Experimental study on impact of high voltage power transmission lines on silicon photovoltaics using artificial neural network

Muhammad Rameez Javed, M. Hussain, Mudassar Usman, Furqan Asghar, Muhammad Shahid, Waseem Amjad, Gwi Hyun Lee, A. Waleed
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Abstract

The recent trend of renewable energy has positioned solar cells as an excellent choice for energy production in today’s world. However, the performance of silicon photovoltaic (PV) panels can be influenced by various environmental factors such as humidity, light, rusting, temperature fluctuations and rain, etc. This study aims to investigate the potential impact of high voltage power transmission lines (HVTL) on the performance of solar cells at different distances from two high voltage levels (220 and 500 KV). In fact, HVTLs generate electromagnetic (EM) waves which may affect the power production and photocurrent density of solar cells. To analyze this impact, a real-time experimental setup of PV panel is developed (using both monocrystalline and polycrystalline solar cells), located in the vicinity of 220 and 500 KV HVTLs. In order to conduct this study systematically, the impact of HVTL on solar panel is being measured by varying the distance between the HVTL and the solar panels. However, it is important to understand that the obtained experimental values alone are insufficient for comprehensive verification under various conditions. To address this limitation, an Artificial Neural Network (ANN) is employed to generate HVTL impact curves for PV panels (particularly of voltage and current values) which are impractical to obtain experimentally. The inclusion of ANN approach enhances the understanding of the HVTL impact on solar cell performance across a wide range of conditions. Overall, this work presents the impact study of HVTL on two different types of solar cells at different distances from HVTL for two HV levels (i.e., 220 and 500 KV) and the comparison study of HVTL impact on both monocrystalline and polycrystalline solar cells.
利用人工神经网络对高压输电线路对硅光电池影响的实验研究
近年来,可再生能源的发展趋势使太阳能电池成为当今世界能源生产的最佳选择。然而,硅光伏(PV)板的性能会受到各种环境因素的影响,如湿度、光线、生锈、温度波动和雨水等。本研究旨在调查高压输电线(HVTL)对太阳能电池在两个高压等级(220 千伏和 500 千伏)的不同距离下的性能的潜在影响。事实上,高压输电线会产生电磁波,可能会影响太阳能电池的发电量和光电流密度。为了分析这种影响,我们在 220 KV 和 500 KV HVTL 附近开发了一个光伏电池板实时实验装置(使用单晶和多晶太阳能电池)。为了系统地开展这项研究,我们通过改变 HVTL 与太阳能电池板之间的距离来测量 HVTL 对太阳能电池板的影响。然而,必须了解的是,仅凭获得的实验值不足以在各种条件下进行全面验证。为了解决这一局限性,我们采用了人工神经网络(ANN)来生成光伏电池板的 HVTL 影响曲线(尤其是电压和电流值),而这是无法通过实验获得的。人工神经网络方法的加入增强了对 HVTL 在各种条件下对太阳能电池性能影响的理解。总之,这项研究介绍了两种不同类型的太阳能电池在两个高压水平(即 220 KV 和 500 KV)下与 HVTL 的不同距离对 HVTL 影响的研究,以及 HVTL 对单晶和多晶太阳能电池影响的比较研究。
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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