An experimental assessment of a solar PVT-PCM thermal management system in severe climatic conditions

Solar photovoltaic thermal (PVT) collectors incorporating phase change material (PCM) as an active-passive cooling approach represent a promising solution for thermally managing PV panels. This needs to be experimentally evaluated in harsh outdoor conditions. Therefore, this study examined the electrical and thermal performance of solar PVT systems in comparison to a reference PV panel during six distinct summer days in Riyadh, Saudi Arabia. A thermal camera was utilized to precisely capture the difference in temperature variations between the two PV panels over the study periods and to examine different options for the PVT collector. On Day 3, near noon, the highest solar irradiance of 1019 W/m² led to the highest power of the PVT, with an increase of 5.75 % over the reference panel. The highest ambient temperature of 47.69 °C was recorded on Day 1 with 901.4 W/m² irradiance, providing 10.58 % electrical efficiency of the PVT, an increase of 5.9 %. On Day 6, the PVT module was equipped with eight rectangular metal conduits that were filled with PCM with a transition temperature range of 41–48 °C. This simple-to-implement design added additional passive cooling for the system through the exterior surface of the metal conduits, along with the PCM contribution. The PTV-PCM option led to the best performance, with an 8.05 % improvement in electrical power and efficiency over the reference PV and 71.16 % and 81.50 % thermal and combined PVT efficiencies, respectively. The importance of cooling the PV panel in such challenging circumstances was illustrated by the 2 %–3.24 % increase in electrical output for every 1 °C decrease in the temperature of the cells.