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Performance evaluation of solar PV pumping system for providing irrigation through micro-irrigation techniques using surface water resources in hot arid region of India

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  • Santra, Priyabrata

Abstract

Solar PV pumping system for irrigation purpose has been gained importance in recent times considering its environmental friendly characteristics and to reduce the dependency on fossil fuel based energy sources for pumping. In general, 3 HP and 5 HP capacity solar PV pumping systems are used for irrigation purpose in India. However, large capacity pumps are often also used to lift groundwater resources, which may lead to further depletion of ground water table. Keeping in mind these constraints, performance of small sized solar PV pumps of 1 HP capacity was evaluated to lift and irrigate shallow water resources using pressurized irrigation systems. Experimental observations revealed that 1 HP solar PV pumping system either AC or DC type could successfully be used to operate mini-sprinklers, micro-sprinklers and drippers with good irrigation uniformity. Further, a self-sustainable module for sustainable use of water and energy was designed in which both water and energy are harvested and recycled. Life cycle cost analysis showed that 1 HP (DC) solar PV pumping system was slightly cheaper than corresponding AC pumping system. Even, the carbon footprint of 1 HP solar PV pumping systems is quite lower (0.009 kg CO2-eq ha-mm−1) than grid-connected electric pumps (1.214 kg CO2-eq ha-mm−1) and diesel operated pumps (0.382 kg CO2-eq ha-mm−1). Therefore, 1 HP solar PV pumping systems could be a feasible solution for small and marginal farmers in the context of water scarcity situation in near future and to mitigate the climate change effects in agricultural farms.

Suggested Citation

  • Santra, Priyabrata, 2021. "Performance evaluation of solar PV pumping system for providing irrigation through micro-irrigation techniques using surface water resources in hot arid region of India," Agricultural Water Management, Elsevier, vol. 245(C).
  • Handle: RePEc:eee:agiwat:v:245:y:2021:i:c:s0378377420321016
    DOI: 10.1016/j.agwat.2020.106554
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    Cited by:

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    2. Chatterjee, Juhi & Kantikar, Tejal, 2024. "A Shift to Solar Irrigation Pump-sets: A Field Study of Two Villages in Uttar Pradesh, India," Review of Agrarian Studies, Foundation for Agrarian Studies, vol. 14(1).
    3. Juan Ignacio Herraiz & Rita Hogan Almeida & Manuel Castillo-Cagigal & Luis Narvarte, 2023. "Experimental Performance Evaluation of a PV-Powered Center-Pivot Irrigation System for a Three-Year Operation Period," Energies, MDPI, vol. 16(9), pages 1-19, April.
    4. Elshurafa, Amro M. & Alatawi, Hatem & Hasanov, Fakhri J. & Algahtani, Goblan J. & Felder, Frank A., 2022. "Cost, emission, and macroeconomic implications of diesel displacement in the Saudi agricultural sector: Options and policy insights," Energy Policy, Elsevier, vol. 168(C).
    5. Chatterjee, Juhi & Kanitkar, Tejal, 2024. "A Shift to Solar Irrigation Pump-Sets: A Case Study from Uttar Pradesh, India," Review of Agrarian Studies, Foundation for Agrarian Studies, vol. 14(1), June.

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