Difference between revisions of "Solar Powered Irrigation Systems in Egypt"

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This article is mainly based on information and documents that can be found at [http://raseed-giz.com/ raseed-giz.com.]<br/>
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This article is mainly based on information and documents that were available at the former webpage (raseed-giz.com).<br/>
  
= '''The Agricultural Sector in Egypt'''<br/> =
+
<br/>
About 54% of [[Egypt_Energy_Situation|Egypt’s]] working population is employed in the agricultural sector, making agriculture key for the country’s development. However, agriculture in Egypt is aggravated by low rainfalls, relative low humidity (except for the coast) hot climate and the fact that water quality and volume of the Nile is constantly decreasing. Furthermore, 90 % of farmers work on lands of about 5 Feddan or less (1 Feddan = 0, 42 Acres). These factors entail that the Delta region has become less attractive for agricultural use and is instead being used to accommodate Egypt’s rapidly growing population. Therefore, and to meet the rising food demand; in the past 5 to 10 ears agribusinesses were forced to reclaim desert lands (the so called “new lands”) for agricultural use in the western desert and other desert areas. Yet, very high evapotranspiration and sandy soils usually require frequently water application to ensure that the water will not leach towards deeper soil layers where it will be unreachable for the crops. This makes [[Energy for Agriculture#Irrigation|irrigation agriculture]] inevitable in Egypt.<br/>
 
== '''Rising Fuel prices'''<br/> ==
 
Costs of diesel for irrigation systems are increasing sharply due to the lack of availability of diesel in the markets. Moreover, the use of diesel fuel is also more expensive in the “new lands” due to the remoteness of desert farms. Taking into account the costs of transportation of diesel, maintenance and overhauling of generators, using diesel will no longer be economically feasible or affordable for those farms in the near future. At the same time, Egypt’s exporters lose competitiveness in the international market due to crop losses that were caused by lack of irrigation. High CO2 emissions, immense diesel spills into the soil and risky long distance transportation of diesel to the farms are just a few ecological downsides of diesel operated water pumps. This makes the use of alternative energy sources vital to the development of Egypt’s agricultural sector.<br/>
 
  
 +
= The Agricultural Sector in Egypt<br/> =
  
= '''Solar Irrigation in Egypt's Agricultural Sector '''<br/> =
+
About 54% of [[Egypt Energy Situation|Egypt’s]] working population is employed in the agricultural sector, making agriculture key for the country’s development. However, agriculture in Egypt is aggravated by low rainfalls, relative low humidity (except for the coast) hot climate and the fact that water quality and volume of the Nile is constantly decreasing. Furthermore, 90&nbsp;% of farmers work on lands of about 5 Feddan or less (1 Feddan = 0, 42 Acres). These factors entail that the Delta region has become less attractive for agricultural use and is instead being used to accommodate Egypt’s rapidly growing population. Therefore, and to meet the rising food demand; in the past 5 to 10 years agribusinesses were forced to reclaim desert lands (the so called “new lands”) for agricultural use in the western desert and other desert areas. Yet, very high evapotranspiration and sandy soils usually require frequently water application to ensure that the water will not leach towards deeper soil layers where it will be unreachable for the crops. This makes [[Energy for Agriculture#Irrigation|irrigation agriculture]] inevitable in Egypt.<br/><br/>
With 96 % of desert land, a high frequency of clear sky days and solar radiations ranging from 2000 kW/h in the north up to 2600 kW/h (m²/year) in the south, Egypt is one of the most potential countries in the MENA region for [[Solar Energy|solar energy]]. The introduction of [[Photovoltaic (PV) Pumping Systems for Irrigation|solar powered irrigation]] technologies presents an opportunity to abandon non-sustainable and non-reliable fossil fuel powered generators. Fluctuations in both fuel prices and supply are prevented through the implementation of solar pump solutions. Using solar power guarantees stable and reliable on farm energy supply. Therewith, crop losses that result from insufficient irrigation are avoided. Furthermore, a cost calculation that was conducted for a remote desert farm in Bahareyia shows that one kw/h generated from diesel will cost the farm 1, 3 Egyptian Pound (LE) due to the cost of transportation, whereas 1kw/h generated from Photovoltaic (PV) will cost them only 0, 95 LE. With respect to irrigation, this implies that 1m<sup>3 </sup>of pumped water costs the farm 0, 35 LE when using diesel generators and 0, 19 LE when using solar energy[[Index.php|[1]]]. Using an alternative energy, such as Photovoltaic Systems, is thus also more cost-effective for remote desert farms. (For more information see [https://drive.google.com/file/d/0BxbNeXH1Y54xY3J4RVhwWUpETjQ/view Irrigation Parctices in Egypt])<br/>
 
