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Advancements in cooling techniques for enhanced efficiency of solar photovoltaic panels: A detailed comprehensive review and innovative classification

•A detailed comprehensive review of photovoltaic panel cooling techniques.•Original classification system for cooling methods applied to photovoltaic panels.•Valuable guidance for future research and insights into improving efficiency.•Automatic spray cooling has the shortest payback period at 1.279...

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Bibliographic Details
Published in:Energy and built environment 2025-04, Vol.6 (2), p.248-276
Main Authors: Akrouch, Mohamad Abou, Chahine, Khaled, Faraj, Jalal, Hachem, Farouk, Castelain, Cathy, Khaled, Mahmoud
Format: Article
Language:English
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Summary:•A detailed comprehensive review of photovoltaic panel cooling techniques.•Original classification system for cooling methods applied to photovoltaic panels.•Valuable guidance for future research and insights into improving efficiency.•Automatic spray cooling has the shortest payback period at 1.279 years.•Phase change materials have varying payback periods between 2.828 and 3.772 years. Solar photovoltaic (PV) cells have emerged as the primary technology for producing green electricity. This innovation harnesses direct sunlight to generate power and its flexibility of installation has drawn significant investment in PV panels. Despite numerous benefits, these cells are hindered by a decline in efficiency caused by elevated cell temperature. As such, researchers have undertaken extensive investigations into possible solutions aimed at enhancing the performance of photovoltaic cells using diverse techniques. This review paper provides a thorough analysis of cooling techniques for photovoltaic panels. It encompasses both passive and active cooling methods, including water and air cooling, phase-change materials, and various diverse approaches. Within each category, it delves into detailed sub-categories, such as evaporative cooling, water immersion, floating systems, water pipes, cooling channels, water sprayers, jet impingement, geothermal cooling, and natural convection enhanced by PV designs. It also covers forced convection using cooling ducts, heat sinks, and air collectors, alongside the integration of Phase Change Materials (PCMs), nanofluids, radiative cooling, thermoelectric methods, heat pipes, heat pumps, and other innovative techniques. Each of these approaches is illustrated with specific schematics and thoroughly discussed and compared. Furthermore, this paper introduces an original classification system for these cooling methods applied to photovoltaic panels, offering valuable guidance for future research and insights into improving efficiency. [Display omitted]
ISSN:2666-1233
2666-1233
DOI:10.1016/j.enbenv.2023.11.002