Numerical research on effect of transition on aerodynamic performance of wind turbine blade with vortex generators

In the inner part of a large wind turbine blade, a thick airfoil is commonly used to guarantee structural integrity and assists the blade to run more easily at high angles of attack in variable winds; its local Reynolds number is less than 3.0 × 106. Under these conditions, flow separation and trans...

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Bibliographic Details
Published in:Journal of renewable and sustainable energy 2016-11, Vol.8 (6)
Main Authors: Zhao, Zhenzhou, Zeng, Guanyu, Wang, Tongguang, Xu, Bofeng, Zheng, Yuan
Format: Article
Language:English
Subjects:
Aerodynamics
Air flow
Angle of attack
Computational fluid dynamics
Fluid flow
Mathematical analysis
Mathematical models
Model accuracy
Reynolds number
Separation
Shear stress
Stalling
Structural integrity
Turbine blades
Vortex generators
Wind turbines
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Summary:In the inner part of a large wind turbine blade, a thick airfoil is commonly used to guarantee structural integrity and assists the blade to run more easily at high angles of attack in variable winds; its local Reynolds number is less than 3.0 × 106. Under these conditions, flow separation and transitions easily occur and exert great impact on blade performance. Vortex generators (VGs) are effective devices used to control flow separation and alter stalling conditions, and hence have been employed in the inner part of the blade in some wind turbines. To clearly understand the aerodynamic performance of a blade with VGs, a blade section employing the thick DU91-W2-250 airfoil and five pairs of VGs is modeled using the transition model. The results for both the coefficient of lift and drag–lift ratio predicted by the transition model are compared with those obtained from the k-ω shear stress transport model and experiment. The comparison demonstrates that the transition model has much higher accuracy. The effects of transition on the distributions of flow stream, shear stress, and vortices from the VGs are investigated and more useful rules are obtained through a comparison between the results of the transition model and the turbulence model at four angles of attack: 5°, 12°, 16°, and 20°.
ISSN:1941-7012
1941-7012
DOI:10.1063/1.4972888