Hybrid optimization strategy for water cooling system: enhancement of photovoltaic panels performance

Energy Harvesting and Systems Pub Date : 2024-01-01 DOI:10.1515/ehs-2023-0091

Vijay Pal Singh, Sandeep Kumar Arya, Ajay Shankar

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Abstract

Solar energy is the most effective substitute for fossil fuels when it comes to Produce electricity among the numerous renewable energy sources. The efficiency may drop as a result of overheating, and the PV cell may also be harmed. Therefore, increasing the output of a solar PV system at a lower cost is essential to improving its efficiency. Additionally, by using cooling methods, the PV cells’ lifetime is extended. By lowering the working temperature of a PV panel’s surface, you may increase efficiency and slow the thermal deterioration rate. This may be done by module cooling and lowering the heat that the PV cells generate while operating. Hence, an active cooling technology known as optimization-aided water spraying technique is employed to increase efficiency. This method enables the PV panels to provide their maximum output power while taking less time to drop down to a lower surface temperature. Beluga Whale assisted Jellyfish Optimization (BWJO) model is suggested as a means of achieving these goals. Finally, Simulink/MATLAB is used to implement the suggested method and optimize the PV system cooling. The performances of the two components were compared using a variety of metrics.

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水冷系统的混合优化策略：提高光伏电池板的性能

在众多可再生能源中，太阳能是最有效的化石燃料发电替代品。过热可能导致效率下降，光伏电池也可能受到损害。因此，以较低的成本提高太阳能光伏发电系统的输出功率对提高其效率至关重要。此外，使用冷却方法还能延长光伏电池的使用寿命。通过降低光伏电池板表面的工作温度，可以提高效率并减缓热衰减速度。这可以通过模块冷却和降低光伏电池工作时产生的热量来实现。因此，我们采用了一种称为优化辅助喷水技术的主动冷却技术来提高效率。这种方法可使光伏电池板在提供最大输出功率的同时，用更少的时间降至较低的表面温度。建议采用白鲸辅助水母优化（BWJO）模型来实现这些目标。最后，Simulink/MATLAB 被用来实现所建议的方法并优化光伏系统的冷却。使用各种指标对两个组件的性能进行了比较。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Energy Harvesting and Systems

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