Difference between revisions of "SPIS Design"
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| + | {{SPIS Design}} {{Back to SPIS Toolbox}}<br/> | ||
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=== '''<span style="color: rgb(135, 150, 55);">Module Aim and Orientation</span>''' === | === '''<span style="color: rgb(135, 150, 55);">Module Aim and Orientation</span>''' === | ||
| − | This module provides information and tools for agricultural service providers on how to estimate the dimensions, type and financial viability of Solar Powered Irrigation Systems for a specific farming situation. An SPIS consists of multiple components that work under constantly varying daily and seasonal conditions. | + | This module provides information and tools for agricultural service providers on how to estimate the dimensions, type and financial viability of Solar Powered Irrigation Systems for a specific farming situation. An SPIS consists of multiple components that work under constantly varying daily and seasonal conditions. <span class="mw-customtoggle-SPIS3" style="color: blue; font-size: small; font-weight: bold; float: right; display: inline-block;"><span class="mw-customtoggletext">read more</span></span> |
| − | <span class="mw-customtoggle-SPIS3" style="color: blue; font-size: small; font-weight: bold; float: right; display: inline-block;"><span class="mw-customtoggletext">read more</span></span> | ||
<div id="mw-customcollapsible-SPIS3" class="mw-collapsible mw-collapsed"> | <div id="mw-customcollapsible-SPIS3" class="mw-collapsible mw-collapsed"> | ||
| − | + | The design of an SPIS lays the foundation for the system’s technical, financial and environmental viability. In particular with regard to financial implications and the risk of unsustainable water abstraction, the decision requires thorough consideration. Therefore, this module is also highly relevant for financial service providers. For more this module should enable the advisor to judge whether the installation of an SPIS would be more suitable and viable than using alternative irrigation systems. The tools are described and referred to in the different process steps of this module. Important design parameters can be estimated with simplified formulas to gain insights into understanding a more detailed design. Given the complex interactions between the different components under different environments, the tools of this module do not replace a detailed technical design created by professionals in solar and irrigation technology. | |
| − | The design of an SPIS lays the foundation for the system’s technical, financial and environmental viability. In particular with regard to financial implications and the risk of unsustainable water abstraction, the decision requires thorough consideration. Therefore, this module is also highly relevant for financial service providers. For more this module should enable the advisor to judge whether the installation of an SPIS would be more suitable and viable than using alternative irrigation systems. The tools are described and referred to in the different process steps of this module. Important design parameters can be estimated with simplified formulas to gain insights into understanding a more detailed design. Given the complex interactions between the different components under different environments, the tools of this module do not replace a detailed technical design created by professionals in solar and irrigation technology. | ||
</div> | </div> | ||
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=== '''<span style="color: rgb(135, 150, 55);">Process Steps</span>''' === | === '''<span style="color: rgb(135, 150, 55);">Process Steps</span>''' === | ||