  
 +
== Rising Diesel Prices<br/> ==
  
 +
Costs of diesel for irrigation systems are increasing sharply due to the lack of availability of diesel in the markets. Moreover, the use of diesel fuel is also more expensive in the “new lands” due to the remoteness of desert farms. Taking into account the costs of transportation of diesel, maintenance and overhauling of generators, using diesel will no longer be economically feasible or affordable for those farms in the near future. At the same time, Egypt’s exporters lose competitiveness in the international market due to crop losses that were caused by lack of irrigation. High CO2 emissions, immense diesel spills into the soil and risky long distance transportation of diesel to the farms are just a few ecological downsides of diesel operated water pumps. This makes the use of alternative energy sources vital to the development of Egypt’s agricultural sector.<br/><br/>
  
 +
== Costs of Diesel vs. Solar Energy<br/> ==
  
 +
However, in comparison with Diesel prices, solar energy is not yet a competitive alternative considering price of input (diesel to solar) only. This is due to the strong subsidization of Diesel by the Egyptian government. The current Diesel price fluctuates between 0.7 and 0.9 LE per kW, while solar power can cost between 0.95 and 1.5 LE. According to calculations, subsidies will have decreased sufficiently within the next 4 years to make solar energy a competitive alternative. Yet, this might already be the case for remote desert farms. A cost calculation that was conducted for a remote desert farm in Bahareyia shows that one kw/h generated from diesel will cost the farm 1, 3 Egyptian Pound (LE) due to the cost of transportation, whereas 1kw/h generated from Photovoltaic (PV) will cost them only 0, 95 LE. With respect to irrigation, this implies that 1m3 of pumped water costs the farm 0, 35 LE when using diesel generators and 0, 19 LE when using solar energy.<ref>To generate 100 m³ of water per hour, the solar pump has to be driven with around 70kWp. This requires the application of solar panels on an area of around 550m² to 800m².</ref> Using an alternative energy, such as Photovoltaic Systems, is thus more cost-effective for remote desert farms. (For more information see [https://drive.google.com/file/d/0BxbNeXH1Y54xY3J4RVhwWUpETjQ/view Irrigation Practices in Egypt]).<br/>
  
= '''The Initiative 'RaSeed''''<br/> =
+
<br/>
For this reason, the German development programme “Agricultural Water Productivity as Adaptation to Climate Change” on behalf of the German Federal Ministry of Economic Cooperation and Development (BMZ) called into life the initiative ‘[http://raseed-giz.com/about-raseed/ RaSeed’]''.''[[#_ftn1|[2]]] The initiative aims to promote the use of Photovoltaic (PV) systems in drip irrigation farming in order to support cost-effective and sustainable agriculture. Therefore, the aim is to introduce high capacity solar operated water pumps - of up to a pump size of 100kW - to the Egyptian agricultural sector. Furthermore, soil in the “New Lands” is mostly sandy, and water used for irrigation is ground water. Hence, it is crucial to use water efficient irrigation systems. RaSeed targets farm specific optimization of drip irrigation systems that enable maximum fuel savings and water efficiency by taking into account soil compositions and environmental conditions. In order to further the initiative, a Private Public Partnership (PPP) was established with two solar energy firms ([http://www.aschoff-solar.com/ Ashoff Solar]] and [http://www.juwi.com/homepage.html Juwi]) that are supported by the multi-donor initiative [[Powering Agriculture: An Energy Grand Challenge for Development|‘Powering Agriculture- an Energy Grand Challenge for]] Development’. Together with its partners, RaSeed establishes a network, providing high quality solar energy technology and training in Egypt.<br/>[[File:Egyptian Desert.jpg|thumb|left|150px|Solar Panels in the Egyptian Desert]][[File:Solar Panels in Egypt.jpg|thumb|left|150px|Solar Panels in the Egyptian Desert]][[File:Crop Cultivation in Desert.jpg|thumb|left|150px|Crop Cultivation in the Egyptian Desert thanks to Solar Powered Irrigation]]<br/><br/>
 
