Journal
JOURNAL OF WIND ENGINEERING AND INDUSTRIAL AERODYNAMICS
Volume 237, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.jweia.2023.105403
Keywords
VAWT; Wake structure; POD; PIV; ABL; Dynamic stall
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Proper orthogonal decomposition (POD) is used to analyze the structure and evolution of the wake behind a model vertical axis wind turbine. The study reveals the presence of high energy coherent structures associated with vortex shedding from dynamic stall and downstream of the tower, as well as the dynamics of the wake interactions. Vortex pairing is identified as an important characteristic of wake evolution. Changing the inflow conditions and the blade sweep angle can reduce the energy associated with dynamic stall, which is beneficial for mitigating fatigue caused by torque and force variations on the blades.
Proper orthogonal decomposition (POD) is used to investigate the structure and evolution of the wake behind a model vertical axis wind turbine. The analysis reveals the high level of energy contained in the coherent structures that mark the vortex shedding due to the dynamic stall on the blades and the vortex shedding downstream of the tower, and the dynamics of the wake interactions. Vortex pairing is shown to be an important feature of the wake evolution. Changing the inflow conditions from a uniform flow to a simulated atmospheric boundary layer flow reduced the relative energy contained in the coherent motions, because of the reduced level of dynamic stall. Similarly, changing the blade sweep angle reduces the modal energy associated with dynamic stall, which is desirable in terms of mitigating fatigue due to torque and force variations on the blades.
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