| − | Before designing an SPIS, it is important to assess the opportunities and threats of an SPIS in a particular area. The institutional setting and environmental aspects, as described in the '''[[SPIS - Promote & Initiate|PROMOTE & INITIATE]]''' and the '''[[SPIS Safeguard Water|SAFEGUARD WATER]]''' modules, are important framework conditions. | + | Before designing an SPIS, it is important to assess the opportunities and threats of an SPIS in a particular area. The institutional setting and environmental aspects, as described in the '''[[SPIS - Promote & Initiate|PROMOTE & INITIATE]]''' and the '''[[SPIS Safeguard Water|SAFEGUARD WATER]]''' modules, are important framework conditions. <span class="mw-customtoggle-SPIS4" style="color: blue; font-size: small; font-weight: bold; float: right; display: inline-block;"><span class="mw-customtoggletext">read more</span></span> |
| − | <span class="mw-customtoggle-SPIS4" style="color: blue; font-size: small; font-weight: bold; float: right; display: inline-block;"><span class="mw-customtoggletext">read more</span></span> | ||
<div id="mw-customcollapsible-SPIS4" class="mw-collapsible mw-collapsed"> | <div id="mw-customcollapsible-SPIS4" class="mw-collapsible mw-collapsed"> | ||
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In addition, local, up-to-date information on markets for input and output (crop sales) and other information are key to deciding whether designing an SPIS for a particular location makes sense at all. Once it is confirmed that an SPIS is the preferred option, it is crucial that design adheres to the intended use. Once the crop water requirements, solar radiation and system pressure have been established, the technical design can then be prepared. The technical planner can choose from a number of methods of varying complexity and accuracy to come up with a final design. Before deciding on a particular contract provider, the cost quotation from the system integrator should be thoroughly assessed. | In addition, local, up-to-date information on markets for input and output (crop sales) and other information are key to deciding whether designing an SPIS for a particular location makes sense at all. Once it is confirmed that an SPIS is the preferred option, it is crucial that design adheres to the intended use. Once the crop water requirements, solar radiation and system pressure have been established, the technical design can then be prepared. The technical planner can choose from a number of methods of varying complexity and accuracy to come up with a final design. Before deciding on a particular contract provider, the cost quotation from the system integrator should be thoroughly assessed. | ||
</div> | </div> | ||
=== '''<span style="color: rgb(135, 150, 55);">Chapters</span>'''<br/> === | === '''<span style="color: rgb(135, 150, 55);">Chapters</span>'''<br/> === | ||
| − | '''1. [[SPIS Toolbox - Collect Data|Collect data]]'''<br/> | + | '''1. [[SPIS Toolbox - Collect Data|Collect data]]'''<br/>'''2. [[SPIS Toolbox - Analyze Agricultural Production Options|Analyze agricultural production options]]'''<br/>'''3. [[SPIS Toolbox - Determine Water Requirements and Availability|Determine water requirement and availability]]'''<br/>'''4. [[SPIS Toolbox - Select SPIS Configuration|Select SPIS configuration]]'''<br/>'''5. [[SPIS Toolbox - Estimate System Size and Costs|Estimate system size and costs]]'''<br/>'''6. [[SPIS Toolbox - Assess Financial Viability|Assess financial viability]]'''<br/>'''7. [[SPIS Toolbox - Pre-select Potential Suppliers|Pre-select potential suppliers]]'''<br/>'''8. [[SPIS Toolbox - Evaluate Quotations and Assess Quality|Evaluate quotations and assess quality]]'''<br/>'''9. [[SPIS Toolbox - Contract Supplier|Contract supplier]]'''<br/> |
| − | '''2. [[SPIS Toolbox - Analyze Agricultural Production Options|Analyze agricultural production options]]'''<br/> | ||
| − | '''3. [[SPIS Toolbox - Determine Water Requirements and Availability|Determine water requirement and availability]]'''<br/> | ||
| − | '''4. [[SPIS Toolbox - Select SPIS Configuration|Select SPIS configuration]]'''<br/> | ||
| − | '''5. [[SPIS Toolbox - Estimate System Size and Costs|Estimate system size and costs]]'''<br/> | ||
| − | '''6. [[SPIS Toolbox - Assess Financial Viability|Assess financial viability]]'''<br/> | ||
