Experimental and Numerical Study on Air Cooling System Dedicated to Photovoltaic Panels

IF 3 4区 工程技术 Q3 ENERGY & FUELS
Energies Pub Date : 2024-08-09 DOI:10.3390/en17163949
Maksymilian Homa, K. Sornek, W. Goryl
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引用次数: 0

Abstract

The efficiency of solar systems, in particular photovoltaic panels, is typically low. Various environmental parameters affect solar panels, including sunlight, the ambient and module surface temperatures, the wind speed, humidity, shading, dust, the installation height, etc. Among others, the key players are indeed solar irradiance and temperature. The higher the temperature is, the higher the short-circuit current is, and the lower the open-circuit voltage is. The negative effect of lowering the open-circuit voltage is dominant, consequently lowering the power of the photovoltaic panels. Passive or active cooling systems can be provided to avoid the negative effect of temperature. This paper presents a prototype of an active cooling system dedicated to photovoltaics. The prototype of such a system was developed at the AGH University of Kraków and tested under laboratory conditions. The proposed system is equipped with air fans mounted on a plate connected to the rear part of a 70 Wp photovoltaic panel. Different configurations of the system were tested, including different numbers of fans and different locations of the fans. The artificial light source generated a irradiation value of 770 W/m2. This value was present for every variant tested in the experiment. As observed, the maximum power generated in the photovoltaic panel under laboratory conditions was approx. 47.31 W. Due to the temperature increase, this power was reduced to 40.09 W (when the temperature of the uncooled panel surface reached 60 °C). On the other hand, the power generated in the photovoltaic panel equipped with the developed cooling system was approx. 44.37 W in the same conditions (i.e., it was higher by 10.7% compared to that of the uncooled one). A mathematical model was developed based on the results obtained, and simulations were carried out using the ANSYS Workbench software. After the validation procedure, several configurations of the air cooling system were developed and analyzed. The most prominent case was chosen for additional parametrical analysis. The optimum fan orientation was recognized: a vertical tilt of 7° and a horizontal tilt of 10°. For the tested module, this modification resulted in a cost-effective system (a net power increase of ~3.1%).
光伏电池板专用空气冷却系统的实验和数值研究
太阳能系统,尤其是光伏电池板的效率通常很低。影响太阳能电池板的环境参数多种多样,包括阳光、环境温度和组件表面温度、风速、湿度、遮阳、灰尘、安装高度等。其中,太阳辐照度和温度是影响太阳能电池板的关键因素。温度越高,短路电流越大,开路电压越低。降低开路电压的负面影响最大,因此会降低光伏电池板的功率。可提供被动或主动冷却系统来避免温度的负面影响。本文介绍了光伏专用主动冷却系统的原型。这种系统的原型是在克拉科夫 AGH 大学开发的,并在实验室条件下进行了测试。建议的系统配备了风扇,风扇安装在与 70 Wp 光伏板后部相连的板上。测试了该系统的不同配置,包括不同数量的风扇和不同位置的风扇。人工光源产生的辐照值为 770 瓦/平方米。实验中测试的每种变体都达到了这个值。据观察,在实验室条件下,光电板产生的最大功率约为 47.31 W。由于温度升高,功率下降到 40.09 W(当未冷却的光电板表面温度达到 60 °C 时)。另一方面,在相同条件下,配备了所开发冷却系统的光伏电池板的发电功率约为 44.37 W(即比未冷却电池板的发电功率高 10.7%)。根据获得的结果建立了数学模型,并使用 ANSYS Workbench 软件进行了模拟。验证程序结束后,对空气冷却系统的几种配置进行了开发和分析。选择了最突出的情况进行额外的参数分析。确定了最佳风扇方向:垂直倾斜 7°,水平倾斜 10°。对于测试的模块而言,这一修改带来了经济高效的系统(净功率增加约 3.1%)。
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
Energies
Energies ENERGY & FUELS-
CiteScore
6.20
自引率
21.90%
发文量
8045
审稿时长
1.9 months
期刊介绍: Energies (ISSN 1996-1073) is an open access journal of related scientific research, technology development and policy and management studies. It publishes reviews, regular research papers, and communications. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. There is no restriction on the length of the papers. The full experimental details must be provided so that the results can be reproduced.
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