== '''Solar Pump Systems in Egypt'''<br/> ==
 
There are different options available when it comes to solar pump systems for irrigation. Generally speaking, the most commonly used PV cells are polycrystalline and monocrystalline cells. RaSeed opted for polycrystalline cells, although, monocrystalline cells are the most efficient ones. However, given that most of the farms in Egypt are located in remote desert areas, far away from on-grid systems and in-house cabling, polycrystalline cells have a better cost-efficiency ratio. Which solar pump system is best suited depends on various external factors. (For further information see [http://raseed-giz.com/infomaterials/ Practical Guidelines for Solar Punp Systems in Egypt]) Stand-alone solar pump systems for direct irrigation offer a very simple solution, with the pump and a solar inverter being directly connected. However, this system does not provide a backup power source. Therefore, three different and more advanced solar pump systems were made available by the partnering firms:<br/>
 
=== '''Battery Based System '''<br/> ===
 
To maximize independence of fuel price fluctuation, a so called Battery Based Hybrid System uses batteries in order to store any excess energy, making it a good option for full- day operations. However, the batteries and their mandatory replacement over time make this system also very cost intensive. In this setup kWp will cost between 33,000 LE to 47,000 LE, with the batteries making up almost half of these costs.<br/><br/>
 
=== '''Solar Fuel Saver System '''<br/> ===
 
To avoid fluctuations in the irrigation schedule and to prolong irrigation hours one may prefer a hybrid system, which combines solar and diesel power. A so called solar fuel saver system avoids the aforementioned high battery costs; by using a controller that ensures continues operations. This system costs only around 16,000 LE per kWp and is therefore much cheaper than the battery based hybrid system. However, this system requires a constantly running diesel generator, despite solar energy being the main energy source.<br/><br/>
 
=== '''Variable Speed Drive '''<br/> ===
 
The variable speed drive system is probably the most adequate for the Egyptian agricultural sector. This system uses a variable speed drive that connects and regulates PV Panels and the diesel generator. Depending on solar irradiation and the size of the power plant, the diesel generator can be turned off completely. Furthermore, the variable speed drive system is the most cost efficient, with 15,000 LE per kWp.<br/><br/><br/>
 
== <span lang="en-us">'''<font size="3">Pilot Projects</font>'''</span><br/> ==
 
<span lang="en-us"><font size="3">Three pilot projects that were initiated mostly at the end of 2014 are supported by the RaSeed initiative in order to promote and assess the feasibility and efficiency of solar energy irrigation systems under different conditions - hot weather, high soil salinity and sand storms. They are implemented at different locations across Egypt, allowing for a pluralistic analysis of solar irrigation systems in desert areas over time:</font></span><br/><span lang="en-us"></span><br/>'''1. SEKEM- the Bahareiya Oasis '''<br/>The solar powered irrigation system (45kWp) at the Bahareiya Oasis that was built at the end of 2014 is exposed to extreme heat (45-50 <sup>o </sup>C during summer time), which can have a negative effect on the PV panels. Also, due to the extreme remoteness of the farm, only solar energy can be used, implying that the fields can only be irrigated throughout the day (6 h during winter and 8 h during summer time).<br/><br/>'''2. WADI FOOD- in Wadi El Natroun'''<br/>In Wadi El Natroun, a hybrid plant of 150kw/p (92Kw pump) was installed at the end of 2014. The irrigation plant is partially powered with diesel fuel (12%). Due to expansions in 2013, 14 % more water and 58% more fuel was needed, which lead to a stark increase in costs. Also, despite a strong water flow (115 m<sup>3</sup>/h), the water at the farm is extremely saline, and the fields are irrigated 16-18 h during summer time and 12 h during winter time, which could lead to salinization of the fields.<br/><br/>'''3. PICO- El Mansoureya '''<br/>The desert farm at the outskirts of Cairo has implemented a central solar powered irrigation system with four pumps (288 kW) and a fuel saver system. The pumps reach 180 meters deep. However the existing generators are massively oversized, which has caused efficiency and distribution problems.<br/><br/>
 
