Abstract
Counter-rotating vortex generators (VGs) are typically employed to delay airflow separation on wind turbine blades. Large-size wind turbine blades equipped with small size VGs make the computational fluid dynamics (CFD) researches require a great deal of computational resources. Parametric models of VGs can effectively improve the numerical research efficiency of wind turbine blades with VGs. In order to improve the accuracy of such parametric models, this study proposed a series of modeling approaches to determine the positions of the adding source term in Cartesian coordinates, the VG vortex core radius, etc., on the wind turbine airfoils. These techniques are integrated with a maximum circulation algorithm by considering the interactions between VG pairs to predict the performance of a DU91-W2-250 blade section with VGs. The proposed parametric model and an entity model at different angles of attack (AoAs) are implemented on the blade section. Our approach is validated using experimental data. Comparisons demonstrate a strong agreement between the modelled and experimental results, proving the high accuracy of the two models. The numerical results of the models are then compared and analyzed at different incoming flow velocities and AoAs to verify the universality of the proposed parametric approaches. The results reveal a high consistency between the vortex structure, the velocity profile above the blade surface and the distribution of the pressure coefficient calculated by the two models. This proves the high universality of the proposed approaches and demonstrates the potential of the parametric model in replacing the VG entity model. The VG parametric model expresses VG parameters by program, which can improve the research efficiency of VG arrangement on wind turbine blades.
Highlights
The vortex generator (VG), initially proposed by Taylor (1947), is a passive flow control technology that can effectively improve the aerodynamic performance of wind turbine blades
Considering that counter-rotating triangle type VG arrays are generally mounted on the wind turbine blade, Zhao et al (2017) accounted for the inter-effects between VG pairs to propose an algorithm for VG pairs
Trailing Vortex Profile and Circulation Validation We model a pair of VGs on a flat plane via the parametric and entity models
Summary
The vortex generator (VG), initially proposed by Taylor (1947), is a passive flow control technology that can effectively improve the aerodynamic performance of wind turbine blades. The jBAY model was developed to improve its predecessor by replacing the VGs with non-thickness mesh surfaces (Jirásek, 2004) These two models fail to substantially reduce the grid number in the VG region. Dudek (2006) employed Wendt’s algorithm to predict the performance of a rectangular Booker and Zhang (2009) proposed a circulation algorithm for large-scale VGs, in which the tangential velocity and axial velocity distribution are set in a cylinder region by the source term to model the topology structure of the trailing vortex. The proposed model exhibited a higher accuracy than those of Zhang and Wendt
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
