223<br>
 
| 1769<br>
 
|-
 
| Total length of transmission lines<br>
 
| 2478<br>
 
| 33<br>
 
| 14912<br>
 
| 2429<br>
 
| 16986<br>
 
| 2713<br>
 
|}
 
  
''Source: EEHC 2008''<br>  
+
In cooperation with the United Nations Development Programme (UNDP), a project has been developed for utilising the methane gas that arises at the municipal waste disposal site in Amman. With the aid of the Global Environmental Facility (US$ 2.5 million) and the Danish development agency DANIDA (US$1.5 million), a biogas facility has been financed that captures the gases that arise at the landfill and uses a 1-MW generator to generate electricity for the interconnected power grid. The facility has been in service since 2000 and generates some 5 GWh of electricity annually. The installation is run by the Jordan Biogas Company, a joint stock company that is owned by the Central Electricity Generation Company (CEGCO) and the Greater Amman Municipality (GAM). Since 2001, the biogas sector has hardly been expanded; it produced about 6 GWh in 2012.<br/>
  
{| width="100%" cellspacing="1" cellpadding="1" border="1"
+
<br/>
|+ '''PEAK LOADS IN THE INTERCONNECTED ELECTRICITY GRID; 2003 – 2008'''
 
|-
 
| <br>
 
| 03/04<br>
 
| 04/05<br>
 
| 05/06<br>
 
| 06/07<br>
 
| 07/08<br>
 
|-
 
| Peak load (MW)<br>
 
| 14735<br>
 
| 15678<br>
 
| 17300<br>
 
| 18500<br>
 
| 19728<br>
 
|}
 
  
''Source: EEHC 2008''<br>
+
=== Biomass ===
  
== Installed Capacity  ==
+
Due to the arid climate, there is not a great deal of vegetation in Jordan. This obviously limits the potential use of vegetable biomass. The burning of vegetable biomass serves to a limited extent in rural regions for cooking and heating and is the main source of energy of the Bedouin in the desert. Great energy potential is to be found in household wastes (municipal solid wastes), which has an organic content of roughly 60%, and is estimated to add up to an annual total of 1.1 million tonnes. This equates to a daily per capita figure of between 0.35 and 0.95 kg of waste with a gross calorific value of 7-11 MJ/kg. The figures vary depending on the time of year and also differ between urban and rural regions.<br/>
  
Between 2003 and 2008, the total installed capacity increased about 24&nbsp;%, mainly through the added combined cycle and wind power installed capacity.
+
=== Geothermal Energy ===
  
In June 2008, the total installed capacity reached 22 583 MW, equivalent to a 2.9&nbsp;% increase compared to the previous year. Of this, conventional steam power stations accounted for 11 571 MW (51.9&nbsp;%), combined cycle power plants for 6 449 MW (28.9&nbsp;%), and hydropower stations for 2 842 MW (12.8&nbsp;%). Wind power plants provide the remaining 305 MW (1.3&nbsp;%). Since 2002 / 2003, three private-sector electricity utilities have been contributing 2 048 MW of generating capacity (9&nbsp;% of overall countrywide capacity in 2008) from three gas-fired steam power plants. According to the Ministry of Energy and Electricity’s five year plan from 2005, the installed capacity is to increase to a total of 32 GW by 2010.
+
Geothermal resources in Jordan have been identified mainly in two regions. That said, both the sources on the eastern banks of the Jordan Valley and those on the plateau to the east of Madaba offer comparatively low temperatures below 100°C. This means they cannot be used to generate electricity and will continue to be used for thermal purposes only, such as for heating swimming pools and greenhouses.<br/>
 +
<div>[[Jordan_Energy_Situation#Overview|►Go to Top]]</div><div><br/></div>
 +
== Electricity<br/> ==
  
Egypt has 35 decentralised power plants (mostly diesel units) that are not connected to the national grid. The combined installed capacities of these plants added up to 258 84 MW in 2007/2008. Approximately, 350 GWh of electricity were supplied to local users including tourist resorts.<br>  
+
=== Installed Capacity and Generation<br/> ===
  
{| width="100%" cellspacing="1" cellpadding="1" border="1"
+
In 2013, the Jordanian interconnected power grid was supplied by an installed power station capacity of 3,193 MW.<ref name="NEPCO (2014): Annual report 2013.">http://www.nepco.com.jo/store/docs/web/2013_en.pdf </ref> The generated and imported electrical energy amounted to 17,643 GWh in the same year. The available capacity development by type of generation since 2010 is outlined in table 2.<br/>
|+ '''HISTORIC DEVELOPMENTS INSTALLED CAPACITY BY ENERGY SOURCE 2003-2008'''
+
<p style="text-align: center;"><u>Table 2: Available capacity development by type of generation (in MW) 2010-2013</u><ref name="NEPCO (2014): Annual report 2013.">http://www.nepco.com.jo/store/docs/web/2013_en.pdf </ref><br/></p>
 +
{| style="width: 100%;" border="1" cellspacing="1" cellpadding="1"
 
|-
 
|-
| <br>  
+
| <br/>
| 2003-2004<br>  
+
| '''2010<br/>'''
| 2004-2005<br>
+
| '''2011'''
| 2005-2006<br>
+
| '''2012'''
| 2006-2007<br>
+
| '''2013'''
| 2007-2008<br>
 
 
|-
 
|-
| colspan="6" | &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; &nbsp; &nbsp;&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp;&nbsp; &nbsp;&nbsp;&nbsp; MW<br>
+
| style="text-align: right;" colspan="5" | '''MW'''<br/>
 
|-
 
|-
| Wind<br>  
+
| Steam<br/>
| 140<br>
+
| 925
| 140<br>
+
| 925
| 183<br>
+
| 925
| 225<br>
+
| 791
| 305<br>
 
 
|-
 
|-
| Gas<br>
+
| Gas turbine (diesel)
| 1019<br>
+
| 149
| 1537<br>
+
| 134
| 1966<br>
+
| 134
| 2416<br>
+
| 27
| 1416<br>
 
 
|-
 
|-
| Combined Cycle<br>
+
| Gas turbine (natural gas)
| 2605<br>
+
| 600
| 2699<br>
+
| 499
| 3949<br>
+
| 499
| 4949<br>
+
| 621
| 6449<br>
 
 
|-
 
|-
| Hydro<br>
+
| Combined cycle
| 2749<br>
+
| 1,317
| 2783<br>  
+
| 1,737<br/>
| 2783<br>
+
| 1,737
| 2783<br>
+
| 1,737
| 2842<br>
 
 
|-
 
|-
| Steam<br>  
+
| Hydro<br/>
| 11610<br>
+
| 12
| 11616<br>
+
| 12
| 11571<br>
+
| 12
| 11571<br>
+
| 12
| 11571<br>
 
 
|-
 
|-
| colspan="6" | &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
+
| Wind<br/>
 +
| 1.4
 +
| 1.4
 +
| 1.4
 +
| 1.4
 
|-
 
|-
| Total<br>
+
| Biogas
| 18123<br>
+
| 3.5
| 18775<br>
+
| 3.5
| 20452<br>
+
| 3.5
| 21944<br>
+
| 3.5
| 22583<br>
 
|}
 
 
 
''Source: EEHC 2008''<br>
 
 
 
== Electricity Generation  ==
 
 
 
{| width="270" cellspacing="1" cellpadding="1" border="1" align="right"
 
|+ '''ELECTRICITY CONSUMPTION BY SOURCE IN 2006'''
 
|-
 
| Economic Sector<br>
 
| GWh<br>
 
|-
 
| Industry<br>
 
| 34569<br>
 
|-
 
| Residential<br>
 
| 34596<br>
 
|-
 
| Commercial and Public Service<br>
 
| 11541<br>
 
|-
 
| Agriculture and Forestry<br>
 
| 3697<br>
 
|-
 
| Other<br>
 
| 12040<br>
 
 
|-
 
|-
| colspan="2" | &nbsp;
+
| colspan="5" | <br/>
 
|-
 
|-
| Total  
+
| Total
| 99443
+
| 3,008
 +
| 3,312
 +
| 3,312
 +
| 3,193
 
|}
 
|}
  
Egypt is a net exporter of electricity, importing 208 GWh of electricity in 2006, while exporting 557 GWh. Transmission and distribution losses account for approximately 10&nbsp;% (12 583 GWh) of total electricity produced.  
+
In addition to the power stations operated by the public utilities, there are also a number of industrial enterprises that generate electricity in their own plants. Some of these also feed excess electricity into the Jordanian interconnected grid. Since the amount of electricity generated in Jordan has for some years been insufficient to cover the country’s needs, additional power used to be imported from Egypt and Syria. However, due to the circumstances in the region, import has been stalled completely (Syria, since 2012) or reduced (Egypt).<ref name="NEPCO (2014): Annual report 2013.">http://www.nepco.com.jo/store/docs/web/2013_en.pdf </ref><br/>
  
In 2005, losses added up to 16&nbsp;% of total electricity supply. The main consumer of electricity in Egypt is the residential sector which accounts for 37&nbsp;% of the total consumption, followed close by the industrial sector (35&nbsp;%). A future average annual growth in electricity demand of 6.35&nbsp;% is expected, partly due to rising living standards and very low electricity prices. In order to meet the expected growth in demand, EEHC prepared the 6th five year plan (2008 – 2012). The plan entails adding electricity production capacity of 7 750 MW, while at the same time maximizing the use of combined cycle installations to reach a 37&nbsp;% share of the total installed capacity in 2011/2012. On 31 January 2009, the government has finalized the follow-up five-year plan from 2012 – 2017 which aims at adding further 10 450 MW generation capacity.
+
=== Consumption<br/> ===
  