  
 +
<br/>
  
= '''Further Information''' =
+
== Solar Irrigation in Egypt's Agricultural Sector<br/> ==
*[[Egypt Energy Situation| Egypt Energy Situation]]
+
 
*[[Portal:Powering Agriculture| Powering agriculture portal on energypedia]]
+
With 96&nbsp;% of desert land, a high frequency of clear sky days and solar radiations ranging from 2000 kW/h in the north up to 2600 kW/h (m²/year) in the south, Egypt is one of the most potential countries in the MENA region for solar energy. The introduction of solar powered pumps presents an opportunity to abandon non-sustainable and non-reliable fossil fuel powered generators. Furthermore, the implementation of solar powered irrigation helps overcoming the risk from fluctuations in both fuel and supply prices, and instead guarantees stable and reliable on farm energy supply. Therewith, crop losses that result from insufficient irrigation are avoided.<br/>
 +
 
 +
<br/>
 +
 
 +
<br/>
 +
 
 +
= The Initiative 'RaSeed'<br/> =
 +
 
 +
For this reason, the German development programme “Agricultural Water Productivity as Adaptation to Climate Change” on behalf of the German Federal Ministry of Economic Cooperation and Development (BMZ) called into life the initiative ‘RaSeed'.<ref>RaSeed is composed of the words Ra & Seed. Ra refers to the pharaonic god of the sun, which stands for energy and life, while a seed is the basis for all agricultural activities. At the same time, Raseed can be translated to ‘Credit’ in Arabic.</ref> The initiative aims to promote the use of Photovoltaic (PV) systems in drip irrigation farming in order to support cost-effective and sustainable agriculture. Therefore, the aim is to introduce high capacity solar operated water pumps - of up to a pump size of 100kW - to the Egyptian agricultural sector. Furthermore, soil in the “New Lands” is mostly sandy, and water used for irrigation is ground water. Hence, it is crucial to use water efficient irrigation systems. RaSeed targets farm specific optimization of drip irrigation systems that enable maximum fuel savings and water efficiency by taking into account soil compositions and environmental conditions. In order to further the initiative, a Private Public Partnership (PPP) was established with a solar energy firm ([http://www.aschoff-solar.com/ Ashoff Solar]] that is supported by the multi-donor initiative [[Powering Agriculture: An Energy Grand Challenge for Development|‘]][[Powering Agriculture: An Energy Grand Challenge for Development|Powering Agriculture - an Energy Grand Challenge for Development]]’. Together with its partners, RaSeed establishes a network, providing high quality solar energy technology and training in Egypt.<br/>
 +
 
 +
{|
 +
|-
 +
| [[File:Egyptian Desert.jpg|thumb|left|300px|alt=Egyptian Desert.jpg]]
 +
| [[File:Solar Panels in Egypt.jpg|thumb|left|300px|alt=Solar Panels in Egypt.jpg]]
 +
|-
 +
| [[File:Crop Cultivation in Desert.jpg|thumb|left|300px|alt=Crop Cultivation in Desert.jpg]]
 +
| [[File:New Lands.jpg|thumb|left|300px|alt=New Lands.jpg]]
 +
|}
 +
 
