Effect of inhomogeneous loads on the mechanics of PV modules

In contrast to homogeneous mechanical load according to IEC 61215, photovoltaic modules in the field are mainly exposed to inhomogeneous loads like snow or wind. This paper deals with such inhomogeneous loads using computational fluid dynamics and finite element method simulations. Temperatures different to room temperature and the choice of encapsulates have significant influences on the thermomechanics of a photovoltaic module in case of snow load. Polyolefin is the encapsulant with the lowest storage modulus and has the lowest overall stress in solar cells and glass down to -30 & DEG;C. Furthermore, with colder temperatures, the first principal stress decreases in solar cells but increases in the glass. For wind loads, the impact of module orientation, wind direction, module inclination angle, and wind speed is analyzed. A crosswind scenario is found to be most critical. Additionally, as a rule of thumb, higher module inclination angles result in higher stresses. Finally, general thermomechanical rules are extracted allowing for a deeper understanding of the underlying effects and therefore help to build more robust modules in the future. Mechanical loads are one of the most common reasons for solar cell and front glass breakage within PV modules. In contrast to the IEC 612151 certification, the load is often distributed inhomogeneously. In this paper, such inhomogeneous loads, caused by snow and wind, are analyzed and general thermomechanical rules are derived.image

Automated summary

This paper uses computational fluid dynamics and finite element method simulations to analyze the impact of inhomogeneous loads like snow and wind on photovoltaic modules. The choice of encapsulants and temperatures different to room temperature are found to have significant influences on the thermomechanics of the modules. The study also examines the effects of module orientation, wind direction, module inclination angle, and wind speed on wind loads. General thermomechanical rules are derived to help improve the robustness of future modules. Evaluation: 7/10.