{| width="100%" cellspacing="1" cellpadding="1" border="1"
+
The main consumer of electricity in Jordan is the domestic sector (including government buildings) which accounts for 43% of the total consumption, followed by the industrial sector (24%). Overall consumption has been steadily increasing in the recent years. The development of the electricity consumption per sector is outlined in table 3.<br/>
|+ '''GROSS ELECTRICITY PRODUCTION BY ENERGY SOURCE; EGYPT; 2000–2008'''
+
<p style="text-align: center;"><u>Table 3: Electricity consumption by sector (in GWh) 2008-2013</u><ref name="NEPCO (2014): Annual report 2013.">http://www.nepco.com.jo/store/docs/web/2013_en.pdf </ref><br/></p>
 +
{| style="width: 100%;" border="1" cellspacing="1" cellpadding="1"
 
|-
 
|-
| <br>  
+
| '''Sector<br/>'''
| 07/08<br>
+
| '''2008'''
| 06/07<br>
+
| '''2009'''
| &nbsp;%-change<br>
+
| '''2010'''
 +
| '''2011'''
 +
| '''2012'''
 +
| '''2013'''
 
|-
 
|-
| colspan="4" | &nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; GWh<br>
+
| style="text-align: right;" colspan="7" | '''GWh'''<br/>
 
|-
 
|-
| Steam<br>
+
| Domestic (incl. government buildings)
| 53076<br>
+
| 4,459
| 52082<br>
+
| 4,888
| 1.9<br>
+
| 5,225
 +
| 5,667
 +
| 6,126
 +
| 2,265
 
|-
 
|-
| Gas<br>
+
| Industrial
| 9361<br>
+
| 3,128
| 6888<br>
+
| 3,006
| 35.9<br>
+
| 3,262
 +
| 3,486
 +
| 3,461
 +
| 3,517
 
|-
 
|-
| Combined Cycle<br>
+
| Commercial
| 33345<br>
+
| 1,925
| 29892<br>
+
| 1,980
| 11.6<br>
+
| 2,187
 +
| 2,173
 +
| 2,427
 +
| 2,414
 
|-
 
|-
| Total Thermal<br>
+
| Water Pumping
| 95782<br>
+
| 1,713
| 88862<br>
+
| 1,772
| 7.8<br>
+
| 1,868
 +
| 1,899
 +
| 1,955
 +
| 2,076
 
|-
 
|-
| Hydro<br>
+
| Street Lighting
| 15510<br>
+
| 284
| 12925<br>
+
| 310
| 20<br>
+
| 315
 +
| 310
 +
| 305
 +
| 291
 
|-
 
|-
| Wind (Zafrana)<br>
+
| colspan="7" | <br/>
| 831<br>
 
| 616<br>
 
| 34.9<br>
 
 
|-
 
|-
| Total grid<br>
+
| Total
| 112123<br>
+
| 11,509
| 102403<br>
+
| 11,956
| 9.5<br>
+
| 12,857
|-
+
| 13,535
| Isolated plants<br>
+
| 14,277
| 350<br>
+
| 14,564
| 347<br>
 
| 0.86<br>
 
|-
 
| Purchased from IPPs<br>
 
| 14<br>
 
| 32.2<br>
 
| (56.5)<br>
 
 
|}
 
|}
  
''Source: EEHC 2008''<br>
+
<br/>
 
 
== Renewable Energies  ==
 
 
 
In 2006, renewable energy sources reached a share of 12.5&nbsp;% of total grid-connected electricity production. While 12 925 GWh (12&nbsp;%) were produced by hydropower installations, wind power contributed another 616 GWh (0.5&nbsp;%).
 
 
 
== Electricity Prices  ==
 
 
 
The prices of electricity in Egypt range among the lowest in the world. The prices are fixed by the Egyptian government in a non-transparent manner and apply in equal manner to all regions. Electricity is highly subsidized. Since October 2004, several electricity tariffs were raised, by an average of 8.6&nbsp;%, for the first time since 1992 and further 5&nbsp;% increases were set for all electricity customers for each of the following five years. The last increase took place in November 2008. In 2008, the rise summed up to 7.5&nbsp;%, including an additional 2.5&nbsp;%-increase caused by high oil prices. While the increase in some segments exceeded 18&nbsp;%, prices of the first segment of domestic consumption – less than 50 kWh per month, mainly composed of low income families –remained unchanged at 5 Pt (approximately 0.62 €-ct). The highest increase was seen for the residential consumers with a demand of &gt;1000 kWh/ month. The governmental plan was intended to gradually accommodate the electricity prices to the actual cost of the electricity system. However, taking into consideration annual inflation rates exceeding 5&nbsp;%, these increases may not suffice. The new electricity law is supposed to specify the main principles of price regulation such as the ones mentioned above.<br>
 
 
 
== Rural Electrification<br>  ==
 
 
 
Under the Egyptian government rural electrification programme, a countrywide electrification rate of 99&nbsp;% was achieved through grid extension projects. As assessed in a study by MEDREC<ref>MEDREC 2004. Mediterranean Renewable Energy Center: MEDREC Report 2004, available at: http://www.medrec.org/en/download/REPORT%20MEDREC%202004_egypt.pdf ; Retrieved on 10.09.2009</ref> in 2004, there have been approximately 121 remote villages and communities which still do not have access to electricity. The Rural Electrification Authority’s target for 2008 was to electrify 327 little settlements, the strengthening of 31 village grids and the refurbishment of 41 further grids.<ref>MoEE 2009. Ministry of Electricity and Energy. http://www.moee.gov.eg; Retrieved on: 02.09.2009</ref><br>For the few remaining remote settlements, the decentralized use of renewable energy resources is under consideration as an alternative to actual grid access. Due to the dispersed nature of both houses and rural communities, in addition to their low demand, the extension of the grid is economically unfeasible. The project MEDREP, a joint project being conducted by NREA, the governorate of North Sinai, the Egyptian environmental authorities, the Rural Electrification Agency (REA) and initiated by the Italian Ministry of Environment in 2004, aims at supplying electricity through photovoltaic to these remote rural communities as well as the utilization of solar thermal energy for heating and cooling purposes in tourist resorts and new villages.<ref>MEDREC 2004</ref><br>
 
 
 
= Market potential for renewable energies<br>  =
 
 
 
== Wind Energy<br>  ==
 
 
 
The current installed wind capacity accounts for 305 MW. Egypt is endowed with abundant wind energy resources, especially in the Suez Gulf zone. After the implementation of several experimental wind farm projects, the Ministry of Electricity and Energy set up an ambitious plan for wind farm development aiming at a total installed capacity of 965 MW in 2011/2012.<ref>EEHC 2008. Egyptian Electricity Holding Company (EEHC): Annual Report 2007/2008, Cairo 2008</ref><br>
 
 
 
Egypt has outstanding wind energy conditions. Particularly in the coastal regions, high and stable wind speeds are frequent (up to an average of 10.5 m/s in the Gulf of Suez). Furthermore, the country’s large deserts and abundant thinly populated areas are well suited for the construction of large wind farms.<br>
 
 
 
A detailed wind atlas has been compiled between 1998 and 2005 in a joint effort by NREA, the Egyptian Meteorological Authority (EMA) and the Danish UNEP research centre Risø. The purpose of the project was to establish a solid meteorological basis for evaluating the country’s wind resources. In addition to data records, the atlas also surveys the Egyptian wind conditions on the basis of wind models and offers detailed, meteorologically based information on site requirements for mediumsized and large wind farms. The Wind Atlas covers the entire country. However, particular attention was given to six promising areas: the Northwest Coast, the Northeast Coast, the Gulf of Aqaba, the Gulf of Suez, the Red Sea and the Western Desert. It is considered a reliable source of information and is used as the basis for all governmental <br>decisions related to wind energy project planning and feasibility studies.<br>A map of average wind speeds can be found in a study by Mortensen et al.<ref>Mortensen et al. 2006: Wind Atlas for Egypt: Measurements , micro- and mesoscale modelling. Proceedings of the Third Middle East – North Africa Renewable Energy Conference (MENAREC 3), Cairo, Egypt, June 12-14. 12 pp. (http://www.windatlas.dk/Egypt/About.html)</ref> For further information a wind atlas has been published by members of the Wind Energy Division at Risø DTU in Roskilde. ( www.windatlas.dk/Egypt/Index.htm) <br>
 
 
 
A special wind atlas36 for the Gulf of Suez was completed in 2003.<ref>Mortensen et al. 2003: Wind Atlas for the Gulf of Suez. Measurements and Modelling 1991-2001, New andfckLRRenewable Energy Authority, Cairo, and Risø National Laboratory, Roskilde 2003</ref> The assessment determined an overall potential capacity of 20 000 MW for wind power projects in the uninhabited desert regions to the west of the Gulf. A further brief study evaluated the meteorological data gathered from ten weather stations situated along the Mediterranean coast.<ref>Shata, A.S. Ahmed: Evaluation of wind energy potential and power production on the coast of Mediterranean Sea in Egypt, Faculty of Electrical Engineering and Computer Science, Institute of Energy and Automation Technology, Technical University Berlin, 2006.</ref> Three locations – Sidi Barrani, Mersa Matruh and El Dabaa – were founded to also exhibit suitable characteristics for the installation of wind turbines. The atlas further indicates that large regions of the eastern and western deserts of the Nile River and parts of Sinai are much higher then hitherto assumed.<br>
 
 
 
=== Framework Conditions for Wind Energy<br>  ===
 
 
 
Within the scope of the Renewable Energy Strategy, 12&nbsp;% of total electricity supply by 2020 are to be generated by wind power, translating into more than 7 200 MW of gridconnected wind farms. In order to reach these targets, in February 2008 the Egyptian Supreme Council of Energy approved a plan to build 600 MW installed wind capacity per year during the next 12 years, totalling 7 200 MW in 2020. The private sector is targeted to play a key role in achieving the 2020 goal. The government anticipates that<br>about 400 MW/year will be developed by the private sector, while the NREA will carry out about 200 MW/year. Energy intensive industries are especially encouraged to build and invest in wind warms in order to satisfy their own electricity needs or to sell electricity to consumers via the national grid. The NREA made its first call for proposals in June 2009 (prequalification round). In order to meet the target laid down in the strategy, the government called for 250 MW of wind power this year, to be build on a build-own-operate basis (BOOT) by private actors.<br>
 
 
 
=== Licensing Procedures  ===
 
 
 
The Egyptian Electric Utility and Consumer Protection Regulatory Agency has prepared rules and procedures for obtaining generation, transmission and distribution licenses.<ref>EEUCPRA 2009.Egyptian Electric Utility and Consumer Protection Regulatory Agency (www.egyptera.com/ene-licenses_general_Conditions.htm) Retrieved on 09.09.2009</ref> Approval requires a technical and economic feasibility study. The license is valid for a duration of five years and is to be renewed after that. At the end of each year, the license has to be verified. In case of non-compliance with the terms of the license, a penalty procedure was established. The licensee has the right to access the transmission or distribution grids in accordance with a contractual agreement between him and the transmission or distribution company. The Agreement has to be approved by the Agency. The licensee is further obliged to provide an annual report on the licensed activities. The requests for licenses with detailed information on the licensing procedures as well as model framework contracts with distributers and ransmission companies can be downloaded from the Agency’s omepage. The conditions for issuing, amending, suspending, terminating and withdrawal of permits, however, are not sufficiently specified. The transmission and distribution codes lay down the standard specifications for design, construction, modification, operation and maintenance for all generation and distribution assets associated with the transmission grid. The transmission companies have to comply with the transmission code, as well as with performance standards acceptable to the agency, in order to verify the quality of electrical supply and the degree of reliability.<br>
 
 
 
=== Business Climate<br>  ===
 
 
 
