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Generating temperature cycle profiles of different solar photovoltaic module technologies from in-situ conditions for accurate prediction of thermomechanical degradation


Bebeto Nii Sampa Sampah
Frank K. A. Nyarko
Benjamin Atribawuni Asaaga
Jefferson Aggor

Abstract

The IEC61215 TC200 is a rigorous approval thermal cycling test process that assesses the reliability of solar photovoltaic modules and  offers a 25-year lifetime guarantee. However, previous research has shown that installed solar photovoltaic modules experience different  rates of degradation depending on the location and climate with most research focused on crystalline silicon. In this study, outdoor  weathering data obtained from a rig set up in Kumasi, Ghana for the year 2014, is used to generate thermal cycles for 5 different  technologies including monocrystalline, polycrystalline, and amorphous silicon, Copper Indium Gallium Selenide (CIGS) and  Heterojunction-With-Intrinsic-Thin-Layer (HIT). From the results, the highest yearly average of the maximum and minimum  temperatures, and ramp rates of 54.8oC, 26.1oC, and 6.05oC/h respectively are recorded in CIGS. Polycrystalline recorded the least  temperatures of 45.2°C and 23.9°C while HIT recorded the least ramp rate of 4.45°C /h. A comparison between the 2014 and the IEC61215  thermal cycles show extremely wide differences which could explain the higher degradation rates and shorter life of installed solar  photovoltaic modules. The procedure adopted in this research can be repeated at different locations to obtain technology-specific  thermal cycling profiles to evaluate the thermomechanical damage and predict the life of different solar photovoltaic modules. 


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eISSN: 2543-3717