Abstract
Solar photovoltaic (PV) panels are very slender structures that can be equipped with a tracking system to adjust their orientation and maximise their energy yield. Theses slender structures are exposed to wind loads and their aerodynamic response can vary considerably depending on the wind speed and operating tilt angle ((Formula presented.)) that can be in the range of (Formula presented.). Large-eddy simulations are performed to unveil the governing mechanisms involved in the vortex shedding and mean flow separation around a solar PV panel. Our results show that three regimes can be distinguished: at (Formula presented.), leading-edge vortices are shed and convected along the panel’s surface without significant flow separation; at (Formula presented.), a low-frequency large-scale structure governs the vortex shedding with less-energetic tailing- and leading-edge vortices being shed at higher frequencies; and, at (Formula presented.), the flow on the suction side is fully separated by non-symmetric vortex shedding due to the proximity of the structure to the bottom ground. The highest Strouhal number is observed for (Formula presented.) at which the tilt moment coefficient is also maximum. Decreasing the distance to the ground slightly increased the Strouhal number for negative tilt angles whilst no changes were observed for positive inclinations.
Original language | English |
---|---|
Article number | 322 |
Journal | Fluids |
Volume | 7 |
Issue number | 10 |
DOIs | |
Publication status | Published - 5 Oct 2022 |
Keywords
- ground-mounted
- large-eddy simulation
- solar arrays
- solar PV panel
- tilt angle
- wind load