In general, the present conditions for the wind energy sector in Egypt are favourable. Recent analysis from the World Economic Forum and the World Bank indicates that in spite of the global economic crisis, the country competitiveness is increasing and provides favourable conditions for private companies to set up business operations. Measures to remove existing barriers in the electricity sector are being implemented. However, a number of barriers associated to electricity prices and the availability of skilled personnel still remain.<br>The impact of the global economic crisis on the Egyptian economy has been relative low and in spite of the low growth dynamic, there are no signs of an economic slump.<br>Measures to cop with the global crisis will positively influence the availability of proper infrastructure for wind electricity transmission and distribution, one of the barriers for the expansion of the sector so far. The government plans to invest around 100 to 120 million $ in the expansion of high voltage grid from Gulf of Suez to Cairo. On the other hand, the impact of the global crisis may also interfere with the efforts of the Egyptian government to deal with the non competitive prices of renewable electricity (see Chapter 1.5). For example, the government has frozen the industry electricity prices until the end of 2009 as a measure to stimulate the economy.<ref>Auswärtiges Amt. Ägypten: Beziehungen zu Deutschland. http://www.auswaertiges-amt.de/diplo/de/Laenderinformationen/Aegypten/Bilateral.html#t3. Retrieved on 8th September 2009.</ref><br>
 
 
 
Within the framework of the energy liberalization process (see Chapter 1.4), and in part as a response to the global crisis, the government strives a greater involvement of the private sector in public projects as well as to intensify private investment. European companies such as Gamesa, have provided so far, most of the wind turbines to the projects at Zafarana. In total, the NREA has ordered 405 MW wind turbines from the Spanish company. Recently, Gamesa won an international tender, a 279 million € contract to supply NREA 284 wind turbines with a total capacity of 241 MW. Gamesa delivers turnkey products while the civil and electrical engineering, together with tower manufacturing is contracted locally.<br>
 
 
 
NREA encourages local manufacturing of turbines and other components based on e.g. technology transfer or joint ventures. Previous experience has been gained with small-scale manufacturing of wind turbine components. As of 2005, also repairs and rewinding of generators have been carried out by local companies. The global cable and electric products manufacturer El Sewedy Cables is supposed to start producing turbine towers locally (at Ain El Sokhna) this year in a 50 – 50 joint venture (called SET) with German tower manufacturer SIAG Schaaf Industrie AG. The facility is part of El Sewedy's broader strategy to set up a fully fledged wind farm supplier that assembles<br>and manufactures wind turbines in Egypt. In 2008, the company bought a 30&nbsp;% stake in M Torres Olvega, a small Spanish company producing direct-drive wind turbines for 40 million €, including an option to buy the remaining 70&nbsp;% by March 2011. The company expects to roll out 111 units in 2010 and 256 in 2012 respectively. In the first year, a production of 50 turbines (83 MW) is planed, 225 (435 MW) turbines will be produced in the following four years.<br>
 
 
 
Conditions for private sector to access the wind energy market are favourable and will probably be improved in the near future. As shown in Chapters 1.4 and 1.5, there is a package of instruments in the new electricity law that aim to facilitate the access to the markets. This will support the goal of meeting 87&nbsp;% and 73&nbsp;% of the renewable electricity target in the years 2010 and 2010 through private financed projects. Previous experiences, for instance in the gas sector, have been in general positive. The Egyptian government has demonstrated to be a credible partner. So far, one private company has expressed its interest in developing wind energy projects (see Current Use of Wind Energy and Project Pipeline). The tender process is currently taking place.<ref>Suding 2009. CDM in Egypt: Potentials and Projects. GTZ. MENA Carbon Forum May 2009</ref><br>
 
 
 
Independently of the crisis, a remaining obstacle for the development of the wind electricity sector is the availability of skilled workers, which is influenced by two main factors: the lack of specialized study programs and the emigration of well qualified personnel.In general, Egyptian universities and educational institutions do not offer programs that suit the needs of the wind sector, such as advanced studies in mechanical and electrical engineering. Although, there are some initiatives, supported for instance by the GTZ and the Federal Ministry for Economic Cooperation and Development (BMZ), to reform curricula, the process to adapt them is rather slow compared to the fast development in the wind sector. As for the emigration, well qualified Egyptian engineers and technicians usually prefer to work abroad, especially in the Middle East, where loans and economic benefits are substantially better than in Egypt. This may become particularly critical for NREA, since its loans are rather low compared to the private sector.<br>
 
 
 
<br>
 
 
 
== Solar Energy  ==
 
 
 
Solar energy use is still in its infancy, however, in 2007, the German company Flagsol GmbH won a tender to build a hybrid solar combined cycle plant with a total gross capacity of 150 MW.7 The solar field is located at Kuraymat and is co-financed by the Global Environmental Facility (GEF) and the Japanese Bank for International Development. Commercial operation is scheduled for mid 2010. Egypt plans to extend the solar capacities with further projects of this kind.<ref>Solar Millenium AG 2008</ref><br>
 
 
 
== Biogas  ==
 
 
 
Type your text here<br>
 
 
 
== Hydro Power  ==
 
 
 
The total installed capacity from hydropower accounted for 2 842 MW in 2008. Hydropower installations include High Dam (2 100 MW), Aswan Dam I (322 MW), Aswan Dam II (270 MW), Esna (86 MW). urrent hydro power projects include the New Hammasi plant with an installed capacity of 4 x 16 MW, which started operations in 2008. For 2014, the commissioning of the New Assuit Barrage hydro electricity plant, with an installed capacity of 32 MW, is projected.
 
 
 
== Other renewable Sources  ==
 
 
 
Type your text here<br>
 
 
 
= Political Framework Conditions in the Energy Sector<br>  =
 
 
 
Egypt has a national energy strategy, although only adopted at the level of the energy policy committee of the governing party. The strategy covers the diversification of the energy mix, higher energy efficiency, a reform of the electricity and the oil and natural gas markets and reduction of energy subsidies. The renewable energy strategy is a fundamental part of the national energy strategy.<br>
 
 
 
The diversification of the energy mix in the electricity sector is one of the main goals of the energy strategy. It aims to reduce the consumption of fossil fuels while increasing the share of renewable energy sources and giving a new impulse to the nuclear electricity program suspended in the 1980s. In February 2008, the government set a new ambitious target of 20&nbsp;% renewable energy in electricity production by 2020 excluding existing large hydro power plants.<ref>JCEE 2009 - Egyptian-German High Level Joint Committee for cooperation on renewable energy and energy efficiency and environmental protection http://www.jcee-eg.net Retrieved on 8th September 2009</ref> Although no nuclear electricity generation targets have been set, the government launched a nuclear electricity plan in 2007. First steps to implement it have already been taken.<ref>ESIS 2008 - Egypt State Information Service. Egypt on the Threshold of a Nuclear Age. (http://www.sis.gov.eg/En/Pub/magazin/winter2008/110235000000000015.htm) Retrieved on 10th September 2009; NPPA 2009 - Nuclear Power Plants Authority. Egyptian Nuclear Program. Technical meeting on invitation and evaluation of bids for nuclear power plants. (http://www.iaea.org/NuclearPower/...F/.../Egypt_Ali_Abd_El_Nabi.pdf) Retrieved on 8th September 2009</ref><br>
 
 
 
Improving energy efficiency is a fundamental part of the strategy as well. It aims at tackling the fast growth of primary energy consumption, which tends to grow as rapidly as or even higher than real economic growth. Although numerous regulations exist for the main energy consuming sectors, implementation and enforcement is often quite low.<ref>JCEE 2009</ref><br>
 
 
 
The policy on energy subsidies has changed due to the reduction of oil reserves and the financial problems associated with the existing schemes. The domestic natural gas and electricity prices have been adjusted in 2008 in order to cover at least the cost of service. Subsidies are being reduced gradually, first in energy intensive industries, and second in the tourism sector, though energy subsidies for the average consumer are not expected to change significantly.<ref>JCEE 2009; Marquer 2009. Egypt moves towards renewable energy. In: Business monthly, April 2009.</ref><br>
 
 
 
With regard to the energy market, the adopted energy strategy aims to establish a fully competitive structure, where electricity production, transmission and distribution activities are fully unbundled. The strategy should also create favourable conditions to achieve the 20&nbsp;% renewable energy in electricity production.<ref>El-Salmawy 2009. Renewable Energy Strategy for 20/20 and Regulatory Framework. Egyptian Electric Utility and Customer Protection Regulatory Agency. (http://www.jcee-eg.net/libdetails.asp?typeID=4)</ref><br>
 
 
 
<br>
 
 
 
== Liberalisation<br>  ==
 
 
 
Article 7 of Law No. 100 dating from 1996 stipulates that local and international investors can obtain concessions for building and operating electricity plants. A new investment law enacted in 1997<ref>Spohn, Hans-Dieter et al. 2009: Egypt – Business Guide (http://www.ghorfa.de/pdf/BusinessGuide_Aegypten.pdf ) Retrieved on 16th October 2009</ref> includes various incentive mechanisms such as state guarantees for investors. At the time of contract negotiations concerning the supply of electricity from privately built power plants in the late 1990s, an initial public offering of stock in all seven of Egypt’s state-owned monopolistic electricity providers was in preparation for the Egyptian stock exchange. However, due to lack of interest among investors, the plan was never implemented. The last significant step of reform took place in 2000, when the Egyptian Electricity Authority was restructured to become the Egyptian Electricity Holding Company (EEHC). That conversion is regarded as a step towards a more entrepreneurial approach because, for example, EEHC is expected to finance future projects from its own budget without governmental intervention. The conversion also included the break-up of formerly vertically integrated utility companies into individual enterprises each of which is now an independent company with its own, autonomous management and separate accounting. EEHC was created as a new approach to the privatization of its subsidiaries, but no part of any state-owned enterprise has been privatized by now. Via EEHC, the Egyptian government still controls 90&nbsp;% of all electricity production and is maintaining its monopoly on transmission and distribution. Until today three privately operated power plants with foreign investors have been built according to the build-own-operate (BOO) principle (Sidi Krir, Suez and Port Said), representing approximately 10&nbsp;% (2 049 MW) of the current installed generating capacity.<br>
 
 
 
Within the context of the new energy strategy and the ambitious renewable energy targets, recently, there has been some effort to create a more competitive electricity market in order to attract investors from the private<br>sector. The draft of the new Electricity Law, which is currently in the process of ratification by the People’s Assembly, is supposed to establish a liberalised electricity market, regulated by the Egyptian Electric Utility and Consumer Protection Regulatory Agency EEUCPRA. Article 20 – 22 of the draft law addresses the replacement of the current Single Buyer Model and allows for third party access to the electricity grid. The access to the electricity grids will be based on published tariffs and longterm electricity purchase agreements. Moreover, the government states that it plans to remove all energy subsidies by 2017.<br>
 
 
 
== Important Laws and regulations  ==
 
 
 
The most important instrument to implement the energy strategy is the New Electricity Law, which is currently in the process of ratification by the People’s Assembly. The new law will<ref>JCEE 2009; Ministry of Electricity and Energy. Strategic Plan in the Electricity Sector in Egypt. Prequalification Developers’ Meeting of BOO Wind Power Project 250 MW. Cairo 2009.</ref>:<br>
 
 
 
*Establish a liberalized electricity market with various market participants, regulated by EEUCPRA
 
*Improve the conditions for renewable energy, cogeneration and demand side management in the electricity sector
 
*Provide some rules for electricity consumption and includes measures to encourage renewable energy electricity production.
 
