Theoretical and Experimental Study on the Performance of Photovoltaic using Porous Media Cooling under Indoor Condition

I. Masalha, Siti Ujila Binti Masuri, O. Badran, Mohd Khairol Anuar Bin Mohd Ariffin, Abd Rahim Abi Talib, F. Alfaqs
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引用次数: 1

Abstract

This paper presents the theoretical and experimental investigation on performance of a photovoltaic (PV) panel cooled by porous media under indoor condition. Porous media offer a large exterior surface area and a high fluid permeability, making them ideal for PV cells cooling. The photovoltaic panel was cooled using 5 cm thick cooling channel filled with porous media (gravel). Several sizes of porosity (0.35, 0.4, 0.48, and 0.5) at different volume flow rates (1, 1.5, 2, 3, and 4 L/min) were tested to obtain the best cooling process. The theoretical analysis was performed at the optimum case found experimentally, which has a porosity of 0.35 and a volume flow rate of 2 L/min, to test various experimental results of the PV hot surface temperature, related power output, efficiency and I-V characteristic curve. The enhancement obtained in PV power output and efficiency is compared against the case without cooling and the case using water alone without porous media. Results showed that cooling using small size porous media and moderate flow rate is more efficient which reduces the average PV hot surface temperature of about 55.87% and increases the efficiency by 2.13% than uncooled PV. The optimum case reduced the PV hot surface temperature to 38.7°C, and increased the power output to 19 W, efficiency to 6.26%, and the open voltage to 22.77 V. The results showed that the presence of small porous media of 0.35 in the PV cooling process displayed the maximum effectiveness compared to the other two scenarios, because the heat loss from PV surface through porous media layer have developed a homogenous heat diffusion removed much quicker at high flow rate (2 L/min). A good agreement was obtained between experimental and theoretical results for different cases with a standard deviation from 3.2% to 5.6%.
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室内条件下多孔介质冷却光伏性能的理论与实验研究
本文对多孔介质冷却的光伏板在室内条件下的性能进行了理论和实验研究。多孔介质具有大的外表面积和高的流体渗透性,是光伏电池冷却的理想选择。使用填充有多孔介质(砾石)的5cm厚的冷却通道来冷却光伏面板。在不同的体积流速(1、1.5、2、3和4L/min)下测试了几种尺寸的孔隙率(0.35、0.4、0.48和0.5),以获得最佳的冷却工艺。在实验发现的孔隙率为0.35、体积流量为2L/min的最佳情况下进行理论分析,以测试PV热表面温度、相关功率输出、效率和I-V特性曲线的各种实验结果。将PV功率输出和效率的提高与没有冷却的情况和单独使用水而没有多孔介质的情况进行比较。结果表明,使用小尺寸多孔介质和中等流速的冷却更有效,比未冷却的PV降低了约55.87%的平均PV热表面温度,并提高了2.13%的效率。最佳情况下,光伏热表面温度降至38.7°C,功率输出增至19W,效率增至6.26%,开路电压增至22.77V。结果表明,与其他两种情况相比,在光伏冷却过程中存在0.35的小多孔介质显示出最大的有效性,因为PV表面通过多孔介质层的热损失已经形成均匀的热扩散,在高流速(2L/min)下去除得更快。在不同情况下,实验结果和理论结果之间取得了良好的一致性,标准偏差为3.2%至5.6%。
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CiteScore
4.50
自引率
16.00%
发文量
83
审稿时长
8 weeks
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