 +
<br/>
 +
 
 +
== Solar Pump Systems in Egypt<br/> ==
 +
 
 +
There are different options available when it comes to solar pump systems for irrigation. Generally speaking, the most commonly used PV cells are polycrystalline and monocrystalline cells. RaSeed opted for polycrystalline cells, although, monocrystalline cells are the most efficient ones. However, given that most of the farms in Egypt are located in remote desert areas, far away from on-grid systems and in-house cabling, polycrystalline cells have a better cost-efficiency ratio. Which solar pump system is best suited depends on various external factors. Stand-alone solar pump systems for direct irrigation offer a very simple solution, with the pump and a solar inverter being directly connected. However, this system does not provide a backup power source. Therefore, three different and more advanced solar pump systems were made available by the partnering firms:<br/>
 +
 
 +
=== Battery Based System<br/> ===
 +
 
 +
To maximize independence of fuel price fluctuation, a so called Battery Based Hybrid System uses batteries in order to store any excess energy, making it a good option for full- day operations. However, the batteries and their mandatory replacement over time make this system also very cost intensive. In this setup kWp will cost between 33,000 LE to 47,000 LE, with the batteries making up almost half of these costs.<br/>[[File:Battery Based Solar System.png|thumb|left|300px|alt=Battery Based Solar System.png]]<br/>
 +
 
 +
 
 +
=== Solar Fuel Saver System<br/> ===
 +
 
 +
To avoid fluctuations in the irrigation schedule and to prolong irrigation hours one may prefer a hybrid system, which combines solar and diesel power. A so called solar fuel saver system avoids the aforementioned high battery costs; by using a controller that ensures continued operations. This system costs only around 16,000 LE per kWp and is therefore much cheaper than the battery based hybrid system. However, this system requires a constantly running diesel generator, despite solar energy being the main energy source.<br/>[[File:Solar Fuel Saver System.png|thumb|left|300px|alt=Solar Fuel Saver System.png]]<br/>
 +
 
 +
 
 +
=== Variable Speed Drive<br/> ===
 +
 
 +
The variable speed drive system is probably the most adequate for the Egyptian agricultural sector. This system uses a variable speed drive that connects and regulates PV Panels and the diesel generator. Depending on solar irradiation and the size of the power plant, the diesel generator can be turned off completely. Furthermore, the variable speed drive system is the most cost efficient, with 15,000 LE per kWp.<br/><br/>[[File:Variable Speed Drive system.png|thumb|left|300px|alt=Variable Speed Drive system.png]]<br/>
 +
 
 +
<br/>
 +
 
 +
== <span lang="en-us"><font size="3">Pilot Projects</font></span><br/> ==
 +
 
 +
<span lang="en-us"></span> Three pilot projects that were initiated mostly at the end of 2014 are supported by the RaSeed initiative in order to promote and assess the feasibility and efficiency of solar energy irrigation systems under different conditions - hot weather, high soil salinity and sand storms. They are implemented at different locations across Egypt, allowing for a pluralistic analysis of solar irrigation systems in desert areas over time.<br/><br/>'''1. SEKEM- the Bahareiya Oasis'''<br/>The solar powered irrigation system (45kWp) at the Bahareiya Oasis that was built at the end of 2014 is exposed to extreme heat (45-50 o C during summer time), which can have a negative effect on the PV panels. Also, due to the extreme remoteness of the farm, only solar energy can be used, implying that the fields can only be irrigated throughout the day (6 h during winter and 8 h during summer time).<br/><br/>'''2. WADI FOOD- in Wadi El Natroun'''<br/>In Wadi El Natroun, a hybrid plant of 150kw/p (92Kw pump) was installed at the end of 2014. The irrigation plant is partially powered with diesel fuel (12%). Due to expansions in 2013, 14&nbsp;% more water and 58% more fuel was needed, which lead to a stark increase in costs. Also, despite a strong water flow (115 m3/h), the water at the farm is extremely saline, and the fields are irrigated 16-18 h during summer time and 12 h during winter time, which could lead to salinization of the fields.<br/><br/>'''3. PICO- El Mansoureya'''<br/>The desert farm at the outskirts of Cairo has implemented a central solar powered irrigation system with four pumps (288 kW) and a fuel saver system. The pumps reach 180 meters deep. However the existing generators are massively oversized, which has caused efficiency and distribution problems.<br/>
 +
 