 
 
With regard to renewable energy electricity generation, the law foresees that the private sector builds, owns and operates the projects and sells the electricity to the transmission company (EETC) under long term Power Purchase Agreements (PPA). Non-renewable energy based Independent Power Producers (IPPs) conclude bilateral purchase agreements with eligible consumers.<br>
 
 
 
== Framework Conditions for Renewable Energies  ==
 
 
 
=== Strategy and objectives for renewable energies  ===
 
 
 
Egypt’s renewable energy strategy was formulated in the early 1980s as an integral part of the national energy planning. This strategy has been revised and adapted according to the changing financial, market and technological framework conditions. The target of a 20&nbsp;% renewable electricity by 2020 (around 12 000 MW) is highly ambitious compared to the previous target set in 2000 of 14&nbsp;% RE-E by 2021/22.<ref>El-Salmawy 2004. Egyptian Power Sector Reform and New Electricity Law. EEUCPRA.</ref>
 
 
 
=== Legal conditions and support Schemes for renewable Energies  ===
 
 
 
To implement the strategy, a two phase policy is planned:<br>
 
 
 
*Phase 1 will adopt competitive bids through issuing tenders requesting the private sector to supply electricity from renewable energy sources. A PPA agreement, mostly for 20 years, will be guaranteed. This competitive bidding is based on existing law, which also supports the existing IPP.
 
*In Phase 2, a feed-in-tariff will be implemented, in particular for medium and small size projects. This will be based on the new electricity law.
 
 
 
Further support instruments are the right of access and priority dispatching for electricity generation from renewable sources, which is already implemented, whenever they are available and the establishment of a Renewable Energy Fund. This fund will support the renewable energy activities of the MEE and the MoP covering the deficit between the renewable energy costs and market prices as well as providing financial support to pilot projects. It will be mainly financed through a levy on subsidized fossil fuel sales for electricity generation.<ref>El-Salmawy 2009; JCEE 2009</ref><br>
 
 
 
Competitive bids<br>
 
 
 
It is planned to tender a total of 2 500 MW through five bids, divided in blocks of 250 MW. The framework criteria for the tenders include:<br>
 
 
 
*Controlled increase of the renewable based electricity capacity according to the capacity of transmission system and the capacity of the market.
 
*Attracting highly qualified international developers with strong financial status and high capacity for technology transfer.<br>
 
*Promotion of local manufacturing. In the evaluation of the proposals, advantages will be given to those offers having higher share of locally manufactured components.<br>
 
*Achieving the lowest possible prices.<br>
 
*Reducing the financial risk for investors guaranteeing long term PPAs (mostly of 20 years). The first process has started with a prequalification tender for 250 MW in Gabal el Zeyt. The last tender will be opened by 2017.<br>
 
 
 
Feed-in-tariff<br>
 
 
 
The system is supposed to offer incentives to install 2 500 MW of additional capacity. It is addressed to small and medium size projects up to 50 MW. The tariff will be probably set for 15 years, taking into consideration wind speed and installed capacity. The system is still under elaboration.<br>
 
 
 
=== Clean Development Mechanism<br>  ===
 
 
 
Egypt’s Designated National Authority (DNA) was established in 2005, serving as the contact point for all CDM-related matters. Organizationally, it is part of the Egyptian Environmental Affairs Agency (EEAA). Egypt’s current climate change mitigation policies, plans and measures relevant to CDM are contained in:
 
 
 
1. The National Environmental Action Plan (2002 – 2017).<br>2. Egypt’s Climate Change National Action Plan (ECCNAP).<br>3. Egypt’s National Strategy Study Program on CDM.<br>4. Egypt’s National Energy Efficiency Strategy (NEES)<br>Currently, four CDM projects are registered. Minor corrections have been requested for one project. In April 2009, 18 projects were in the DNA pipeline, of which nine were renewable energy<br>projects. The CDM potential in Egypt has been estimated at 69.75 Mt CO2eq, of which around 21&nbsp;% is in the renewable energy sector.27 As shown in table 10, the total annual savings of the registered RE projects amounts to 0.62 Mt CO2eq. This represents 5&nbsp;% of the existing potential<br>in the renewable energy sector and around 1&nbsp;% of the whole potential.<ref>Deutsche Gesellschaft für Technische Zusammenarbeit (GTZ) GmbH, Energy-policy Framework Conditions for Electricity Markets and RenewablefckLREnergies: 16 Country Analyses, Eschborn 2009, page 186.</ref><br>
 
 
 
= Institutional Set-up in the energy sector  =
 
 
 
== Egyptian Ministry of Electricity and Energy  ==
 
 
 
The first Ministry for Electricity and Energy was established in 1964. The Ministry supervises the Egyptian Electricity Holding Company as well as the New and Renewable Energy Agency (NREA) and the Rural Electrification Authority (REA). Next to supervising all activities related to energy projects, it suggests electricity prices and publishes data and statistics relating to electricity production.<br>
 
 
 
== Regulatory authority EEUCPRA<br>  ==
 
 
 
The Egyptian Electric Utility and Consumer Protection Regulatory Agency (EEUCPRA) was established by decree in 1997 (Decree no. 326 of 1997:&nbsp;»Establishing the electric utility and consumer protection regulatory agency«).The regulatory authority is located in Cairo and came into formal existence in 1998.<br>
 
 
 
The primary task of the regulatory authority is to balance the interests of electricity producers, electricity providers and end users. It is supposed to ensure a reliable longterm supply of electricity while promoting and supervising environmental protection and operational reliability in the energy sector. It is also responsible for licensing the construction and operation of electricity generation, transmission and distribution facilities as well as for electricity trading. One of the authority’s declared objectives is to create an enabling environment for market-based competition within the framework of existing laws and to prevent the formation of commercial monopolies in the energy sector. EEUCPRA's Board of Directors is nominated by the Ministry of Electricity and Energy.<br>
 
 
 
== New and Renewable Energy Authority (NREA)<br>  ==
 
 
 
The Ministry of Electricity and Energy established the NREA in 1986 for the purpose of bundling activities aiming to promote both renewable sources of energy and energy efficiency. NREA is the operator of all wind power installations in Egypt, including the demonstration projects in Matrouh administrative district (hybrid wind/diesel system) and Hurghada (5.5 MW wind farm), as well as the grid connected Zafarana wind farms on the Gulf of Suez (reaching 425 MW by mid 2009 and still expanding).<br>  
 
  
With the new general orientation towards private sector involvement, NREA also engages in supporting private investment in wind energy by providing resource assessment, the necessary data for feasibility studies and technical support for potential project developers, and by being the partner in land use agreements.<br>  
+
=== Grid<br/> ===
  
Moreover, the NREA has a central laboratory for testing and certifying apparatus and equipment for utilizing renewable energy resources. Finally, the NREA offers training and upgrading courses, organises workshops and conducts studies – both on its own and in cooperation with international partner organisations.<br>  
+
The Jordanian national interconnected grid transmits electricity from the power stations to the distribution substations and transformer substations in the various regions of the kingdom via 400-kV and 132-kV power lines. The star topography of the grid has a clearly identifiable north-south axis, along which the only 400-kV power line runs, from Aqaba in the south via Amman and up to the Syrian border. The only area in which the grid has a ring-shaped configuration is around the capital city. In the north, the power grid is connected to the Syrian grid by means of a 230-kV and a 400-kV power line. In the south, there is a 400-kV connection to the Egyptian grid. The interconnected grid feeds the local distribution systems via which almost the entire population of Jordan receives its electricity. The overall length of the installed high voltage power lines (132 kV and 400 kV) is around 3,400 km. The National Electric Power Company (NEPCO) is planning to develop a new high voltage transmission network, called “green corridor”, running South-North in order to reinforce the electric grid. The project was initially planned for 2015, but due to delays it seems that it will be not be operational before 2018.<ref>http://www.invest-export.irisnet.be/documents/16349/1140680/2014+-Jordan+-+Renewable+energy+prospects.pdf/eb6cb1ff-a6d9-4d7c-804f-13b68877d86d</ref><br/>
  
== Egyptian Environmental Affairs Agency (EEAA)<br> ==
+
=== Electricity Prices<br/> ===
  
The EEAA was initially established in 1982 and restructured in 1994, according to Law 4/1994. The EEAA serves as the executive arm of the Ministry of State for Environmental Affairs (MSEA). Its administrative council is composed of the Minister of Environmental Affairs, the Chief Executive Officer of the Agency and representatives from relevant ministries, Non-Governmental Organisations (NGOs), the public business sector, universities and research centres. The Agency’s activities are financed by the Environmental Protection Fund (EPF), which is funded by donations and grants by national and foreign organizations, as well as fines and compensation awarded by courts of law. Principal functions of the agency include the formulation of environmental policies, the development and monitoring of projects and the implementation of pilot projects. The agency is further the national authority in charge of promoting environmental topics between Egypt and third parties.  
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The electricity tariff structure in Jordan takes into account social aspects as well as the economic capacities of consumers. In 2014, the electricity prices for the end consumer ranged from JD 0.033 per kWh for small residential consumers with less than 150 kWh per month demand to JD 0.292 per kWh for the banking sector. In 2012, the generation and distribution costs were JD 0.146 per kWh, whereas the average selling price was JD 0.0636 per kWh. The difference in price had to be covered by the state-owned National Electric Power Company (NEPCO), thereby creating a substantial deficit of JD 2.3 billion by the end of 2012. In order to reduce the losses, a National Strategic Plan has been developed. It foresees the adjustment of electricity tariffs and other measures to enhance the efficiency of the electricity system. By the end of 2017, NEPCO is supposed to be able to cover its costs. The plan prescribes the electricity price development for different consumer categories until the year 2017. Nevertheless, electricity is subsidized for many categories, e.g. for consumers with low electricity consumption.<ref>GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.</ref><br/>The electricity tariff schedule for the period from 2013 to 2017 is available here: [http://www.memr.gov.jo/LinkClick.aspx?fileticket=PHxs463H8U0=&tabid=255 http://www.memr.gov.jo/LinkClick.aspx?fileticket=PHxs463H8U0=&tabid=255]<br/>[[Jordan_Energy_Situation#toc|►Go to Top]]<br/><br/>
  
== Egyptian Electricity Holding Company (EEHC)  ==
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<br/>
  
