Effect of nanofluid cooling on electrical power of solar panel system in existence of TEG implementing magnetic force
Mashhour A. Alazwari, Ali Basem, Hussein A.Z. AL-bonsrulah, Khalid H. Almitani, Nidal H. Abu‐Hamdeh, Mahmood Shaker Albdeiri, Turki AlQemlas, Galal A. Ahmed Alashaari
Abstract
This study investigates the efficacy of applying a Lorentz force to improve the efficiency of a photovoltaic-thermal (PVT) system featuring a finned duct, while also addressing challenges associated with dust accumulation. The magnetic field helps to prevent nanoparticle aggregation, enhancing the cooling process. The use of a finned duct combined with a nanofluid as the cooling medium efficiently dissipates excess heat from the silicon layer. Dust accumulation on the glass layer reduces transmissivity, negatively impacting system performance. The magnetic field's interaction with the nanoparticles enhances convective cooling of the upper layer, leading to an overall improvement in performance. Increased pumping power results in higher cooling rates, with improvements of approximately 3.48 % in thermal efficiency (η th ), 75.01 % in thermoelectric generator efficiency (η TEG ), and 39.37 % in photovoltaic efficiency (η PV ). An increase in the Hartmann number ( Ha ) improves ηth by about 1.87 %, with corresponding enhancements in electrical performance components. A higher concentration of ferrofluid further boosts performance, with the effect being roughly 1.7 times more significant in the absence of MHD compared to when Ha = 97. Dust presence decreases η th , η TEG , and η PV by approximately 9.39 %, 8.55 %, and 25.77 %, respectively. Furthermore, the presence of Ha diminishes the influence of V in on η th by around 1.33 %.