Difference between revisions of "Hydropower in Powering Agriculture"
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= Overview<br/> = | = Overview<br/> = | ||
Worldwide, hydropower is the most widely used renewable energy resource due to its significant advantages over other renewable resources: high energy density, low cost and reliability in particular. Hydropower plants are available from very small sizes of only few Kilowatts (kW) to multi-Gigawatts (GW). Small hydropower plants, generally in kW range, are used for rural electrification in many countries and have high potential to be integrated into the agriculture value chain in those locations.<br/> | Worldwide, hydropower is the most widely used renewable energy resource due to its significant advantages over other renewable resources: high energy density, low cost and reliability in particular. Hydropower plants are available from very small sizes of only few Kilowatts (kW) to multi-Gigawatts (GW). Small hydropower plants, generally in kW range, are used for rural electrification in many countries and have high potential to be integrated into the agriculture value chain in those locations.<br/> | ||
− | Hydropower, especially small-scale hydropower (up to 1 MW), works according to a simple principle: water from streams or rivers runs through a turbine, the turbine rotates and turns tools (pumps, mills etc.) or a generator which can produce electricity (see | + | Hydropower, especially small-scale hydropower (up to 1 MW), works according to a simple principle: water from streams or rivers runs through a turbine, the turbine rotates and turns tools (pumps, mills etc.) or a generator which can produce electricity (see the figure below). To achieve a reliable production of energy, it is important to have good knowledge about the local water resources and to design the system accordingly.<br/> |
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− | [[File:Micro Hydro Power Plant GIZ.JPG|thumb|left| | + | [[File:Micro Hydro Power Plant GIZ.JPG|thumb|left|750px|Components Micro Hydro Power Plant|link=https://energypedia.info/images/3/3b/Hydro_scout_guide_ET_may10.pdf]]<br/> |
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+ | ► For more information see the [[:File:Hydro scout guide ET may10.pdf|Micro Hydro Power Scout Guide]].<br/> | ||
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= System Example: Smart Hydropower (In-Stream Turbine) <br/> = | = System Example: Smart Hydropower (In-Stream Turbine) <br/> = | ||
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<br/>Calculation for the power equation:<br/> | <br/>Calculation for the power equation:<br/> | ||
− | + | P=ρ*q*g*h*η | |
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− | + | q= water flow rate [m3/s] h= head (falling height) [m] | |
− | + | ρ= density of water (1000[kg/m3]) | |
− | + | η= efficiency of the systems, usually between 50% and 75% for micro/small hydro plants | |
− | + | The theoretical power output of such a hydropower system can be estimated by multiplying the water flow of the river by the height difference from intake to the turbine, the system efficiency as well as some constants (see the calculation). An annual or daily energy yield can be estimated by further multiplying the power output by the number of hours the system is running during this period. An alternative solution is an in-stream turbine. However, this type has not yet been commercially used in a wider scale. | |
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− | + | = Further Information<br/> = | |
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− | <br/> | + | *FAO Study: [[Opportunities for Agri-Food Chains to become Energy-Smart|Opportunities for Agri-Food Chains to become Energy-Smart]]<br/> |
− | + | *[https://gc21.giz.de/ibt/var/app/wp385P/2624/wp-content/uploads/2015/03/PAEGC_MOOC_COMPILED_READER.pdf Reader of the MOOC "Powering Agriculture - Sustainable Energy for Food"]<br/> | |
− | = | + | *[[Portal:Hydro|Hydro Portal on energypedia]]<br/> |
− | + | *<span dir="auto">[[Productive Use of Micro Hydro Power (MHP)|Productive Use of Micro Hydro Power (MHP)]]</span><br/> | |
− | < | + | *[[Portal:Water and Energy for Food|Water and Energy for Food (WE4F) portal on energypedia]] |
+ | [[Category:Agriculture]] | ||
+ | [[Category:Hydro]] | ||
[[Category:Powering_Agriculture]] | [[Category:Powering_Agriculture]] | ||
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Latest revision as of 19:09, 14 July 2020
Overview
Worldwide, hydropower is the most widely used renewable energy resource due to its significant advantages over other renewable resources: high energy density, low cost and reliability in particular. Hydropower plants are available from very small sizes of only few Kilowatts (kW) to multi-Gigawatts (GW). Small hydropower plants, generally in kW range, are used for rural electrification in many countries and have high potential to be integrated into the agriculture value chain in those locations.
Hydropower, especially small-scale hydropower (up to 1 MW), works according to a simple principle: water from streams or rivers runs through a turbine, the turbine rotates and turns tools (pumps, mills etc.) or a generator which can produce electricity (see the figure below). To achieve a reliable production of energy, it is important to have good knowledge about the local water resources and to design the system accordingly.
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► For more information see the Micro Hydro Power Scout Guide.
System Example: Smart Hydropower (In-Stream Turbine)
The Smart Hydropower turbine was developed to produce a maximum amount of electrical power with the kinetic energy of flowing waters. Because it is powered by kinetic energy and not with potential energy it is known as a so-called “zero-head” or “in-stream” turbine. As such, no dams and/or height differences are necessary for the operation of this device; the course of a river remains in its natural state and no high investments in infrastructure are required. Because the amount of kinetic energy (velocity) varies from river to river, the capacity of an in-stream turbine ranges: from a minimum of a few watts to a maximum of 5 kW.
Check out this video to learn more.
Calculation for the power equation:
P=ρ*q*g*h*η
q= water flow rate [m3/s] h= head (falling height) [m]
ρ= density of water (1000[kg/m3])
η= efficiency of the systems, usually between 50% and 75% for micro/small hydro plants
The theoretical power output of such a hydropower system can be estimated by multiplying the water flow of the river by the height difference from intake to the turbine, the system efficiency as well as some constants (see the calculation). An annual or daily energy yield can be estimated by further multiplying the power output by the number of hours the system is running during this period. An alternative solution is an in-stream turbine. However, this type has not yet been commercially used in a wider scale.