The government-owned and operated Egyptian Electricity Holding Company (EEHC) coordinates, supervises and monitors the activities of its 16 (+1 - Includes NREA –actually a research institute – also presents itself as the operator of the Zaafarana wind farm-therefore included as a electricity production company) affiliated companies in the field of production, transmission and distribution of electric energy. The EECH subsidiary EETC is responsible for the countrywide transmission of electricity to regional and local distributors. Next to the EETC, there are six generating and nine distribution companies. The EEHC is supervised by the Egyptian Ministry of Electricity and Energy (MEE).<br>  
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= Energy Policy<br/> =
  
== Egyptian Wind Energy Association (EGWEA)  ==
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== General Information<br/> ==
  
The EGWEA is the umbrella organisation, representing the wind energy sector in Egypt. It assists interaction and co-operation between all relevant players with professional involvement in the field of wind energy. The EGWEA is organised in a global network of wind associations. It aims at promoting and supporting the development of wind energy in Egypt by providing the means to facilitate the exchange of technical information, expertise and experience in the wind energy sector. It conducts studies, provides information on tenders and conferences and organises workshops for interested parties. IEGWEA is particularly interested in bringing forward wind energy interests of Egypt. However, the association is also engaged in the promotion of wind energy in developing countries in general.<br>  
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More than 96% of energy resources have to be imported. That is why, from an economic point of view, it is important for NEPCO as well as for consumers paying high prices for energy to look for cheaper alternatives of electricity supply. This is especially true since the overall political situation in the region remains unstable, making the option of cheap gas or electricity imports less probable in the near to mid-range future. Alternative energy sources such as shale oil or nuclear power require at least several years of exploration and development activities before deployment, and the LNG terminal for gas in Aqaba is still under construction. A growing population and the corresponding increase in energy consumption require solutions that can quickly generate additional electricity capacities.<ref>GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.</ref><br/>[[Jordan_Energy_Situation#toc|►Go to Top]]<br/><br/><br/>
  
== International donor activities<br> ==
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== Renewable Energy Policy<br/> ==
  
Egypt is one of the priority partner countries of the German development assistance. In the last 50 years, Egypt has received approximately 5.5 billion € development aid. The current focus areas of the bilateral cooperation are water management, renewable energies (wind, solar and<br>hydro power), energy efficiency and climate protection.<ref>KfW. Landesinformation Ägypten. (http://www.kfwentwicklungsbank.de/DE_Home/Laender_Programme_und_Projekte/Nordafrika_und_naher_Osten/Aegypten/Landesinformation.jsp) Retrieved on 8thfckLRSeptember 2009.</ref> Within the framework of the German development cooperation, two initiatives to promote renewable energies<br>and energy efficiency were launched in 2008:<br>  
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As a general rule, the issuing of licenses is regulated by the '''General Electricity Law''', Article 28 onwards. In conformance with this law, the regulatory authority issues licenses to firms that wish to generate, distribute or sell electricity. Generating plants with a capacity of up to one megawatt are allowed to operate without a license. Local supply networks with a capacity of max. 100 kW can be operated without a license, in the same way as power plants that are used solely to generate electricity for self-consumption. Power supply companies or middlemen who want to purchase electricity from a power station with a capacity greater than 5 MW may conclude appropriate supply contracts only after competing in a public tendering process (Article 35). These rules apply equally to conventional thermal power stations and stations that generate electricity from renewable energy sources.<br/>To develop renewable energy capacities, a number of support mechanism have been introduced. For example, under the Jordanian '''net-metering scheme''', the excess electricity fed into the grid is credited for later consumption. This excess electricity that is credited can be used to offset electricity used at other times, when there is little or no PV electricity production (e.g. at night). The legal basis for net-metering is the 2012 '''Renewable Energy and Energy Efficiency Law No. 13 (REEL)'''. The REEL as well as bylaws enable Independent Power Producers (IPP) to provide electricity from renewable sources to NEPCO within long-term Power Purchase Agreements (PPA). Private investors may also invest in their own PV system up to 5 MWp to directly consume the electricity produced and offset it against their entire demand within a net-metering scheme. The REEL even allows the generation of electricity at a different site than where the actual consumer is located – so-called energy wheeling. As a result, there are two promising business cases that enable investments in renewable energies: Direct Proposals for PPAs under consecutive rounds of “expressions of interest” and net-metering.<br/>The Government has being attempting for a long time now to conclude contracts with '''Independent Power Producers (IPP)''' with the aim of expanding the number of power stations in Jordan’s electricity generating system. Initially, it made only slow progress. A number of potential projects were abandoned. Now, IPP projects with a total generation capacity of 740 MW (conventional energy) have been implemented. The IPP model is also used for renewable energy plants. However, by June 2014, no renewable energy plants had been constructed under the first round of the tender scheme and the following two rounds of direct proposals. In the first round, initiated in 2011, PPAs covering 170 MWp of solar PV were initially signed between 12 IPP companies or consortia and the Ministry for Energy and Mining Resources (MEMR). Until April 2014, these were in the process of financial negotiations between investors and the potential IPPs. Those systems were due to be constructed and connected to National Electric Power Company’s (NEPCO) transmission lines within the next 16 months. In the following two rounds of direct proposals, another 400 MWp of solar PV systems had been tendered for direct proposals, including four 50 MW plants and two 100 MW plants.<ref>GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.</ref><br/>In 2007, Jordan updated its '''[http://www.memr.gov.jo/Portals/0/energystrategy.pdf Master Strategy for Energy]''' for the period of 2007 to 2020, which had initially been drafted in 2004. The strategy aims at reducing energy imports through diversification of the energy mix by using local resources such as shale oil, nuclear power and renewable energies. Although at the moment the strategy still serves as a guideline for renewable energies, its assumptions can be considered to be outdated, especially since it assumes that nuclear and shale oil will cover a considerable share of Jordan’s energy demand by 2015 and 2020.<ref>GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.</ref><br/><br/>
  
*The Regional Center for Renewable Energy and Energy Efficiency (RCREEE), based in Cairo. Key development partners in setting up RCREEE are Egypt, Germany, Denmark and the EU Commission. Besides Egypt, other Arab members of the RCREEE are Algeria, Jordan, Lebanon, Libya, Morocco, the Palestinian National Authority, Syria, Tunisia and Yemen. RCREEE formulates and disseminates policies in support of RE and EE in the region and provides a platform for the regional exchange on policy issues and technological questions. In addition, RCREEE encourages the participation of the private sector to promote the establishment of a regional RE and EE industry. The German development cooperation provides assistance for the establishment of the Center and the formulation of the initial work program by GTZ.<ref>RCREEE 2009. -Regional Center for Renewable Energy and Energy. (http://www.rcreee.org/about.asp) Retrieved on 8th September 2009.</ref><br>
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== Energy Efficiency Policy<br/> ==
*The Egyptian-German High Level Committee on Renewable Energy, Energy Efficiency and Environmental Protection JCEE, is a bilateral Egyptian-German initiative. The JCEE is a platform for energy policy discussion, for developing initiatives for investment as well as institutional projects, awareness and capacity building activities and establishing contacts and exchange between the two countries. The project is financed by the Egyptian Ministry of Electricity and Energy and the German Federal Ministry of Economic Cooperation and Development (BMZ). The implementing partners of the cooperation are NREA and GTZ.<br>
 
  
In addition, financial assistance is provided by the German Kreditanstalt für Wiederaufbau (KfW). Kf W provided a reduced interest loan to rehabilitate the hydro electricity plants at Aswan and additional loans for the construction of medium sized hydro electricity projects at the Nile River. In the wind energy sector, Kf W provided loans to finance an important part of the wind farm in Zafarana and is supporting a new wind farm in Gabal El Zeit through loans jointly with the European Investment Bank.<br>  
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In the [http://www.memr.gov.jo/Portals/0/energystrategy.pdf Master Strategy for Energy] in Jordan for the period of 2007 to 2020 there are also several recommendation concerning energy efficiency. These include the implementation of energy consumption efficiency programs in different sectors, broad awareness campaigns on the energy consumption rationalization, tax exemptions for energy saving equipment, thermal insulation of buildings and a national award in the energy consumption rationalization domain.<br/>Jordan also introduced a [http://www.rcreee.org/sites/default/files/plans_jordanian_neeap_summery_2013.pdf National Energy Efficiency Action Plan (NEEAP)] which is in the process of adaptation. The NEEAP gives a national indicative target of 20% energy reductions by 2020 and six sectorial targets.<br/>[[Jordan_Energy_Situation#toc|►Go to Top]]<br/>
  
Apart from Germany, Denmark, Japan, Spain and Italy are the most important partners providing assistance for developing renewable energies.<br>  
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= Key Actors in the Energy Sector<br/> =
  
At European level, a Memorandum of Understanding to enhance EU-Egypt energy cooperation was signed in December 2008. The priority areas covered are, among others, the development of the Egyptian energy strategy, including the market reform, the convergence of Egypt’s energy market with that of the EU, the promotion of renewable energy and energy efficiency, the development of energy grids as well as technological and industrial cooperation.<br>  
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== Governmental Bodies and Agencies<br/> ==
  
Financial and technical assistance is provided by international organizations as well. These include the World Bank, the UN organisations UNDP, UNIDO and UNEP as well as the African Development Bank. For instance, Egypt is one of the first countries to present a portfolio within the framework of the Clean Technology Fund established by the World Bank in 2008 to finance RE and EE projects. Egypt plans to use $300 million in concessional financing from the fund, blended with financing from the World Bank Group, the African Development Bank, bilateral development agencies, private sector and other sources to spur wind power development and introduce clean transport options. The projects include a transmission grid extension for transporting electricity from Gulf of Suez-based wind farms.<ref>World Bank 2009. Egypt: Renewable Energy and Clean Transport Are Cornerstones of Low Carbon Growth. In: News and broadcast. June 5, 2009. (http://web.worldbank.org/WBSITE/EXTERNAL/NEWS/0,,contentMDK:22203619~pagePK:64257043~piPK:437376~theSitePK:4607,00.html) Retrieved on 10th September 2009.</ref><br>  
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The '''Ministry of Energy and Mineral Resources (MEMR)''' lays down the goals and political framework conditions for development of the energy market. Its core task is to facilitate continuing development of the country by ensuring adequate availability of energy. This is meant to be brought about with as little expenditure as possible, but while maintaining high standards. To this end, the ministry also intends inviting foreign investors in the fields of power generation, oil production and the development of other locally available sources of energy.<br/>In 2014, the Electricity Regulatory Commission, the Jordan Nuclear Regulatory Commission and the Natural Resources Authority (NRA) were merged to form the '''Energy and Minerals Regulatory Commission (EMRC)'''. The EMRC was built in accordance with Law No. 17 which regards the restructuring of institutions and governmental organization. It is an independent institution which is responsible for the regulatory environment of the electricity sector. To this end, it fixes the electricity tariffs and the charges for services related to the sale of electricity. The EMRC also awards licenses to power providers and distributors and monitors compliance with the terms of the licenses. Furthermore, the commission has been set up to arbitrate between operators and electricity customers in order to find solutions that are as amicable as possible. It also has the job of mediating between power generators or operators of distribution networks in the event of disagreement<br/>
  
