Difference between revisions of "Solar Powered Irrigation Systems - Technology, Economy, Impacts"

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'''Important note:''' The underlying report&nbsp;of this article about Solar Powered Irrigation Systems is <u>currently unavailable</u> due to a forthcoming revision. We apologize for any inconvenience. The&nbsp;report will be uploaded as soon as the revision process&nbsp;is completed.<br/>
  
 
= Background<br/> =
 
= Background<br/> =
  
The Deutsche Gesellschaft für Internationale Zusammenarbeit (GIZ) GmbH has commissioned a worldwide study on technical solutions and management practices related to solar-powered irrigation systems (SPIS). The study is developed in close cooperation with the sector program Poverty-oriented Basic Energy Services (HERA), which has more than three decades of experience in the field of energy access. Based on actual technical innovations and good practices in applying photovoltaic technology in water extraction and conveyance for agricultural purposes, a manual and tools for the promotion of SPIS in the development sector and beyond will be developed.<br/>
+
Irrigated agriculture is the backbone of local economic development in the majority of developing countries. Reliable and affordable access to irrigation water is a crucial factor as the [[Powering Agriculture: Irrigation|article on irrigation]]&nbsp;emphasizes already.<br/>
  
The manual and the tools shall cater for the main issues of<br/>
+
The technological option of Solar Powered Irrigation Systems (SPIS) is rarely taken into consideration due to a lack of pertinent experience and the comparably high investment costs of the past. Nevertheless, as prices for solar modules have fallen substantially in recent years, governments, extension services and technical cooperation are reconsidering photovoltaic water pumps (PVP) to be employed in agricultural production and beyond. Demand in this regard will have to be largely generated from the side of rural farm households themselves.<br/>
  
*Information and knowledge sourcing;<br/>
+
As indicated by the Powering Agriculture Energy Grand Challenge (PAEGC), some barriers exist, which hinder the integration of “clean” energy technology in agriculture development:<br/>
*Technology choice and suitability;<br/>
 
*Assessment of financial viability and environmental impacts;<br/>
 
*Determination of operation and maintenance (O&M) implications;<br/>
 
*Identification of required and recommended promotion measures accompanying support measures.<br/>
 
  
&nbsp;<br/>
+
*Farmers and extension services are not aware of the variety of new technologies that may be appropriate for them;<br/>
 +
*Clean energy technologies are relatively new, therefore farmers have limited access to distributors for installation, parts, and service;<br/>
 +
*Farmers often do not have the means to cover high capital costs associated with clean energy upgrades - and financing is seldom available.<br/>
  
The development of the SPIS-manual and the related tools follows a two-step approach, comprising
+
The Deutsche Gesellschaft für Internationale Zusammenarbeit (GIZ) GmbH is implementing BMZ’s contribution to this initiative and has commissioned a worldwide study on technical solutions and management practices related to solar-powered irrigation systems (SPIS). The study is developed in close cooperation with the sector program Poverty-oriented Basic Energy Services ([http://www.giz.de/fachexpertise/html/2769.html HERA]), which has more than three decades of experience in the field of [[Access to Modern Energy|energy access]].<br/>
  
*An initial stocktaking and analysis based on information generated by practitioners and researchers worldwide, backed-up by case studies from the German international cooperation (Step 1);<br/>
+
<br/>
*The development of the manual, guidelines and assessment and decision-making tools based on experience with existing publications, thereby addressing the requirements of the development sector (Step 2).<br/>
 
  
&nbsp;
+
= Overview of Irrigation Technologies&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;<br/> =
  
The present&nbsp;[https://energypedia.info/images/4/45/Stocktaking_and_Analysis_Report_-_Final_Draft.pdf Stocktaking and Analysis Report] captures the findings of the study’s first step. It is based on literature review, desk research and four country case studies in Chile, India, Kenya and Morocco executed in the period between December 2014 and February 2015.<br/>
+
This chapter gives an overview about modern irrigation technologies, their advantages and disadvantages, required energy sources as well as financial aspects:<br/>
  