 +
<br/>
 +
 
 +
<br/>
 +
 
 +
= Further Information<br/> =
 +
 
 +
*[[Egypt Energy Situation|Egypt Energy Situation]]
 +
*[[Portal:Water and Energy for Food|Water and Energy for Food (WE4F) portal on energypedia]]
 +
*[[Photovoltaic (PV) Pumping Systems for Irrigation|PV Pumping Systems for Irrigation]]<br/>
 +
*[[Solar Powered Irrigation Systems - Technology, Economy, Impacts|Solar Powered Irrigation Systems - Technology, Economy, Impacts]]
 +
*[[Toolbox on SPIS|Toolbox on Solar Powered Irrigation Systems]]
 +
 
 +
<br/>
 +
 
 +
= References<br/> =
  
= '''References'''<br/> =
 
[http://raseed-giz.com/ RaSeed]<br/>
 
 
*[https://drive.google.com/file/d/0BxbNeXH1Y54xYWFQaDdrUldUMjA/view GIZ RaSeed Green Energy in Agriculture Brochure]<br/>
 
*[https://drive.google.com/file/d/0BxbNeXH1Y54xYWFQaDdrUldUMjA/view GIZ RaSeed Green Energy in Agriculture Brochure]<br/>
 
*[https://drive.google.com/file/d/0BxbNeXH1Y54xY3J4RVhwWUpETjQ/view Manual for Irrigation Practices in Egypt]<br/>
 
*[https://drive.google.com/file/d/0BxbNeXH1Y54xY3J4RVhwWUpETjQ/view Manual for Irrigation Practices in Egypt]<br/>
*[http://raseed-giz.com/infomaterials/ Practical guidelines for solar pump systems in Egypt]<br/>
 
*[http://raseed-giz.com/infomaterials/ Solar Pump Systems in Egypt]<br/>
 
 
*[https://drive.google.com/file/d/0BxbNeXH1Y54xc3FzcmhaTUtrTjA/view Study on Solar Energy vs. Diesel on Pilot Farm]<br/>
 
*[https://drive.google.com/file/d/0BxbNeXH1Y54xc3FzcmhaTUtrTjA/view Study on Solar Energy vs. Diesel on Pilot Farm]<br/>
<div><br/>--<br/></div><div>[1] To generate 100 m³ of water per hour, the solar pump has to be driven with around 70kWp. This requires the application of solar panels on an area of around 550m² to 800m²<br/>----<div id="ftn1">[[#_ftnref1|[2]]]''RaSeed'' is composed of the words ''Ra'' & ''Seed''. ''Ra'' refers to the pharaonic god of the sun, which stands for energy and life, while a ''seed'' is the basis for all agricultural activities. At the same time, ''Raseed'' can be translated to ‘Credit’ in Arabic.<br/><br/></div></div>
+
<div></div><div><references /><br/></div>
  
 +
[[Category:Powering_Agriculture]]
 +
[[Category:Irrigation]]
 +
[[Category:Solar]]
 +
[[Category:Solar_Pumping]]
 
[[Category:Egypt]]
 
[[Category:Egypt]]
[[Category:Solar]]
 
[[Category:Irrigation]]
 
[[Category:Powering_Agriculture]]
 

Latest revision as of 19:14, 14 July 2020

This article is mainly based on information and documents that were available at the former webpage (raseed-giz.com).