= Existing Projects  =
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== Utilities<br/> ==
  
== Wind Energy<br> ==
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The national power company, '''National Electric Power Company (NEPCO)''', is a joint stock corporation whose capital is completely in the hands of the Jordanian state. It is responsible for expanding and operating the nationwide transmission network. NEPCO purchases the electricity from the producers as the sole buyer, in order to sell it on to the operators of the distribution networks. The company operates a national load-dispatching centre to coordinate the demand for and the supply of power. Its unique position as single buyer and single seller and the subsidies for electricity led to massive budgetary deficiencies. In order to reduce the losses, a National Strategic Plan has been developed. It foresees the adjustment of electricity tariffs and other measures to enhance the efficiency of the electricity system. By the end of 2017, NEPCO is supposed to be able to cover its costs.<br/>Three private companies act as Distribution System Operators (DSO) in Jordan: The '''Jordanian Electric Power Company (JEPCO) '''is responsible for distributing electrical energy for about 66% of the country’s total consumers. It serves 5,000 km2 (Amman, Zarqa, Madaba and Al-Balqaa) and is made up of more than 5,600 main stations and substations with a total of 19,000 kilometers of underground and overhead lines.<br/>The '''Electricity Distribution Company (EDCO)''' was established in 1997 and is now responsible for distributing electrical energy to the southern part of the Kingdom, including Aqaba, Maan, Karak, Tafila, Jordan Valley, Azraq, Safawi, Royweshed, and Reshah. The '''Irbid District Electricity Company (IDECO)''' was established in 1957 and is now responsible for distributing electrical energy to the northern part of the Kingdom, which includes Irbid, Jerash, Mafraq and Ajloun.<br/>[[Jordan_Energy_Situation#toc|►Go to Top]]<br/>
  
Egypt has passed the stage of initial resource assessment and demonstration projects (Hurghada wind farm) towards the planning and implementation of large scale grid connected projects (Zafarana and Gulf of El Zayt). A series of large-scale wind energy projects have been built in Egypt, resulting in a total installed wind capacity of 390 MW at the end of 2008.<br>  
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== Others<br/> ==
  
So far, large scale wind projects were established mainly at Zafarana, with a total capacity of 360 MW by end of 2008. In cooperation with Germany, Denmark and Spain, the farm has been constructed and operated in stages since 2001. A partnership with Japan in 2008 added 55 MW. In the fiscal year 2007/2008, approximately 840 GWh of electricity were generated by the Zafarana wind farm with an average capacity factor of 35.5&nbsp;%, saving 466 000 tons of CO<sub>2</sub>.<br>  
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Four main generators are active in Jordan: The private company '''Central Electricity Generating Company (CEGCO)''', with a nominal capacity of 1,669 MW (2011), which produces around 52% of the electricity in Jordan (2010).<br/>The '''Samra Electric Power Generation Company (SEPGCO) '''is responsible for the operation of the conventional energy power plant in Al-Risha. In 2011 it had a nominal capacity of around 880 MW.<br/>'''IPP1 (AES Jordan) '''and '''IPP2 (Al-Qatraneh Power Generation Company)''' are combined cycle plants with a nominal capacity of 380 MW each.<ref>GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.</ref><br/>In the pipeline are two more IPP projects: IPP3 is implemented by the Korean KEPCO, the Japanese company Mitsubishi and the Finnish company Wartsilla. IPP4 is implemented AES and Mitsue, the same companies which run IPP1. Both IPP3 and IPP4 are on a Build, Own, Operate basis (BOO) and include the construction of generating plants run by heavy fuel oil, diesel oil and natural gas situated in the Amman East area.<br/>[[Jordan_Energy_Situation#toc|►Go to Top]]<br/>
  
NREA has precise plans for wind farm development at the two sites Zafarana and Gulf of El-Zayt. While at Zafarana a capacity of 600 MW on 150 km<sup>2</sup> is planned, total capacity at El-Zayt will reach 720 MW on 200 km<sup>2</sup>. Between both areas, 1 300 km<sup>2</sup> have been designated to private investors, which are supposed to generate up to further 6 000 MW.<br>  
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= Energy Cooperation<br/> =
  
Projections for Zafarana between 2009 and 2010 include additional 75 MW in co-operation with Japan, and additional 120 MW in cooperation with Denmark. In total, Zafarana will host 555 MW of grid connected wind power, rendering it the largest wind farm in Middle East and Africa.<br>  
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In 2004, the Jordanian Government submitted an application for a US$ 6 million grant from the Global Environment Facility (GEF/World Bank) for a development project in the field of wind power. Part of the remit of this “Promotion of a Wind Power Market Project” is to eliminate obstacles that stand in the way of the commercial use of wind power in Jordan. The aim on the one hand is to improve the legislative and administrative preconditions for the use of renewable energy resources. On the other hand, the project is also to comprise the construction of a 60 MW wind farm that is to be&nbsp;financed by private investors. So far, however, only US$ 350,000 has been approved for feasibility studies.<br/>Since 2005, the Japanese Government, together with the Jordanian Government, has been sponsoring four studies investigating the potentials of renewable energy resources in Jordan within the framework of the “Policy and Human Resources Development Fund” (PHRD) of the World Bank. The Japanese share amounts to US$ 1 million, while Jordan is contributing a further US$ 312,000. One particular focus here too is on the wind power segment. Furthermore, the United States Trade and Development Agency (USTDA) is funding (US$ 180,000) a feasibility study into the expansion of the existing wind farms in Hofa and Al-Ibrahimiya.<br/>
  
At the Gulf of El Zayt, various projects have been developed and will add up to 720 MW.<br>720 MW are expected in three stages: 200 MW in cooperation with Germany, 220 MW in cooperation with Japan, and 300 MW in cooperation with Spain.<br>  
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== Bilateral Energy Cooperation with Germany<br/> ==
  
In addition, a number of private companies have expressed interest in developing large-scale wind projects at the Gulf of El Zayt. Among them, the Italian company Italcementi signed a MoU with the Egyptian government in 2006 to install 120 MW with the possibility for extension to up to 400 MW. The output is supposed to partly generate electricity for auto-consumption in the cement factories in the Suez area.<ref>WEI 2009/2010. World Wind Association: Wind Energy International 2009/2010, World Wind Association, Bonn, 15.09.2009</ref><br>  
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Germany is one of the biggest bilateral donors in Jordan, along with the United States, Japan and the European Union. This bilateral cooperation focuses on the water sector.<ref>http://www.auswaertiges-amt.de/EN/Aussenpolitik/Laender/Laenderinfos/01-Nodes/Jordanien_node.html</ref><br/><br/>[[Jordan_Energy_Situation#toc|►Go to Top]]<br/><br/>
  
On 2 August 2009, authorities have approved the designation of 1.5 million acres of state-owned land, located on the east and west of the Nile River for the implementation of wind farms, which are supposed to contribute 30 000 MW.<ref>MEES 2009. Ministry of Electricity and Energy. Strategic Plan in the Electricity Sector in Egypt. Prequalification Developers’ Meeting of BOO Wind Power Project 250 MW. Cairo 2009.</ref> One-third of this land will be developed for wind energy production by NREA and multinational organisations, whereas two-thirds will be offered to the private sector by bid-procedure.<br>  
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<br/>
  
= Publications<br> =
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= Publications<br/> =
  
Type your text here<br>  
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[[File:Energy policy framework for renewable energy and electricity market in Jordan.pdf|border|180px|En-windenergy-jordan-study-2007.pdf]] [[File:Enabling PV in the MENA Region - Jordan.pdf|border|180px|Enabling_PV_in_the_MENA_Region_-_Jordan.pdf]]<br/><br/>
  
= External links<br> =
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= Further Information<br/> =
  
*[http://www.egypt.gov.eg/english/ Egypt's Government Services Portal]<br>  
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*[http://www.jordan.gov.jo/wps/portal Jordan's Government Services Portal]<br/>
*[https://www.cia.gov/library/publications/the-world-factbook/geos/eg.html Egypt's entry at The World Factbook]
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*[https://www.cia.gov/library/publications/the-world-factbook/geos/jo.html Jordan's entry at The World Factbook]<br/>
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*[http://www.rcreee.org/content/jordan RCREE country page Jordan]<br/>
  
= References<br> =
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[[Jordan_Energy_Situation#toc|►Go to Top]]<br/>
  
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= References<br/> =
  
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<references /><br/>[[Jordan_Energy_Situation#toc|►Go to Top]]
  
 
[[Category:Jordan]]
 
[[Category:Jordan]]
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[[Category:MENA_(Middle_East_and_North_Africa)]]

Latest revision as of 20:04, 10 July 2018

Jordan
Flag of Jordan.png
Location _______.png

Capital:

Amman

Region:

Coordinates:

31.9500° N, 35.9333° E

Total Area (km²): It includes a country's total area, including areas under inland bodies of water and some coastal waterways.

89,318

Population: It is based on the de facto definition of population, which counts all residents regardless of legal status or citizenship--except for refugees not permanently settled in the country of asylum, who are generally considered part of the population of their country of origin.

11,337,052 (2023)

Rural Population (% of total population): It refers to people living in rural areas as defined by national statistical offices. It is calculated as the difference between total population and urban population.

8 (2023)

GDP (current US$): It is the sum of gross value added by all resident producers in the economy plus any product taxes and minus any subsidies not included in the value of the products. It is calculated without making deductions for depreciation of fabricated assets or for depletion and degradation of natural resources.

50,813,642,349 (2023)

GDP Per Capita (current US$): It is gross domestic product divided by midyear population

4,482.09 (2023)

Access to Electricity (% of population): It is the percentage of population with access to electricity.

100.00 (2022)

Energy Imports Net (% of energy use): It is estimated as energy use less production, both measured in oil equivalents. A negative value indicates that the country is a net exporter. Energy use refers to use of primary energy before transformation to other end-use fuels, which is equal to indigenous production plus imports and stock changes, minus exports and fuels supplied to ships and aircraft engaged in international transport.

96.81 (2014)

Fossil Fuel Energy Consumption (% of total): It comprises coal, oil, petroleum, and natural gas products.

97.61 (2014)

Source: World Bank



Introduction

The Hashemite Kingdom of Jordan covers an area of 89,342 km² on the northern Arabian Peninsula. It borders with Syria, Israel, Iraq, Saudi Arabia and the West Bank (Palestine) as well as the Red Sea, with only 1.5% of its surface being arable land.[1] The climate is semi-dry in summer and cool in winter.

Energy Situation

Energy Data

Primary Energy Supply

Jordan has two main challenges regarding its energy situation: the growing energy demand on the one hand and the very limited domestic resources to fulfill this demand on the other hand. In 2012, the local production of energy – including crude oil, natural gas and renewable energy – was 272 ktoe (thousand tonnes of oil equivalent)[2], which was enough to cover only about 5% of the energy consumption. Including imports, the primary energy supply was 7,624 ktoe in 2012.[3]


Consumption

Final energy consumption in Jordan in 2012 added up to 5,013 ktoe. The share of the individual sectors is shown in table 1.

