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Design and Analysis of Low-Cost and Efficient SEPIC Converter for Affordable Solar Water Pump in Ethiopia

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Abstract:

Abstract. Smallholder farms provide a significant share of the world's food supply. Smallholder farmers can cultivate crops more consistently throughout the year when using solar water pumps, which offer a dependable source of irrigation. However, the upfront capital cost and efficiency are major barriers to widespread adoption. This paper aimed to design a cost-effective and efficient DC-DC converter for small-scale irrigation farming in the Dangishta, Amhara region of Ethiopia, focusing on a direct solar water pump system using a SEPIC-based DC-DC converter. The system directly supplies power to a 100 W/24 V brushless DC pump, with a 120 W/24 V/5 A optimized SEPIC converter. A PLECS simulation was conducted to understand the converter's operation. The prototype design considered enhanced power handling capabilities using the paralleling method. The power switches are controlled by a digital circuit based on the RP2040 microcontroller, which generates PWM signals with a fixed duty cycle at 100 kHz. The average material cost of the converter was significantly minimized to approximately $15. Experimental tests showed an efficiency of 93.5% and an average temperature of 31°C, making it a promising solution for sustainable agriculture in resource-constrained environments.Keywords— Smallholder farms, Low-cost, SEPIC converter, Solar water pump, PLECS

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International Journal of Engineering Research in Africa Vol. 72

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Periodical:

International Journal of Engineering Research in Africa (Volume 72)

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47-69

DOI:

https://doi.org/10.4028/p-3aNeSp

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Online since:

December 2024

Authors:

Minyahil Tanashu*, Tassew Tadiwos, Amare Kassaw, Seifu Admasu, Noam Ezra, Teng Long, Lara Allen, Elizabeth M. Tennyson, Sam Stranks, Tefera Terefe

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Low Cost, PLECS, SEPIC Converter, Smallholder Farms, Solar Water Pump

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