The Agricultural Sector in Egypt

About 54% of Egypt’s working population is employed in the agricultural sector, making agriculture key for the country’s development. However, agriculture in Egypt is aggravated by low rainfalls, relative low humidity (except for the coast) hot climate and the fact that water quality and volume of the Nile is constantly decreasing. Furthermore, 90 % of farmers work on lands of about 5 Feddan or less (1 Feddan = 0, 42 Acres). These factors entail that the Delta region has become less attractive for agricultural use and is instead being used to accommodate Egypt’s rapidly growing population. Therefore, and to meet the rising food demand; in the past 5 to 10 years agribusinesses were forced to reclaim desert lands (the so called “new lands”) for agricultural use in the western desert and other desert areas. Yet, very high evapotranspiration and sandy soils usually require frequently water application to ensure that the water will not leach towards deeper soil layers where it will be unreachable for the crops. This makes irrigation agriculture inevitable in Egypt.

Rising Diesel Prices

Costs of diesel for irrigation systems are increasing sharply due to the lack of availability of diesel in the markets. Moreover, the use of diesel fuel is also more expensive in the “new lands” due to the remoteness of desert farms. Taking into account the costs of transportation of diesel, maintenance and overhauling of generators, using diesel will no longer be economically feasible or affordable for those farms in the near future. At the same time, Egypt’s exporters lose competitiveness in the international market due to crop losses that were caused by lack of irrigation. High CO2 emissions, immense diesel spills into the soil and risky long distance transportation of diesel to the farms are just a few ecological downsides of diesel operated water pumps. This makes the use of alternative energy sources vital to the development of Egypt’s agricultural sector.

Costs of Diesel vs. Solar Energy

However, in comparison with Diesel prices, solar energy is not yet a competitive alternative considering price of input (diesel to solar) only. This is due to the strong subsidization of Diesel by the Egyptian government. The current Diesel price fluctuates between 0.7 and 0.9 LE per kW, while solar power can cost between 0.95 and 1.5 LE. According to calculations, subsidies will have decreased sufficiently within the next 4 years to make solar energy a competitive alternative. Yet, this might already be the case for remote desert farms. A cost calculation that was conducted for a remote desert farm in Bahareyia shows that one kw/h generated from diesel will cost the farm 1, 3 Egyptian Pound (LE) due to the cost of transportation, whereas 1kw/h generated from Photovoltaic (PV) will cost them only 0, 95 LE. With respect to irrigation, this implies that 1m3 of pumped water costs the farm 0, 35 LE when using diesel generators and 0, 19 LE when using solar energy.[1] Using an alternative energy, such as Photovoltaic Systems, is thus more cost-effective for remote desert farms. (For more information see Irrigation Practices in Egypt).



Solar Irrigation in Egypt's Agricultural Sector

With 96 % of desert land, a high frequency of clear sky days and solar radiations ranging from 2000 kW/h in the north up to 2600 kW/h (m²/year) in the south, Egypt is one of the most potential countries in the MENA region for solar energy. The introduction of solar powered pumps presents an opportunity to abandon non-sustainable and non-reliable fossil fuel powered generators. Furthermore, the implementation of solar powered irrigation helps overcoming the risk from fluctuations in both fuel and supply prices, and instead guarantees stable and reliable on farm energy supply. Therewith, crop losses that result from insufficient irrigation are avoided.



The Initiative 'RaSeed'

For this reason, the German development programme “Agricultural Water Productivity as Adaptation to Climate Change” on behalf of the German Federal Ministry of Economic Cooperation and Development (BMZ) called into life the initiative ‘RaSeed'.[2] The initiative aims to promote the use of Photovoltaic (PV) systems in drip irrigation farming in order to support cost-effective and sustainable agriculture. Therefore, the aim is to introduce high capacity solar operated water pumps - of up to a pump size of 100kW - to the Egyptian agricultural sector. Furthermore, soil in the “New Lands” is mostly sandy, and water used for irrigation is ground water. Hence, it is crucial to use water efficient irrigation systems. RaSeed targets farm specific optimization of drip irrigation systems that enable maximum fuel savings and water efficiency by taking into account soil compositions and environmental conditions. In order to further the initiative, a Private Public Partnership (PPP) was established with a solar energy firm (Ashoff Solar] that is supported by the multi-donor initiative Powering Agriculture - an Energy Grand Challenge for Development’. Together with its partners, RaSeed establishes a network, providing high quality solar energy technology and training in Egypt.