The information collected during the stocktaking and analysis step of the study will be a source of information for the subsequent development of the SPIS promotion and planning manual and tools. Main results and findings of this first step have been discussed in the framework of a stakeholder workshop hosted by GIZ in March 2015 ([https://energypedia.info/images/4/45/Stocktaking_and_Analysis_Report_-_Final_Draft.pdf Minutes of the Workshop]).<br/>
+
*<u>General types of irrigation</u><br/>
 +
**[[Surface Irrigation|Surface irrigation]]<br/>
 +
**[[Sprinkler Irrigation|Sprinkler irrigation]]<br/>
 +
**[[Drip Irrigation|Drip irrigation]]<br/>
 +
**Comparison of sprinkler and drip irrigation<br/>
  
<br/>
+
*Micro-sprinkler irrigation<br/>
 +
 
 +
*<u>Modern water-saving irrigation solutions</u><br/>
 +
**Cropping pattern requirements<br/>
 +
**Efficiency and durability<br/>
  
= Overview of Irrigation Technologies&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;<br/> =
+
*<u>Energy sources for water abstraction and pressurized irrigation</u><br/>
 +
**General classification and description<br/>
 +
**Hybrid solutions<br/>
  
This chapter gives an overview about modern irrigation technologies, their advantages and disadvantages, required energy sources as well as financial aspects:<br/>
+
*<u>Pumping technology for water abstraction and irrigation</u><br/>
 +
*<u>[[Comparative Financial Analysis of Irrigation Solutions|Comparative financial analysis of irrigation solutions]]</u><br/>
 +
**Generic costs of irrigation solutions<br/>
 +
**Financial impact on farm budgets<br/>
 +
**Financial services requirements<br/>
  
*General types of irrigation<br/>
+
*<u>Financial calculation models</u><br/>
*Modern water-saving irrigation solutions<br/>
 
*Energy sources for water abstraction and pressurized irrigation<br/>
 
*Pumping technology for water abstraction and irrigation<br/>
 
*Comparative financial analysis of irrigation solutions<br/>
 
*Financial calculation models<br/>
 
  
►Read more&nbsp;[https://energypedia.info/images/4/45/Stocktaking_and_Analysis_Report_-_Final_Draft.pdf#page=19 here].<br/>
+
► The report is currently under revision and not available on energypedia.<br/>
  
 
<br/>
 
<br/>
Line 46: Line 53:
 
The chapter technical characteristics and design of SPIS introduces the following aspects:<br/>
 
The chapter technical characteristics and design of SPIS introduces the following aspects:<br/>
  
*Components of photovoltaic pumping systems<br/>
+
*<u>Components of photovoltaic pumping systems</u><br/>
*SPIS plant concepts<br/>
+
**Solar generator<br/>
*Planning and sizing of SPIS<br/>
+
**Mounting and solartracking systems<br/>
 +
**Controller and motor<br/>
 +
**Water pump<br/>
 +
**Water storage tank<br/>
 +
**Monitoring&nbsp;<br/>
 +
 
 +
*<u>SPIS plant concepts</u><br/>
 +
**Variability of global solar radiation<br/>
 +
**SPIS plant configurations and operation<br/>
 +
**Suitability for drip irrigation<br/>
 +
**Filter systems<br/>
 +
**Fertigation systems<br/>
 +
 
 +
*<u>Planning and sizing of SPIS</u><br/>
 +
**Design data collection<br/>
 +
**Estimation of PV generator size<br/>
 +
**EXCEL-based system sizing<br/>
 +
**Computer-based system sizing and simulation<br/>
 +
**Land requirements for SPIS<br/>
  
►Read more&nbsp;[https://energypedia.info/images/4/45/Stocktaking_and_Analysis_Report_-_Final_Draft.pdf#page=61 here].<br/>
+
► The report is currently under revision and not available on energypedia.<br/>
  
 
<br/>
 
<br/>
Line 58: Line 83:
 
For assessing the specific management requirements of PV irrigation systems, it is advisable to distinguish between strategic, tactical and operational management:<br/>
 
For assessing the specific management requirements of PV irrigation systems, it is advisable to distinguish between strategic, tactical and operational management:<br/>
  
*Stakeholder in the SPIS management<br/>
+
*<u>Stakeholder in the SPIS management</u><br/>
*Impacts on strategic farm management<br/>
+
*<u>Impacts on strategic farm management</u><br/>
*Impacts on tactical farm management<br/>
+
 
*Impacts on operational farm management<br/>
+
*<u>Impacts on tactical farm management</u><br/>
  