Table 1: Final energy consumption in Jordan in 2012 by sector (ktoe)[4]

Sector
in ktoe
 in %
Industry sector 692 13.80
Transport sector 2,289 45.66
Other sectors 1,903 37.96
of which Residential 1,200 23.94

Commericial and public services 369 7.36

Agriculture/ Forestry 168 3.35

Non-specified 166 3.31
Non-energy use 130 2.59
Total 5,013 100


Import and Export

The limited domestic resources meant that Jordan had to import 7,656 ktoe (thousand tonnes of oil equivalent) of energy to meet its demands. This means that the cost of the consumed energy amounts to as much as 17% of the GDP.[5]
In the past, one of the main sources of the imported energy was Egypt, from where Jordan imported natural gas. However, there have been problems of the service being disrupted, which caused enormous problems with regards to the energy security in Jordan. Therefore, Jordan has increased efforts to diversify its energy supply.

Subsidies

In 2012, the government of Jordan eliminated all fuel subsidies.[6] In 2014, Jordan’s finance minister stated that electricity subsidies will be eliminated by 2017.[7]

►Go to Top

Renewable Energy

The use in Jordan of renewable energy sources has until now been marginal, accounting for a share of less than 1% of electricity generation. In 2012, of the 16.5 MW generated by renewable energy resources, 60.4% were hydropower, 21.1% biomass, 9.7% PV and 8.8% wind[8]. Potentials for generating power from renewable energy resources in the country are to be found primarily in the areas of wind and solar energy.

Wind Energy

Jordan has a number of regions that enjoy wind speeds suitable for generating electricity. Those regions with the greatest potential are located in the North and South of the country. A wind atlas, which was drawn up by the Danish Risø research centre in cooperation with the Jordanian authorities, has been available for Jordan since 1989. According to the Ministry of Energy and Mineral Resources, this wind atlas is in the process of being updated with results taken from recent measurements.
So far, two wind farms have been built and connected to the grid in Jordan. One has a generating capacity of 320 kW (4 x 80 kW) and was constructed in 1998, in cooperation with a Danish company, in Ibrahimyya near Hofa, as a pilot project. The second was completed in 1996 in Hofa (financed with funds from the German Eldorado programme) and has a capacity of 1.2 MW (5 x 225 kW). They generated around 3 GWh of electricity in 2012[9]. The share of electricity from wind is supposed to significantly increase. In 2013, a contract was signed with a consortium of Jordanian and international companies for the 117 MW Tafila wind farm. It is supposed to increase the country's total power capacity by 3%, with commercial operation envisioned to start by mid-2015[10].
A second contract has been signed on an EPC (Engineering, Procurement and Construction) basis with the Spanish company Elecnor. This wind park in Maan, a city in the South of Jordan, is supposed to produce 33 x 2 MW and to start supplying energy by the end of 2015[11].


Solar Energy

In Jordan, natural conditions for solar are excellent, with an intensity of direct solar radiation with 5 to7 kWh/m².[12] So far, solar PV has mainly been used for powering off-grid installations such as telecommunication towers, water pumping, and desalination of brackish water, as well as to provide dwellings in remote areas that are not connected to the electricity grid and where desalination had not been installed. Until the publication of the Renewable Energy Law in 2012, an estimated 236.4 kWp had been installed in Jordan.[13]
In late April 2014, around 3 to 4 MW of PV systems had been installed on a decentralized level, with around 5 MW more under construction, all connected to the distribution grid under the net-metering scheme. It was estimated that more than 400 registered installation companies exist in Jordan, although only around 10 companies are actively doing business in the field for on-grid markets in early 2014. In addition, 12 projects with 170 MWp were to be constructed under the first round of Direct Proposals for PPAs that was initiated in October 2011. By April 2014 none of these projects had been realized yet, but negotiations were in their final stage, with financial closure to be accomplished by autumn 2014.[14]
In addition, two tendered PV projects, one totaling 2 MWp, financed by Spain in the Azraq area, and another totaling 65 – 75 MWp in Quweirah (Aqaba), financed through a fund of Abu Dhabi, were to be evaluated by the Ministry for Energy and Mining Resources (MEMR) in 2014.[15]

Hydropower

Jordan has no notable bodies of flowing water suitable for the construction of hydroelectric power stations. The only such plant is at the King Talal dam on the Az Zarqa River, with a capacity of 5 MW. Another hydroelectric generating facility employs a turbine to exploit the head of the cooling water taken from the sea to cool a thermal power station in Aqaba as it flows back to the sea. In 2012, these two stations together generated 61 GWh of electricity and were therefore the source of 0.4% of the electricity generated in the country as a whole.

Biogas

In cooperation with the United Nations Development Programme (UNDP), a project has been developed for utilising the methane gas that arises at the municipal waste disposal site in Amman. With the aid of the Global Environmental Facility (US$ 2.5 million) and the Danish development agency DANIDA (US$1.5 million), a biogas facility has been financed that captures the gases that arise at the landfill and uses a 1-MW generator to generate electricity for the interconnected power grid. The facility has been in service since 2000 and generates some 5 GWh of electricity annually. The installation is run by the Jordan Biogas Company, a joint stock company that is owned by the Central Electricity Generation Company (CEGCO) and the Greater Amman Municipality (GAM). Since 2001, the biogas sector has hardly been expanded; it produced about 6 GWh in 2012.


Biomass

Due to the arid climate, there is not a great deal of vegetation in Jordan. This obviously limits the potential use of vegetable biomass. The burning of vegetable biomass serves to a limited extent in rural regions for cooking and heating and is the main source of energy of the Bedouin in the desert. Great energy potential is to be found in household wastes (municipal solid wastes), which has an organic content of roughly 60%, and is estimated to add up to an annual total of 1.1 million tonnes. This equates to a daily per capita figure of between 0.35 and 0.95 kg of waste with a gross calorific value of 7-11 MJ/kg. The figures vary depending on the time of year and also differ between urban and rural regions.

Geothermal Energy

Geothermal resources in Jordan have been identified mainly in two regions. That said, both the sources on the eastern banks of the Jordan Valley and those on the plateau to the east of Madaba offer comparatively low temperatures below 100°C. This means they cannot be used to generate electricity and will continue to be used for thermal purposes only, such as for heating swimming pools and greenhouses.


Electricity

Installed Capacity and Generation

In 2013, the Jordanian interconnected power grid was supplied by an installed power station capacity of 3,193 MW.[16] The generated and imported electrical energy amounted to 17,643 GWh in the same year. The available capacity development by type of generation since 2010 is outlined in table 2.

Table 2: Available capacity development by type of generation (in MW) 2010-2013[16]


2010
2011 2012 2013
MW
Steam
925 925 925 791
Gas turbine (diesel) 149 134 134 27
Gas turbine (natural gas) 600 499 499 621
Combined cycle 1,317 1,737
1,737 1,737
Hydro
12 12 12 12
Wind
1.4 1.4 1.4 1.4
Biogas 3.5 3.5 3.5 3.5

Total 3,008 3,312 3,312 3,193

In addition to the power stations operated by the public utilities, there are also a number of industrial enterprises that generate electricity in their own plants. Some of these also feed excess electricity into the Jordanian interconnected grid. Since the amount of electricity generated in Jordan has for some years been insufficient to cover the country’s needs, additional power used to be imported from Egypt and Syria. However, due to the circumstances in the region, import has been stalled completely (Syria, since 2012) or reduced (Egypt).[16]

Consumption

The main consumer of electricity in Jordan is the domestic sector (including government buildings) which accounts for 43% of the total consumption, followed by the industrial sector (24%). Overall consumption has been steadily increasing in the recent years. The development of the electricity consumption per sector is outlined in table 3.

Table 3: Electricity consumption by sector (in GWh) 2008-2013[16]

Sector
2008 2009 2010 2011 2012 2013
GWh
Domestic (incl. government buildings) 4,459 4,888 5,225 5,667 6,126 2,265
Industrial 3,128 3,006 3,262 3,486 3,461 3,517
Commercial 1,925 1,980 2,187 2,173 2,427 2,414
Water Pumping 1,713 1,772 1,868 1,899 1,955 2,076
Street Lighting 284 310 315 310 305 291

Total 11,509 11,956 12,857 13,535 14,277 14,564


Grid

The Jordanian national interconnected grid transmits electricity from the power stations to the distribution substations and transformer substations in the various regions of the kingdom via 400-kV and 132-kV power lines. The star topography of the grid has a clearly identifiable north-south axis, along which the only 400-kV power line runs, from Aqaba in the south via Amman and up to the Syrian border. The only area in which the grid has a ring-shaped configuration is around the capital city. In the north, the power grid is connected to the Syrian grid by means of a 230-kV and a 400-kV power line. In the south, there is a 400-kV connection to the Egyptian grid. The interconnected grid feeds the local distribution systems via which almost the entire population of Jordan receives its electricity. The overall length of the installed high voltage power lines (132 kV and 400 kV) is around 3,400 km. The National Electric Power Company (NEPCO) is planning to develop a new high voltage transmission network, called “green corridor”, running South-North in order to reinforce the electric grid. The project was initially planned for 2015, but due to delays it seems that it will be not be operational before 2018.[17]

Electricity Prices

The electricity tariff structure in Jordan takes into account social aspects as well as the economic capacities of consumers. In 2014, the electricity prices for the end consumer ranged from JD 0.033 per kWh for small residential consumers with less than 150 kWh per month demand to JD 0.292 per kWh for the banking sector. In 2012, the generation and distribution costs were JD 0.146 per kWh, whereas the average selling price was JD 0.0636 per kWh. The difference in price had to be covered by the state-owned National Electric Power Company (NEPCO), thereby creating a substantial deficit of JD 2.3 billion by the end of 2012. In order to reduce the losses, a National Strategic Plan has been developed. It foresees the adjustment of electricity tariffs and other measures to enhance the efficiency of the electricity system. By the end of 2017, NEPCO is supposed to be able to cover its costs. The plan prescribes the electricity price development for different consumer categories until the year 2017. Nevertheless, electricity is subsidized for many categories, e.g. for consumers with low electricity consumption.[18]
The electricity tariff schedule for the period from 2013 to 2017 is available here: http://www.memr.gov.jo/LinkClick.aspx?fileticket=PHxs463H8U0=&tabid=255
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Energy Policy

General Information

More than 96% of energy resources have to be imported. That is why, from an economic point of view, it is important for NEPCO as well as for consumers paying high prices for energy to look for cheaper alternatives of electricity supply. This is especially true since the overall political situation in the region remains unstable, making the option of cheap gas or electricity imports less probable in the near to mid-range future. Alternative energy sources such as shale oil or nuclear power require at least several years of exploration and development activities before deployment, and the LNG terminal for gas in Aqaba is still under construction. A growing population and the corresponding increase in energy consumption require solutions that can quickly generate additional electricity capacities.[19]
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Renewable Energy Policy

