A comprehensive study of feasibility and applicability of building integrated photovoltaic (BIPV) systems in regions with high solar irradiance

Building integrated photovoltaic (BIPV) systems at the building scale can not only reduce building energy consumption but also further promote the sustainable development of our society. To enhance the utilization of BIPV systems, this paper reviews their feasibility and applicability in regions with high solar irradiance from many perspectives. Specifically, this paper first investigates the application advantages of the BIPV system in terms of the energy supply and aesthetic value of buildings. Subsequently, several performance influencing factors of the BIPV in regions with high solar irradiance are analyzed independently, such as the PV module temperature, solar radiation intensity, PV module orientation and tilt angle, PV module types, and inverter. Simultaneously, the feasibility of the BIPV system in high solar-irradiance regions is systematically assessed in terms of energy efficiency, environmental benefit, and economic performance. And an ideal coordination model is highlighted to promote the development of the BIPV system. Additionally, the future research direction of the BIPV system in these regions is explored. Overall, this paper can provide valuable information for the development of BIPV systems in regions with high solar irradiance.

Automated summary

This paper examines the feasibility and applicability of building integrated photovoltaic (BIPV) systems in regions with high solar irradiance. Key factors influencing the performance of BIPV systems are analyzed, and the energy efficiency, environmental benefit, and economic performance of the systems are systematically evaluated. A coordination model to promote the development of BIPV systems is highlighted, along with an exploration of future research directions in these regions. Valuable insights for the development of BIPV systems in high solar irradiance regions are provided.