►Read more&nbsp;[https://energypedia.info/images/4/45/Stocktaking_and_Analysis_Report_-_Final_Draft.pdf#page=104 here].<br/>
+
*<u>Impacts on operational farm management</u><br/>
 +
 
 +
► The report is currently under revision and not available on energypedia.<br/>
  
 
<br/>
 
<br/>
Line 71: Line 98:
 
Financial viability is the ability to generate sufficient income to meet operating expenditure, financing needs and, ideally, to allow profit generation. Each irrigation technology choice has its limitations in terms of the range of crops it can support in production. On the other hand, the investment costs attached to the choice of technology limit the range of crops to select for production to a large extent. Pressurized irrigation systems in general and micro irrigation systems in particular are on the capitalintensive side of investments for irrigation infrastructure and equipment.<br/>
 
Financial viability is the ability to generate sufficient income to meet operating expenditure, financing needs and, ideally, to allow profit generation. Each irrigation technology choice has its limitations in terms of the range of crops it can support in production. On the other hand, the investment costs attached to the choice of technology limit the range of crops to select for production to a large extent. Pressurized irrigation systems in general and micro irrigation systems in particular are on the capitalintensive side of investments for irrigation infrastructure and equipment.<br/>
  
This chapter explains respective parameters for assessing financial viability and provides an exemplary financial analysis of eight SPIS systems.<br/>
+
This chapter explains respective parameters for assessing financial viabilit, provides an exemplary financial analysis of eight SPIS systems and includes business models for SPIS.<br/>
  
&nbsp;►Read more&nbsp;[https://energypedia.info/images/4/45/Stocktaking_and_Analysis_Report_-_Final_Draft.pdf#page=111 here].<br/>
+
&nbsp;► The report is currently under revision and not available on energypedia.<br/>
  
 
<br/>
 
<br/>
Line 79: Line 106:
 
= Ecological Impacts and Sustainability of SPIS<br/> =
 
= Ecological Impacts and Sustainability of SPIS<br/> =
  
Apart from being a cost-competitive and reliable source of electricity, photovoltaic systems generate a number of ecologic benefits. This chapter describes the ecological impacts and sustainability aspects of SPIS, as well as associated water governance issues.<br/>
+
Apart from being a cost-competitive and reliable source of electricity, photovoltaic systems generate a number of ecologic benefits. This chapter describes:&nbsp;<br/>
 +
 
 +
*<u>Ecological impacts:</u><br/>
 +
**The Carbon Footprint of photovoltaic systems<br/>
 +
**Energy payback time<br/>
 +
**Recycling of solar panels<br/>
 +
**Reducing the risk of groundwater depletion<br/>
 +
**Avoidance of groundwater contamination<br/>
 +
**Reducing soil salination<br/>
 +
**Avoidance of noise and exhaust fumes emissions<br/>
 +
 
 +
*<u>Sustainability of SPIS:</u><br/>
 +
**Technical reliability of system components<br/>
 +
**Detected failures and trouble shooting<br/>
 +
**Availability of SPIS components on local markets<br/>
 +
**Spare parts and after sales service<br/>
 +
**Acceptance of SPIS<br/>
 +
 
 +
*<u>Water governance issues</u><br/>
  
►Read more&nbsp;[https://energypedia.info/images/4/45/Stocktaking_and_Analysis_Report_-_Final_Draft.pdf#page=129 here].&nbsp;<br/>
+
► The report is currently under revision and not available on energypedia.<br/>
  
 
<br/>
 
<br/>
Line 89: Line 134:
 
In this chapter, a selection of the individual software tools will be presented. The information has been compiled from reliable documented and published references/resources as cited in the publication. The following tools are presented:<br/>
 
In this chapter, a selection of the individual software tools will be presented. The information has been compiled from reliable documented and published references/resources as cited in the publication. The following tools are presented:<br/>
  
*Design and simulation tools for PV pumps<br/>
+
*<u>Design and simulation tools for PV pumps</u><br/>
*Design and simulation tools for irrigation systems<br/>
+
*<u>Design and simulation tools for irrigation systems</u><br/>
*Calculation tools for irrigation requirements<br/>
+
*<u>Calculation tools for irrigation requirements</u><br/>
  