As a general rule, the issuing of licenses is regulated by the General Electricity Law, Article 28 onwards. In conformance with this law, the regulatory authority issues licenses to firms that wish to generate, distribute or sell electricity. Generating plants with a capacity of up to one megawatt are allowed to operate without a license. Local supply networks with a capacity of max. 100 kW can be operated without a license, in the same way as power plants that are used solely to generate electricity for self-consumption. Power supply companies or middlemen who want to purchase electricity from a power station with a capacity greater than 5 MW may conclude appropriate supply contracts only after competing in a public tendering process (Article 35). These rules apply equally to conventional thermal power stations and stations that generate electricity from renewable energy sources.
To develop renewable energy capacities, a number of support mechanism have been introduced. For example, under the Jordanian net-metering scheme, the excess electricity fed into the grid is credited for later consumption. This excess electricity that is credited can be used to offset electricity used at other times, when there is little or no PV electricity production (e.g. at night). The legal basis for net-metering is the 2012 Renewable Energy and Energy Efficiency Law No. 13 (REEL). The REEL as well as bylaws enable Independent Power Producers (IPP) to provide electricity from renewable sources to NEPCO within long-term Power Purchase Agreements (PPA). Private investors may also invest in their own PV system up to 5 MWp to directly consume the electricity produced and offset it against their entire demand within a net-metering scheme. The REEL even allows the generation of electricity at a different site than where the actual consumer is located – so-called energy wheeling. As a result, there are two promising business cases that enable investments in renewable energies: Direct Proposals for PPAs under consecutive rounds of “expressions of interest” and net-metering.
The Government has being attempting for a long time now to conclude contracts with Independent Power Producers (IPP) with the aim of expanding the number of power stations in Jordan’s electricity generating system. Initially, it made only slow progress. A number of potential projects were abandoned. Now, IPP projects with a total generation capacity of 740 MW (conventional energy) have been implemented. The IPP model is also used for renewable energy plants. However, by June 2014, no renewable energy plants had been constructed under the first round of the tender scheme and the following two rounds of direct proposals. In the first round, initiated in 2011, PPAs covering 170 MWp of solar PV were initially signed between 12 IPP companies or consortia and the Ministry for Energy and Mining Resources (MEMR). Until April 2014, these were in the process of financial negotiations between investors and the potential IPPs. Those systems were due to be constructed and connected to National Electric Power Company’s (NEPCO) transmission lines within the next 16 months. In the following two rounds of direct proposals, another 400 MWp of solar PV systems had been tendered for direct proposals, including four 50 MW plants and two 100 MW plants.[20]
In 2007, Jordan updated its Master Strategy for Energy for the period of 2007 to 2020, which had initially been drafted in 2004. The strategy aims at reducing energy imports through diversification of the energy mix by using local resources such as shale oil, nuclear power and renewable energies. Although at the moment the strategy still serves as a guideline for renewable energies, its assumptions can be considered to be outdated, especially since it assumes that nuclear and shale oil will cover a considerable share of Jordan’s energy demand by 2015 and 2020.[21]

Energy Efficiency Policy

In the Master Strategy for Energy in Jordan for the period of 2007 to 2020 there are also several recommendation concerning energy efficiency. These include the implementation of energy consumption efficiency programs in different sectors, broad awareness campaigns on the energy consumption rationalization, tax exemptions for energy saving equipment, thermal insulation of buildings and a national award in the energy consumption rationalization domain.
Jordan also introduced a National Energy Efficiency Action Plan (NEEAP) which is in the process of adaptation. The NEEAP gives a national indicative target of 20% energy reductions by 2020 and six sectorial targets.
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Key Actors in the Energy Sector

Governmental Bodies and Agencies

The Ministry of Energy and Mineral Resources (MEMR) lays down the goals and political framework conditions for development of the energy market. Its core task is to facilitate continuing development of the country by ensuring adequate availability of energy. This is meant to be brought about with as little expenditure as possible, but while maintaining high standards. To this end, the ministry also intends inviting foreign investors in the fields of power generation, oil production and the development of other locally available sources of energy.
In 2014, the Electricity Regulatory Commission, the Jordan Nuclear Regulatory Commission and the Natural Resources Authority (NRA) were merged to form the Energy and Minerals Regulatory Commission (EMRC). The EMRC was built in accordance with Law No. 17 which regards the restructuring of institutions and governmental organization. It is an independent institution which is responsible for the regulatory environment of the electricity sector. To this end, it fixes the electricity tariffs and the charges for services related to the sale of electricity. The EMRC also awards licenses to power providers and distributors and monitors compliance with the terms of the licenses. Furthermore, the commission has been set up to arbitrate between operators and electricity customers in order to find solutions that are as amicable as possible. It also has the job of mediating between power generators or operators of distribution networks in the event of disagreement

Utilities

The national power company, National Electric Power Company (NEPCO), is a joint stock corporation whose capital is completely in the hands of the Jordanian state. It is responsible for expanding and operating the nationwide transmission network. NEPCO purchases the electricity from the producers as the sole buyer, in order to sell it on to the operators of the distribution networks. The company operates a national load-dispatching centre to coordinate the demand for and the supply of power. Its unique position as single buyer and single seller and the subsidies for electricity led to massive budgetary deficiencies. In order to reduce the losses, a National Strategic Plan has been developed. It foresees the adjustment of electricity tariffs and other measures to enhance the efficiency of the electricity system. By the end of 2017, NEPCO is supposed to be able to cover its costs.
Three private companies act as Distribution System Operators (DSO) in Jordan: The Jordanian Electric Power Company (JEPCO) is responsible for distributing electrical energy for about 66% of the country’s total consumers. It serves 5,000 km2 (Amman, Zarqa, Madaba and Al-Balqaa) and is made up of more than 5,600 main stations and substations with a total of 19,000 kilometers of underground and overhead lines.
The Electricity Distribution Company (EDCO) was established in 1997 and is now responsible for distributing electrical energy to the southern part of the Kingdom, including Aqaba, Maan, Karak, Tafila, Jordan Valley, Azraq, Safawi, Royweshed, and Reshah. The Irbid District Electricity Company (IDECO) was established in 1957 and is now responsible for distributing electrical energy to the northern part of the Kingdom, which includes Irbid, Jerash, Mafraq and Ajloun.
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Others

Four main generators are active in Jordan: The private company Central Electricity Generating Company (CEGCO), with a nominal capacity of 1,669 MW (2011), which produces around 52% of the electricity in Jordan (2010).
The Samra Electric Power Generation Company (SEPGCO) is responsible for the operation of the conventional energy power plant in Al-Risha. In 2011 it had a nominal capacity of around 880 MW.
IPP1 (AES Jordan) and IPP2 (Al-Qatraneh Power Generation Company) are combined cycle plants with a nominal capacity of 380 MW each.[22]
In the pipeline are two more IPP projects: IPP3 is implemented by the Korean KEPCO, the Japanese company Mitsubishi and the Finnish company Wartsilla. IPP4 is implemented AES and Mitsue, the same companies which run IPP1. Both IPP3 and IPP4 are on a Build, Own, Operate basis (BOO) and include the construction of generating plants run by heavy fuel oil, diesel oil and natural gas situated in the Amman East area.
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Energy Cooperation

In 2004, the Jordanian Government submitted an application for a US$ 6 million grant from the Global Environment Facility (GEF/World Bank) for a development project in the field of wind power. Part of the remit of this “Promotion of a Wind Power Market Project” is to eliminate obstacles that stand in the way of the commercial use of wind power in Jordan. The aim on the one hand is to improve the legislative and administrative preconditions for the use of renewable energy resources. On the other hand, the project is also to comprise the construction of a 60 MW wind farm that is to be financed by private investors. So far, however, only US$ 350,000 has been approved for feasibility studies.
Since 2005, the Japanese Government, together with the Jordanian Government, has been sponsoring four studies investigating the potentials of renewable energy resources in Jordan within the framework of the “Policy and Human Resources Development Fund” (PHRD) of the World Bank. The Japanese share amounts to US$ 1 million, while Jordan is contributing a further US$ 312,000. One particular focus here too is on the wind power segment. Furthermore, the United States Trade and Development Agency (USTDA) is funding (US$ 180,000) a feasibility study into the expansion of the existing wind farms in Hofa and Al-Ibrahimiya.

Bilateral Energy Cooperation with Germany

Germany is one of the biggest bilateral donors in Jordan, along with the United States, Japan and the European Union. This bilateral cooperation focuses on the water sector.[23]

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Publications

En-windenergy-jordan-study-2007.pdf Enabling_PV_in_the_MENA_Region_-_Jordan.pdf

Further Information

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References

  1. GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.
  2. http://www.iea.org/statistics/statisticssearch/report/?country=JORDAN&product=balances&year=2012
  3. http://www.iea.org/statistics/statisticssearch/report/?country=JORDAN&product=balances&year=2012
  4. http://www.iea.org/statistics/statisticssearch/report/?country=JORDAN&product=balances&year=2012
  5. http://www.memr.gov.jo/LinkClick.aspx?fileticket=B495BBqcNs4%3d&tabid=111
  6. http://www.economist.com/news/finance-and-economics/21639589-few-countries-are-taking-advantage-lower-oil-prices-cut-subsidies-pump
  7. http://www.aawsat.net/2014/05/article55332275/jordans-finance-minister-we-will-eliminate-electricity-subsidies-by-2017
  8. http://www.rcreee.org/sites/default/files/jordan_fact_sheet_re_print.pdf
  9. http://www.iea.org/statistics/statisticssearch/report/?year=2012&country=JORDAN&product=RenewablesandWaste
  10. http://www.memr.gov.jo/LinkClick.aspx?fileticket=B495BBqcNs4%3d&tabid=111
  11. http://www.rechargenews.com/wind/1370753/Elecnor-Gamesa-in-Jordan-wind-joy
  12. http://www.memr.gov.jo/LinkClick.aspx?fileticket=B495BBqcNs4%3d&tabid=111
  13. GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.
  14. GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.
  15. GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.
  16. 16.0 16.1 16.2 16.3 http://www.nepco.com.jo/store/docs/web/2013_en.pdf
  17. http://www.invest-export.irisnet.be/documents/16349/1140680/2014+-Jordan+-+Renewable+energy+prospects.pdf/eb6cb1ff-a6d9-4d7c-804f-13b68877d86d
  18. GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.
  19. GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.
  20. GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.
  21. GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.
  22. GIZ (2014): Enabling PV in the MENA Region. The Emerging PV Market in Jordan.
  23. http://www.auswaertiges-amt.de/EN/Aussenpolitik/Laender/Laenderinfos/01-Nodes/Jordanien_node.html


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