Modeling the future of irrigation: A parametric description of pressure compensating drip irrigation emitter performance

Drip irrigation is a means of distributing the exact amount of water a plant needs by dripping water directly onto the root zone. It can produce up to 90% more crops than rain-fed irrigation, and reduce water consumption by 70% compared to conventional flood irrigation. Drip irrigation may enable mi...

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Veröffentlicht in:	PloS one 2017-04, Vol.12 (4), p.e0175241-e0175241
Hauptverfasser:	Shamshery, Pulkit, Wang, Ruo-Qian, Tran, Davis V, Winter V, Amos G
Format:	Artikel
Sprache:	eng
Schlagworte:	Agricultural economics Agricultural Irrigation Agricultural production Agriculture Biology and Life Sciences Climate change Crops Crops, Agricultural Design and construction Developing countries Diaphragm Diaphragms (mechanics) Drip irrigation Emergency preparedness Emitters Engineering Engineering and Technology Flood irrigation Flow control Flow rates Flow velocity Fluid dynamics Fluid-structure interaction Food Food supply Irrigation Irrigation water Laboratories LDCs Mechanical engineering Models, Theoretical Moisture content Parameterization Performance enhancement Physical Sciences Poverty Pressure Pressure variations Prototypes Rain Root zone Solid mechanics Stress concentration Theory Trickle irrigation Water consumption Water content Water distribution Water engineering
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creator	Shamshery, Pulkit Wang, Ruo-Qian Tran, Davis V Winter V, Amos G
description	Drip irrigation is a means of distributing the exact amount of water a plant needs by dripping water directly onto the root zone. It can produce up to 90% more crops than rain-fed irrigation, and reduce water consumption by 70% compared to conventional flood irrigation. Drip irrigation may enable millions of poor farmers to rise out of poverty by growing more and higher value crops, while not contributing to overconsumption of water. Achieving this impact will require broadening the engineering knowledge required to design new, low-cost, low-power drip irrigation technology, particularly for poor, off-grid communities in developing countries. For more than 50 years, pressure compensating (PC) drip emitters-which can maintain a constant flow rate under variations in pressure, to ensure uniform water distribution on a field-have been designed and optimized empirically. This study presents a parametric model that describes the fluid and solid mechanics that govern the behavior of a common PC emitter architecture, which uses a flexible diaphragm to limit flow. The model was validated by testing nine prototypes with geometric variations, all of which matched predicted performance to within R2 = 0.85. This parametric model will enable irrigation engineers to design new drip emitters with attributes that improve performance and lower cost, which will promote the use of drip irrigation throughout the world.
doi_str_mv	10.1371/journal.pone.0175241
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subjects	Agricultural economics Agricultural Irrigation Agricultural production Agriculture Biology and Life Sciences Climate change Crops Crops, Agricultural Design and construction Developing countries Diaphragm Diaphragms (mechanics) Drip irrigation Emergency preparedness Emitters Engineering Engineering and Technology Flood irrigation Flow control Flow rates Flow velocity Fluid dynamics Fluid-structure interaction Food Food supply Irrigation Irrigation water Laboratories LDCs Mechanical engineering Models, Theoretical Moisture content Parameterization Performance enhancement Physical Sciences Poverty Pressure Pressure variations Prototypes Rain Root zone Solid mechanics Stress concentration Theory Trickle irrigation Water consumption Water content Water distribution Water engineering
title	Modeling the future of irrigation: A parametric description of pressure compensating drip irrigation emitter performance
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