Abstract
Renewable energy sources are the most useful way to generate clean energy and guide the transition toward green power generation and a low-carbon economy. Among renewables, the best alternative to electricity generation from fossil fuels is solar energy because it is the most abundant and does not release pollutants during conversion processes. Despite the photovoltaic (PV) module ability to produce electricity in an eco-friendly way, PV cells are extremely sensitive to temperature increments. This can result in efficiency drop of 0.25%/ ∘ C to 0.5%/ ∘ C. To overcome this issue, manufacturers and researchers are devoted to the improvement of PV cell efficiency by decreasing operating temperature. For this purpose, the authors have developed a low-cost and high-performance PV cooling system that can drastically reduce module operating temperature. In the present work, the authors present a set of experimental measurements devoted to selecting the PV cooling arrangement that guarantees the best compromise of water-film uniformity, module temperature reduction, water-consumption minimization, and module power production maximization. Results show that a cooling system equipped with 3 nozzles characterized by a spraying angle of 90 ∘ , working with an inlet pressure of 1.5 bar, and which remains active for 30 s and is switched off for 120 s, can reduce module temperature by 28 ∘ C and improve the module efficiency by about 14%. In addition, cost per single module of the cooling system is only 15 €.
Highlights
Energy is the driving force of our society and its availability at reasonable prices influences countries’ development and standard of living.At worldwide level, about one billion people out of 7.5 billion have no access to electricity.these people live in geographical areas, mainly sub-Saharan Africa, rich in both fossil fuels and renewable resources and characterized by the highest 2017 regional real gross domestic product (GDP) growth rate: +3.8% [1]
About one billion people out of 7.5 billion have no access to electricity. These people live in geographical areas, mainly sub-Saharan Africa, rich in both fossil fuels and renewable resources and characterized by the highest 2017 regional real gross domestic product (GDP) growth rate: +3.8% [1]
The first aim of this work is to select the nozzle spraying angle but, after that, other work aims are the allocation of the nozzle number and their operating pressure, which guarantee the compromise between cooling efficiency and water consumption
Summary
About one billion people out of 7.5 billion have no access to electricity These people live in geographical areas, mainly sub-Saharan Africa, rich in both fossil fuels and renewable resources and characterized by the highest 2017 regional real gross domestic product (GDP) growth rate: +3.8% [1]. Despite these key factors, no access to electricity implies an extremely low standard of living, as well as living below the poverty threshold. The energy sector and, in particular, electricity, is essential for the social and economic development of the world population, and for their quality of life. Urbanization and industrialization, as well as a high standard of living, are strictly linked to energy availability
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