&nbsp;►Read more&nbsp;[https://energypedia.info/images/4/45/Stocktaking_and_Analysis_Report_-_Final_Draft.pdf#page=158 here].<br/>
+
&nbsp;► The report is currently under revision and not available on energypedia.<br/>
  
 
<br/>
 
<br/>
Line 101: Line 146:
 
Country case studies were carried out in Chile, India, Kenya and Morocco as part of the stocktaking and analysis exercise. The selection of countries was made to have a worldwide bias and an insight into different markets and market scopes:<br/>
 
Country case studies were carried out in Chile, India, Kenya and Morocco as part of the stocktaking and analysis exercise. The selection of countries was made to have a worldwide bias and an insight into different markets and market scopes:<br/>
  
*Chile: Widespread utilization of PV pumping technology in irrigation, strong promotion of SPIS by government, main target group small tomedium farms (2 - 5 ha), but also larger farms up to 30 ha under PVirrigation;<br/>
+
*<u>Chile</u>: Widespread utilization of PV pumping technology in irrigation, strong promotion of SPIS by government, main target group small to medium farms (2 - 5 ha), but also larger farms up to 30 ha under PV irrigation;<br/>
*India: High level of water abstraction with pumps, ambitious government program to replace conventional pumps by PV technology, main target group small to medium farms (2 - 5 ha), local products/systems on the market;<br/>
+
*<u>India</u>: High level of water abstraction with pumps, ambitious government program to replace conventional pumps by PV technology, main target group small to medium farms (2 - 5 ha), local products/systems on the market;<br/>
*Kenya: Very high share of smallholders (< 2 ha) and high potential to develop dry lands by PV pumping from groundwater, local products on the market;<br/>
+
*<u>Kenya</u>: Very high share of smallholders (< 2 ha) and high potential to develop dry lands by PV pumping from groundwater, local products on the market;<br/>
*Morocco: Main market for suppliers like Lorentz and Grundfos, medium (10 – 15 ha) and large size commercial farms utilizing PV pumping<br/>
+
*<u>Morocco</u>: Main market for suppliers like Lorentz and Grundfos, medium (10 – 15 ha) and large size commercial farms utilizing PV pumping<br/>
  
&nbsp;►Read more&nbsp;[https://energypedia.info/images/4/45/Stocktaking_and_Analysis_Report_-_Final_Draft.pdf#page=169 here].<br/>
+
&nbsp;► The report is currently under revision and not available on energypedia.<br/>
  
 
<br/>
 
<br/>
Line 114: Line 159:
 
Several barriers need to be overcome in developing countries to develop their huge PV potential. This chapter gives a brief overview of key drivers for solar pumps and key hurdles that stand in the way of SPIS dissemination. An opportunity and risk assessment in the following aspects has been conducted:<br/>
 
Several barriers need to be overcome in developing countries to develop their huge PV potential. This chapter gives a brief overview of key drivers for solar pumps and key hurdles that stand in the way of SPIS dissemination. An opportunity and risk assessment in the following aspects has been conducted:<br/>
  
&nbsp;<u>Opportunity assessment:</u><br/>
+
*&nbsp;<u>Opportunity assessment</u><br/>
 
+
**Global PV market growth<br/>
*Global PV Market Growth<br/>
+
**Diesel generator replacement<br/>
*Diesel Generator Replacement<br/>
+
**Greenfield development<br/>
*Greenfield Development<br/>
+
**Technology access to smallholders<br/>
*Technology Access to Smallholders<br/>
+
**Bridging grid power failures<br/>
*Bridging Grid Power Failures<br/>
+
**Job creation and local production<br/>
*Job Creation and Local Production<br/>
+
**Innovation potential<br/>
*Innovation Potential<br/>
 
  
 
&nbsp;<br/>
 
&nbsp;<br/>
  
<u>Risk assessment:</u><br/>
+
*<u>Assessment of Barriers and Risks</u><br/>
 +
**High initial investment cost<br/>
 +
**Lack of market-oriented financing<br/>
 +
**Oil price development<br/>
 +
**Lack of market-oriented policies<br/>
 +
**Lack of awareness and impact monitoring<br/>
 +
**Lack of quality assurance and service<br/>
 +
**Natural disasters and theft<br/>
 +
**Summary of opportunity and risks<br/>
  
*High initial investment cost<br/>
+
► The report is currently under revision and not available on energypedia.<br/>
*Lack of market-oriented financing<br/>
 
