Experimental and computational analyses of a photovoltaic module cooled with an optimized converging channel absorber

IF 8 Q1 ENERGY & FUELS

Energy nexus Pub Date : 2025-02-12 DOI:10.1016/j.nexus.2025.100401

Ali Radwan , Salah Haridy , Aimane Kemel , Ibrahim I. El-Sharkawy , Essam M. Abo-Zahhad

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引用次数: 0

Abstract

The electrical performance of photovoltaic (PV) modules under concentrated illumination significantly declines due to the substantial increase in the module's average temperature, especially in areas with elevated ambient temperatures and high levels of solar radiation, such as the Gulf region. Therefore, implementing efficient thermal management to these modules is required for achieving a lower operating temperature, longer lifespan, higher electrical energy output, and harnessing low-grade thermal energy. Converging absorbers are commonly used in PV module's cooling. However, the optimized design for these absorbers is rarely explored. This study proposes an integrated framework combining outdoor experimental testing, computational modeling, and desirability optimization through response surface methodology (RSM) to fill this gap. This integrated framework is employed to statistically evaluate the impact of the converging channel outlet height (H_out, ranging from 3 mm to 17 mm), cooling fluid velocity (from 0.007 to 0.01 m/s), adhesive material thermal conductivity (from 0.14 to 3.7 W/m·K), and cooling water inlet temperature (25 to 35 °C) at a solar concentration ratio of 3 Suns on various PV module responses. Five responses including module temperature, module temperature non-uniformity, thermal power, net electrical power, and entropy generation rate are evaluated at these ranges of the design factors. Predictive models for these five responses are developed with high coefficients of determination (R²). An analysis of variance is performed to identify the most significant factors and interactions influencing each response. Various optimization scenarios for the responses are explored. Among these, maximizing the thermal and electrical generated power can be attained by using a converging channel with H_out of 3 mm, inlet velocity of 0.0084 m/s, inlet temperature of 20 °C, and adhesive thermal conductivity of 2.94 W/m·K.

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聚光通道吸收器冷却光伏组件的实验与计算分析

由于组件的平均温度大幅增加，特别是在环境温度升高和太阳辐射水平高的地区，如海湾地区，光伏（PV）组件在集中照明下的电性能显着下降。因此，需要对这些模块实施有效的热管理，以实现更低的工作温度，更长的使用寿命，更高的电能输出，并利用低品位的热能。聚光吸收器通常用于光伏组件的冷却。然而，对这些吸收器的优化设计却很少进行探索。本研究通过响应面法（response surface methodology， RSM）提出了一个结合户外实验测试、计算建模和可取性优化的综合框架来填补这一空白。利用这一综合框架，统计评估在太阳能集中比为3太阳时，汇聚通道出口高度（Hout，范围为3 mm ~ 17 mm）、冷却流体速度（0.007 ~ 0.01 m/s）、胶粘剂材料导热系数（0.14 ~ 3.7 W/m·K）和冷却水进口温度（25 ~ 35℃）对各种光伏组件响应的影响。在这些设计因素范围内，评估了模块温度、模块温度不均匀性、热功率、净功率和熵产率等五个响应。这五种反应的预测模型具有高决定系数（R²）。进行方差分析以确定影响每种反应的最重要因素和相互作用。探讨了响应的各种优化方案。其中，采用孔径为3 mm、入口速度为0.0084 m/s、入口温度为20℃、胶粘剂导热系数为2.94 W/m·K的收敛通道，可获得最大的热电功率。

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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来源期刊

Energy nexus Energy (General), Ecological Modelling, Renewable Energy, Sustainability and the Environment, Water Science and Technology, Agricultural and Biological Sciences (General)

CiteScore

7.70

自引率

0.00%

发文量

审稿时长

109 days