Analysis of the Effects of Hard Shading Pattern on I–V Performance Curve

Complex shading on a photovoltaic (PV) module has a disproportionate impact on its power production. Minimizing power losses is critical in the installation of the PV module since it can greatly diminish the module’s performance and capacity to generate electricity. Thorough examination of the conse...

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Veröffentlicht in:	Applied solar energy 2023-08, Vol.59 (4), p.369-377
Hauptverfasser:	Ismail, Mohd Azlan, Adil, Nur Lyana Jasmin, Yan, Farm Yan, Amaludin, Nazrein, Bohari, Nuramalina, Sar-ee, Sherena
Format:	Artikel
Sprache:	eng
Schlagworte:	Direct Conversion of Solar Energy into Electrical Energy Electric power generation Electric power loss Electrical Machines and Networks Engineering High temperature Maximum power Photovoltaic cells Photovoltaics Power Electronics Shading Solar energy Solar radiation
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container_title	Applied solar energy
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creator	Ismail, Mohd Azlan Adil, Nur Lyana Jasmin Yan, Farm Yan Amaludin, Nazrein Bohari, Nuramalina Sar-ee, Sherena
description	Complex shading on a photovoltaic (PV) module has a disproportionate impact on its power production. Minimizing power losses is critical in the installation of the PV module since it can greatly diminish the module’s performance and capacity to generate electricity. Thorough examination of the consequences of hard shading on the PV modules is necessary to lower power losses and maximize the module’s efficacy. This paper presents the background and findings from three different types of PV module (Full Cell, Half-Cut and Shingle PV module) operated under a variety of shading pattern (horizontal, vertical, and diagonal), and obscuring percentage (25, 50, and 75%). Experiments are conducted in a location at Sabah, a state located within Malaysia. Sabah which has a tropical climate with high temperatures and humidity, along with consistent level of solar radiation throughout the year making it well-suited for solar energy production. The experimental technique, which involved testing PV modules under various shading patterns and percentages, was found to be highly accurate in determining the amount of shading loss, particularly in instances of hard shading. The findings are presented by I – V and P – V curve that was traced by using a portable PV power meter (SEAWARD PV200) relating the pattern and percentage of shading to maximum power point (MPP) and power losses of the PV modules.
doi_str_mv	10.3103/S0003701X23700020
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subjects	Direct Conversion of Solar Energy into Electrical Energy Electric power generation Electric power loss Electrical Machines and Networks Engineering High temperature Maximum power Photovoltaic cells Photovoltaics Power Electronics Shading Solar energy Solar radiation
title	Analysis of the Effects of Hard Shading Pattern on I–V Performance Curve
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