| − | '''7. [[SPIS Toolbox - Pre-select Potential Suppliers|Pre-select potential suppliers]]'''<br/> | ||
| − | '''8. [[SPIS Toolbox - Evaluate Quotations and Assess Quality|Evaluate quotations and assess quality]]'''<br/> | ||
| − | '''9. [[SPIS Toolbox - Contract Supplier|Contract supplier]]'''<br/> | ||
=== '''<span style="color: rgb(135, 150, 55);">Supplementary Tools</span>''' === | === '''<span style="color: rgb(135, 150, 55);">Supplementary Tools</span>''' === | ||
| − | *'''[[:File:DESIGN | + | *'''[[:File:DESIGN Site Data Collection Template.docx|DESIGN – Site Data Collection Tool]]''' |
| − | *'''[[:File:DESIGN – SPIS Suitability Checklist | + | *'''[[:File:DESIGN – SPIS Suitability Checklist.xlsx|DESIGN – SPIS Suitability Checklist]]''' |
| − | *'''[[:File:DESIGN | + | *'''[[:File:DESIGN - Pump Sizing Tool 1.xlsm|DESIGN – Pump Sizing Tool]]'''<br/> |
| + | **''Watch the instruction video ''[https://www.youtube.com/watch?v=hyEESxjQOZQ&t=275s here]'' to learn more!''<br/> | ||
| − | === '''<span style="color: | + | === '''<span style="color: rgb(135, 150, 55);">Tutorial Videos</span>'''<br/> === |
| + | |||
| + | *[https://www.youtube.com/watch?v=ADNwqcrxykA&list=PLu657ZvVdWgD0P16LyGbCxkYyTmN-wkBU&index=6 SPIS: Farm Suitability and Finding the Right Pump - YouTube]<br/> | ||
| + | *[https://www.youtube.com/watch?v=szgcPhHZ410&list=PLu657ZvVdWgDYWwFEVpmTOzccpPqkQ9ln&index=6 SPIS: Farm Suitability and Finding the Right Pump (in Swahili)]<br/> | ||
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| + | === '''<span style="color: rgb(135, 150, 55);">Further Readings</span>'''<br/> === | ||
*Alfredson, T. & Cungu´, A. (2008): Negotiation Theory and Practice. A Review of the Literature. FAO. Retrieved from [http://bit.ly/2p5mRM6 http://www.fao.org/docs/up/easypol/550/4-5_negotiation_background_paper_179en.pdf] | *Alfredson, T. & Cungu´, A. (2008): Negotiation Theory and Practice. A Review of the Literature. FAO. Retrieved from [http://bit.ly/2p5mRM6 http://www.fao.org/docs/up/easypol/550/4-5_negotiation_background_paper_179en.pdf] | ||
| − | <span class="mw-customtoggle-SPIS38" style="font-size:small; font-weight: bold; display:inline-block; | + | <span class="mw-customtoggle-SPIS38" style="color: blue; font-size: small; font-weight: bold; float: right; display: inline-block;"><span class="mw-customtoggletext">read more</span></span> |
<div id="mw-customcollapsible-SPIS38" class="mw-collapsible mw-collapsed"> | <div id="mw-customcollapsible-SPIS38" class="mw-collapsible mw-collapsed"> | ||
| − | |||
*Food and Agriculture Organization: Land & Water. Retrieved from [http://www.fao.org/land-water/en/ http://www.fao.org/land-water/en/] | *Food and Agriculture Organization: Land & Water. Retrieved from [http://www.fao.org/land-water/en/ http://www.fao.org/land-water/en/] | ||
*GRUNDFOS. Retrieved from [http://de.grundfos.com/ http://de.grundfos.com/] | *GRUNDFOS. Retrieved from [http://de.grundfos.com/ http://de.grundfos.com/] | ||
| + | |||
The Grundfos sizing software is called WebCAPS and can be found at [http://net.grundfos.com/Appl/WebCAPS http://net.grundfos.com/Appl/WebCAPS]. It works only for the company’s borepump products, the SQF range, although the site gives you the option of selecting surface pumps. | The Grundfos sizing software is called WebCAPS and can be found at [http://net.grundfos.com/Appl/WebCAPS http://net.grundfos.com/Appl/WebCAPS]. It works only for the company’s borepump products, the SQF range, although the site gives you the option of selecting surface pumps. | ||
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*NASA (2016): Surface meteorology and Solar Energy. With the cooperation of Atmospheric Science Data Centre. Retrieved from [http://eosweb.larc.nasa.gov/sse http://eosweb.larc.nasa.gov/sse] | *NASA (2016): Surface meteorology and Solar Energy. With the cooperation of Atmospheric Science Data Centre. Retrieved from [http://eosweb.larc.nasa.gov/sse http://eosweb.larc.nasa.gov/sse] | ||
</div> | </div> | ||
| + | {{SPIS Magic Words}} | ||
| − | + | [[Category:SPIS_Toolbox]] | |
Revision as of 13:38, 20 April 2021
