An Analytical Model for the Steady-State Thermal Analysis of Façade-Integrated PV Modules Cooled by a Solar Chimney

This paper proposes a steady-state thermal model for the passive cooling of photovoltaic (PV) modules integrated into a vertical building fa & ccedil;ade by means of a solar chimney, including an empirical correlation for turbulent free convection from a vertical isothermal plate. The proposed analytical model estimates the air velocities at the inlet and at the outlet of the ventilation channel of such a cooling system and the average temperature of the fa & ccedil;ade-integrated PV modules. A configuration composed of a maximum of six vertically installed PV modules and one solar chimney is considered. The air velocities at the inlet and at the outlet of the ventilation channel obtained for the case of installing PV modules on the building fa & ccedil;ade are compared with those calculated for the case where the PV modules are integrated into the roof with a slope of 37 degrees. By comparing each of the solutions with one PV module to the corresponding one with six PV modules, it was found that the increase in the air velocity due to the effects of the solar irradiance and the height difference between the two openings of the ventilation channel ranges between 41.05% in the case of "Roof" and 141.14% in the case of "Fa & ccedil;ade". In addition, it was obtained that an increase in the solar chimney height of 1 m leads to a decrease in the average PV section temperature by 1.95-7.21% and 0.65-2.92% in the cases of "Roof" and "Fa & ccedil;ade", respectively. Finally, the obtained results confirmed that the use of solar chimneys for passive cooling of fa & ccedil;ade-integrated PV modules is technically justified.