*Oil price development<br/>
 
*Lack of marked-oriented policies<br/>
 
*Lack of awareness and impact monitoring<br/>
 
*Lack of quality assurance and service<br/>
 
*Natural disasters and theft<br/>
 
*Summary of opportunity and risks<br/>
 
 
 
►Read more&nbsp;[https://energypedia.info/images/4/45/Stocktaking_and_Analysis_Report_-_Final_Draft.pdf#page=184 here].<br/>
 
  
 
<br/>
 
<br/>
 
 
  
 
= Conclusions and Recommendations<br/> =
 
= Conclusions and Recommendations<br/> =
  
The analysis in this report underline that photovoltaic powered irrigation is a technically mature option, even when it is not yet very widespread. Solar powered water pumping can be built into irrigation systems in different ways. The introduced case studies from different countries give an insight into the wide range of application of the technology. From a technical point of view, photovoltaic water pumping can be integrated into most irrigation concepts. The technological development on the side of the pump manufacturers is far advanced and the market can hence provide a suitable pumping solution for almost any requirement and condition. This includes the integration of PV pumps into hybrid systems.<br/>
+
The analysis in this report underlines that photovoltaic powered irrigation is a technically mature option, even when it is not yet very widespread. Solar powered water pumping can be built into irrigation systems in different ways. The introduced case studies from different countries give an insight into the wide range of application of the technology. From a technical point of view, photovoltaic water pumping can be integrated into most irrigation concepts. The technological development on the side of the pump manufacturers is far advanced and the market can hence provide a suitable pumping solution for almost any requirement and condition. This includes the integration of PV pumps into hybrid systems.<br/>
  
 
The information collection and the analysis brought together in this report show that agronomic and financial feasibility requirements limit the range of application of PV technology in irrigation. The promotion of the technology will have to take these limits into account by departing from the fact that the utilization of PV technology requires a high initial capital investment and technological know-how for system design and development.<br/>
 
The information collection and the analysis brought together in this report show that agronomic and financial feasibility requirements limit the range of application of PV technology in irrigation. The promotion of the technology will have to take these limits into account by departing from the fact that the utilization of PV technology requires a high initial capital investment and technological know-how for system design and development.<br/>
Line 151: Line 192:
 
The absence of suitable financing products catering for the specific needs of SPIS development (high initial capital needs, no additional collateral options, long repayment period) is an obstacle to the dissemination of the technology. Good examples like in India and Morocco show that corresponding loan financing is an option, even though it may require a particular risk management.<br/>
 
The absence of suitable financing products catering for the specific needs of SPIS development (high initial capital needs, no additional collateral options, long repayment period) is an obstacle to the dissemination of the technology. Good examples like in India and Morocco show that corresponding loan financing is an option, even though it may require a particular risk management.<br/>
  
►Read more&nbsp;[https://energypedia.info/images/4/45/Stocktaking_and_Analysis_Report_-_Final_Draft.pdf#page=200 here].<br/>
+
► The report is currently under revision and not available on energypedia.<br/>
  
 +
<br/>
 +
 +
= Reference<br/> =
 +
 +
The report is currently under revision and not available on energypedia (see the important notes&nbsp;on top of the article for more details).<br/>
 +
 +
<br/>
 +
 +
<br/>
  
 
= Further Information<br/> =
 
= Further Information<br/> =
  
 +
*[[Toolbox on SPIS|Toolbox on Solar Powered Irrigation Systems on energypedia]]
 
*[[Drip Irrigation|Drip irrigation]]<br/>
 
*[[Drip Irrigation|Drip irrigation]]<br/>
 
*[[Powering Agriculture: Irrigation|Irrigation on Powering Agriculture Portal]]<br/>
 
*[[Powering Agriculture: Irrigation|Irrigation on Powering Agriculture Portal]]<br/>
*[[:File:Stocktaking and Analysis Report - Final Draft.pdf|Manual and Tools for Promoting SPIS – Stocktaking and Analysis Report]]<br/>
 
 
*[[Sprinkler Irrigation|Sprinkler irrigation]]<br/>
 
*[[Sprinkler Irrigation|Sprinkler irrigation]]<br/>
 
*[[Surface Irrigation|Surface irrigation]]<br/>
 
*[[Surface Irrigation|Surface irrigation]]<br/>
*[[Portal:Powering Agriculture|Powering Agriculture Portal on energypedia]]<br/>
+
*[[Portal:Water and Energy for Food|Water and Energy for Food (WE4F) portal on energypedia]]
  
