混合纳米流体应用于腔道光伏热系统的电效率数值研究

IF 0.7 Q2 MATHEMATICS
A. A. Memon, M. A. Memon, M. Haque
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引用次数: 1

摘要

光伏热系统(PV/T)是用于从太阳能中收集电能和热能的设备。通过将冷却剂通过连接到PV/T系统的流动通道,电池的温度降低,以提高其电力效率。因此,本研究旨在研究基于Cu-Al2O3/水的混合纳米流体传输的光伏热系统。我们假设流道可以在二维上考虑,由硅板、吸收器和流道组成。该流道由沿吸收体的具有固定长度和一定高度的空腔组成。这将是一个综合的传导和对流问题,传导发生在硅板和吸收器的最上面两层。建模和仿真问题使用COMSOL Multiphysics 5.6进行。入口高度与空腔高度的长径比由Ar确定,Al2O3的体积分数为Cu的两倍。通过改变雷诺数(100-1000)、进口温度(50°C - 450°C)、铜体积分数(0.01%-10%)和展弦比(0.5、0.7、0.9和1)对电池效率进行了参数化研究。结果表明,增加进口温度和展弦比会降低电池效率,而增加雷诺数和体积分数会提高电池效率。当进口温度为50℃,铜体积分数为10%,Re = 1000, Ar = 0.5时,电池效率最高,约为6%。当铜的体积分数为0.1时,雷诺数从100增加到1000,电池效率提高了0.5%。另一方面,在Re = 1000时,当铜的体积分数从最小增加到最大时,电池效率提高了0.3%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Numerical Investigation of Electrical Efficiency with the Application of Hybrid Nanofluids for Photovoltaic Thermal Systems Contained in a Cavity Channel
Photovoltaic thermal systems (PV/T) are devices used to collect both electrical and thermal energies from solar energy. By passing a coolant through flow channels that are connected to the PV/T systems, the temperature of the cells is reduced to enhance their electrical efficiency. Therefore, this study aims at investigating a photovoltaic thermal system via the transport of hybrid nanofluids based on Cu-Al2O3/water. We assume that the flow channel can be considered in two dimensions and is composed of the silicon panel, absorber, and flow channel. The flow channel consists of a cavity along the absorber with a fixed length and a certain height. This will be a combined conduction and convection problem, with conduction occurring on the top two layers of the silicon panel and absorber. Modeling and simulation problems are performed using COMSOL Multiphysics 5.6. The aspect ratio from inlet height to cavity height is defined by Ar, and the volume fraction of Al2O3 is taken double that of Cu. The cell efficiency is analyzed by performing a parametric study by altering the Reynold number (100–1000), inlet temperature (50°C–450°C), the volume fraction of copper (0.01%–10%), and the aspect ratio (0.5, 0.7, 0.9, and 1). It is found that increasing the inlet temperature and aspect ratio decreases the cell efficiency while increasing the Reynolds number and volume fraction increases it. The maximum efficiency of the cell, about 6%, is achieved when the inlet temperature is 50°C, the volume fraction of copper is 10%, Re = 1000, and Ar = 0.5. It was also concluded that when the volume fraction of copper is 0.1, the increase in Reynolds number from 100 to 1000 is improving the cell efficiency by 0.5%. On the other hand, when increasing the volume fraction of copper from minimum to maximum at Re = 1000, the cell efficiency is increasing by 0.3%.
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