| Template:SPIS Arabic | Template:SPIS French | Template:SPIS Spanish |
Module Aim and Orientation
This module provides information and tools for agricultural service providers on how to estimate the dimensions, type and financial viability of Solar Powered Irrigation Systems for a specific farming situation. An SPIS consists of multiple components that work under constantly varying daily and seasonal conditions. read more
The design of an SPIS lays the foundation for the system’s technical, financial and environmental viability. In particular with regard to financial implications and the risk of unsustainable water abstraction, the decision requires thorough consideration. Therefore, this module is also highly relevant for financial service providers. For more this module should enable the advisor to judge whether the installation of an SPIS would be more suitable and viable than using alternative irrigation systems. The tools are described and referred to in the different process steps of this module. Important design parameters can be estimated with simplified formulas to gain insights into understanding a more detailed design. Given the complex interactions between the different components under different environments, the tools of this module do not replace a detailed technical design created by professionals in solar and irrigation technology.
Process Steps
Before designing an SPIS, it is important to assess the opportunities and threats of an SPIS in a particular area. The institutional setting and environmental aspects, as described in the PROMOTE & INITIATE and the SAFEGUARD WATER modules, are important framework conditions. read more
In addition, local, up-to-date information on markets for input and output (crop sales) and other information are key to deciding whether designing an SPIS for a particular location makes sense at all. Once it is confirmed that an SPIS is the preferred option, it is crucial that design adheres to the intended use. Once the crop water requirements, solar radiation and system pressure have been established, the technical design can then be prepared. The technical planner can choose from a number of methods of varying complexity and accuracy to come up with a final design. Before deciding on a particular contract provider, the cost quotation from the system integrator should be thoroughly assessed.
Chapters
1. Collect data
2. Analyze agricultural production options
3. Determine water requirement and availability
4. Select SPIS configuration
5. Estimate system size and costs
6. Assess financial viability
7. Pre-select potential suppliers
8. Evaluate quotations and assess quality
9. Contract supplier
Supplementary Tools
- DESIGN – Site Data Collection Tool
- DESIGN – SPIS Suitability Checklist
- DESIGN – Pump Sizing Tool
- Watch the instruction video here to learn more!
- Watch the instruction video here to learn more!
Tutorial Videos
- SPIS: Farm Suitability and Finding the Right Pump - YouTube
- SPIS: Farm Suitability and Finding the Right Pump (in Swahili)
Further Readings
- Alfredson, T. & Cungu´, A. (2008): Negotiation Theory and Practice. A Review of the Literature. FAO. Retrieved from http://www.fao.org/docs/up/easypol/550/4-5_negotiation_background_paper_179en.pdf
read more
- Food and Agriculture Organization: Land & Water. Retrieved from http://www.fao.org/land-water/en/
- GRUNDFOS. Retrieved from http://de.grundfos.com/
The Grundfos sizing software is called WebCAPS and can be found at http://net.grundfos.com/Appl/WebCAPS. It works only for the company’s borepump products, the SQF range, although the site gives you the option of selecting surface pumps.
- Irrigation Association (2017): Irrigation Glossary. Retrieved from http://www.irrigation.org/IAGlossary
- LORENTZ: Submersible Solar Pumps. Retrieved from https://www.lorentz.de/products-and-technology/pump-types/submersible-solar-pumps
- NASA (2016): Surface meteorology and Solar Energy. With the cooperation of Atmospheric Science Data Centre. Retrieved from http://eosweb.larc.nasa.gov/sse