 
[[Category:Irrigation]]
 
[[Category:Irrigation]]
 +
[[Category:Water-Energy-Food_Nexus]]
 +
[[Category:Water_Supply]]
 +
[[Category:Solar_Pumping]]
 
[[Category:Powering_Agriculture]]
 
[[Category:Powering_Agriculture]]
 
[[Category:Solar]]
 
[[Category:Solar]]

Latest revision as of 21:28, 14 July 2020

Important note: The underlying report of this article about Solar Powered Irrigation Systems is currently unavailable due to a forthcoming revision. We apologize for any inconvenience. The report will be uploaded as soon as the revision process is completed.

Background

Irrigated agriculture is the backbone of local economic development in the majority of developing countries. Reliable and affordable access to irrigation water is a crucial factor as the article on irrigation emphasizes already.

The technological option of Solar Powered Irrigation Systems (SPIS) is rarely taken into consideration due to a lack of pertinent experience and the comparably high investment costs of the past. Nevertheless, as prices for solar modules have fallen substantially in recent years, governments, extension services and technical cooperation are reconsidering photovoltaic water pumps (PVP) to be employed in agricultural production and beyond. Demand in this regard will have to be largely generated from the side of rural farm households themselves.

As indicated by the Powering Agriculture Energy Grand Challenge (PAEGC), some barriers exist, which hinder the integration of “clean” energy technology in agriculture development:

  • Farmers and extension services are not aware of the variety of new technologies that may be appropriate for them;
  • Clean energy technologies are relatively new, therefore farmers have limited access to distributors for installation, parts, and service;
  • Farmers often do not have the means to cover high capital costs associated with clean energy upgrades - and financing is seldom available.

The Deutsche Gesellschaft für Internationale Zusammenarbeit (GIZ) GmbH is implementing BMZ’s contribution to this initiative and has commissioned a worldwide study on technical solutions and management practices related to solar-powered irrigation systems (SPIS). The study is developed in close cooperation with the sector program Poverty-oriented Basic Energy Services (HERA), which has more than three decades of experience in the field of energy access.


Overview of Irrigation Technologies     

This chapter gives an overview about modern irrigation technologies, their advantages and disadvantages, required energy sources as well as financial aspects:

  • Micro-sprinkler irrigation
  • Modern water-saving irrigation solutions
    • Cropping pattern requirements
    • Efficiency and durability
  • Energy sources for water abstraction and pressurized irrigation
    • General classification and description
    • Hybrid solutions
  • Financial calculation models

► The report is currently under revision and not available on energypedia.


Technical Characteristics and Design of SPIS     

The chapter technical characteristics and design of SPIS introduces the following aspects:

  • Components of photovoltaic pumping systems
    • Solar generator
    • Mounting and solartracking systems
    • Controller and motor
    • Water pump
    • Water storage tank
    • Monitoring 
  • SPIS plant concepts
    • Variability of global solar radiation
    • SPIS plant configurations and operation
    • Suitability for drip irrigation
    • Filter systems
    • Fertigation systems
  • Planning and sizing of SPIS
    • Design data collection
    • Estimation of PV generator size
    • EXCEL-based system sizing
    • Computer-based system sizing and simulation
    • Land requirements for SPIS

► The report is currently under revision and not available on energypedia.


Management Requirements of SPIS    

For assessing the specific management requirements of PV irrigation systems, it is advisable to distinguish between strategic, tactical and operational management:

  • Stakeholder in the SPIS management
  • Impacts on strategic farm management
  • Impacts on tactical farm management
  • Impacts on operational farm management

► The report is currently under revision and not available on energypedia.


Financial Viability of SPIS

Financial viability is the ability to generate sufficient income to meet operating expenditure, financing needs and, ideally, to allow profit generation. Each irrigation technology choice has its limitations in terms of the range of crops it can support in production. On the other hand, the investment costs attached to the choice of technology limit the range of crops to select for production to a large extent. Pressurized irrigation systems in general and micro irrigation systems in particular are on the capitalintensive side of investments for irrigation infrastructure and equipment.

