Numerical and Experimental Study of the Impact of Key Parameters on a PVT Air Collector: Mass Flow Rate and Duct Depth

The PVT-air solar system simultaneously generates electrical and thermal energy. Therefore, increasing the cost-effectiveness of the system requires an appropriate choice of key parameters such as mass flow rate and air channel depth. In this paper, a PVT-air kit of a single module with a 30 degrees slope was used to measure photovoltaic electricity and air heating power in the city of Sfax, Tunisia. Besides, a computer method was implemented using the ANSYS Fluent 17.0 software and the MATLAB program to analyse the properties of the airflow and to characterise PVT-air yields under different mass flow rates and depths. From the comparison of numerical and experimental data, the numerical method was validated with a good agreement. Indeed, we have found that increasing of the airflow rate improves the thermal efficiency with a slight change on electrical output. However, the reduction in depth shows an improvement on thermal efficiency and a negligible effect on electrical efficiency. Also, we have presented the thermal and electrical performance of PVT-air as a function of the key parameters with the Hottel-Whillier-Bliss formulation.