Egyptian Desert.jpg
Solar Panels in Egypt.jpg
Crop Cultivation in Desert.jpg
New Lands.jpg


Solar Pump Systems in Egypt

There are different options available when it comes to solar pump systems for irrigation. Generally speaking, the most commonly used PV cells are polycrystalline and monocrystalline cells. RaSeed opted for polycrystalline cells, although, monocrystalline cells are the most efficient ones. However, given that most of the farms in Egypt are located in remote desert areas, far away from on-grid systems and in-house cabling, polycrystalline cells have a better cost-efficiency ratio. Which solar pump system is best suited depends on various external factors. Stand-alone solar pump systems for direct irrigation offer a very simple solution, with the pump and a solar inverter being directly connected. However, this system does not provide a backup power source. Therefore, three different and more advanced solar pump systems were made available by the partnering firms:

Battery Based System

To maximize independence of fuel price fluctuation, a so called Battery Based Hybrid System uses batteries in order to store any excess energy, making it a good option for full- day operations. However, the batteries and their mandatory replacement over time make this system also very cost intensive. In this setup kWp will cost between 33,000 LE to 47,000 LE, with the batteries making up almost half of these costs.

Battery Based Solar System.png



Solar Fuel Saver System

To avoid fluctuations in the irrigation schedule and to prolong irrigation hours one may prefer a hybrid system, which combines solar and diesel power. A so called solar fuel saver system avoids the aforementioned high battery costs; by using a controller that ensures continued operations. This system costs only around 16,000 LE per kWp and is therefore much cheaper than the battery based hybrid system. However, this system requires a constantly running diesel generator, despite solar energy being the main energy source.

Solar Fuel Saver System.png



Variable Speed Drive

The variable speed drive system is probably the most adequate for the Egyptian agricultural sector. This system uses a variable speed drive that connects and regulates PV Panels and the diesel generator. Depending on solar irradiation and the size of the power plant, the diesel generator can be turned off completely. Furthermore, the variable speed drive system is the most cost efficient, with 15,000 LE per kWp.

Variable Speed Drive system.png



Pilot Projects

Three pilot projects that were initiated mostly at the end of 2014 are supported by the RaSeed initiative in order to promote and assess the feasibility and efficiency of solar energy irrigation systems under different conditions - hot weather, high soil salinity and sand storms. They are implemented at different locations across Egypt, allowing for a pluralistic analysis of solar irrigation systems in desert areas over time.

1. SEKEM- the Bahareiya Oasis
The solar powered irrigation system (45kWp) at the Bahareiya Oasis that was built at the end of 2014 is exposed to extreme heat (45-50 o C during summer time), which can have a negative effect on the PV panels. Also, due to the extreme remoteness of the farm, only solar energy can be used, implying that the fields can only be irrigated throughout the day (6 h during winter and 8 h during summer time).

2. WADI FOOD- in Wadi El Natroun
In Wadi El Natroun, a hybrid plant of 150kw/p (92Kw pump) was installed at the end of 2014. The irrigation plant is partially powered with diesel fuel (12%). Due to expansions in 2013, 14 % more water and 58% more fuel was needed, which lead to a stark increase in costs. Also, despite a strong water flow (115 m3/h), the water at the farm is extremely saline, and the fields are irrigated 16-18 h during summer time and 12 h during winter time, which could lead to salinization of the fields.

3. PICO- El Mansoureya
The desert farm at the outskirts of Cairo has implemented a central solar powered irrigation system with four pumps (288 kW) and a fuel saver system. The pumps reach 180 meters deep. However the existing generators are massively oversized, which has caused efficiency and distribution problems.



Further Information


References

  1. To generate 100 m³ of water per hour, the solar pump has to be driven with around 70kWp. This requires the application of solar panels on an area of around 550m² to 800m².
  2. RaSeed is composed of the words Ra & Seed. Ra refers to the pharaonic god of the sun, which stands for energy and life, while a seed is the basis for all agricultural activities. At the same time, Raseed can be translated to ‘Credit’ in Arabic.