This chapter explains respective parameters for assessing financial viabilit, provides an exemplary financial analysis of eight SPIS systems and includes business models for SPIS.

 ► The report is currently under revision and not available on energypedia.


Ecological Impacts and Sustainability of SPIS

Apart from being a cost-competitive and reliable source of electricity, photovoltaic systems generate a number of ecologic benefits. This chapter describes: 

  • Ecological impacts:
    • The Carbon Footprint of photovoltaic systems
    • Energy payback time
    • Recycling of solar panels
    • Reducing the risk of groundwater depletion
    • Avoidance of groundwater contamination
    • Reducing soil salination
    • Avoidance of noise and exhaust fumes emissions
  • Sustainability of SPIS:
    • Technical reliability of system components
    • Detected failures and trouble shooting
    • Availability of SPIS components on local markets
    • Spare parts and after sales service
    • Acceptance of SPIS
  • Water governance issues

► The report is currently under revision and not available on energypedia.


Tools for Technical Design and Economic Assessment

In this chapter, a selection of the individual software tools will be presented. The information has been compiled from reliable documented and published references/resources as cited in the publication. The following tools are presented:

  • Design and simulation tools for PV pumps
  • Design and simulation tools for irrigation systems
  • Calculation tools for irrigation requirements

 ► The report is currently under revision and not available on energypedia.


Country Case Studies

Country case studies were carried out in Chile, India, Kenya and Morocco as part of the stocktaking and analysis exercise. The selection of countries was made to have a worldwide bias and an insight into different markets and market scopes:

  • Chile: Widespread utilization of PV pumping technology in irrigation, strong promotion of SPIS by government, main target group small to medium farms (2 - 5 ha), but also larger farms up to 30 ha under PV irrigation;
  • India: High level of water abstraction with pumps, ambitious government program to replace conventional pumps by PV technology, main target group small to medium farms (2 - 5 ha), local products/systems on the market;
  • Kenya: Very high share of smallholders (< 2 ha) and high potential to develop dry lands by PV pumping from groundwater, local products on the market;
  • Morocco: Main market for suppliers like Lorentz and Grundfos, medium (10 – 15 ha) and large size commercial farms utilizing PV pumping

 ► The report is currently under revision and not available on energypedia.


Potential and Barriers for SPIS Distribution

Several barriers need to be overcome in developing countries to develop their huge PV potential. This chapter gives a brief overview of key drivers for solar pumps and key hurdles that stand in the way of SPIS dissemination. An opportunity and risk assessment in the following aspects has been conducted:

  •  Opportunity assessment
    • Global PV market growth
    • Diesel generator replacement
    • Greenfield development
    • Technology access to smallholders
    • Bridging grid power failures
    • Job creation and local production
    • Innovation potential

 

  • Assessment of Barriers and Risks
    • High initial investment cost
    • Lack of market-oriented financing
    • Oil price development
    • Lack of market-oriented policies
    • Lack of awareness and impact monitoring
    • Lack of quality assurance and service
    • Natural disasters and theft
    • Summary of opportunity and risks

► The report is currently under revision and not available on energypedia.


Conclusions and Recommendations

The analysis in this report underlines that photovoltaic powered irrigation is a technically mature option, even when it is not yet very widespread. Solar powered water pumping can be built into irrigation systems in different ways. The introduced case studies from different countries give an insight into the wide range of application of the technology. From a technical point of view, photovoltaic water pumping can be integrated into most irrigation concepts. The technological development on the side of the pump manufacturers is far advanced and the market can hence provide a suitable pumping solution for almost any requirement and condition. This includes the integration of PV pumps into hybrid systems.

The information collection and the analysis brought together in this report show that agronomic and financial feasibility requirements limit the range of application of PV technology in irrigation. The promotion of the technology will have to take these limits into account by departing from the fact that the utilization of PV technology requires a high initial capital investment and technological know-how for system design and development.

The absence of suitable financing products catering for the specific needs of SPIS development (high initial capital needs, no additional collateral options, long repayment period) is an obstacle to the dissemination of the technology. Good examples like in India and Morocco show that corresponding loan financing is an option, even though it may require a particular risk management.

► The report is currently under revision and not available on energypedia.


Reference

The report is currently under revision and not available on energypedia (see the important notes on top of the article for more details).



Further Information

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