Influence of vortex generators chord position on airfoil dynamic stall

被引:0
|
作者
Jiang R. [1 ]
Zhao Z. [1 ,2 ]
Wang T. [3 ]
Meng L. [1 ]
Chen M. [1 ]
Feng J. [1 ]
机构
[1] College of Energy and Electrical Engineering, Hohai University, Nanjing
[2] Institute of Ocean and Offshore Engineering, Hohai University, Nantong
[3] Jiangsu Key Laboratory of Hi-Tech Research for Wind Turbine Design, Nanjing University of Aeronautics and Astronautics, Nanjing
来源
Taiyangneng Xuebao/Acta Energiae Solaris Sinica | 2022年 / 43卷 / 11期
关键词
Dynamic stall; Flow control; K-ω SST turbulence model; Numerical simulation; Vortex generators; Wind turbines;
D O I
10.19912/j.0254-0096.tynxb.2021-0484
中图分类号
学科分类号
摘要
The dynamic stall process of DU91-W2-250 blade section with delta wing vortex generators(VGs) is studied by using the k-ω SST turbulence model. The effect and law of the chordal position of VGs(x/c) on the dynamic stall inhibition is analyzed from the aspects of the lift and drag coefficient, surface pressure coefficient, flow field and the development process of VGs shedding vortex. The results show that x/c has a great influence on the lift increase effect during the dynamic stall of airfoil, and VGs increase the stall angle of attack of airfoil. The results of lift, resistance and pressure show that when x/c=0.25, the lift increase effect is the best, and the Cp on the upper surface of the blade section is larger. When x/c=0.20-0.25, the trailing edge adhesion flow is better. From the change of vorticity peak value, when the value of x/c is too large or too small, the inhibition effect of VGs on separated vortex is weakened. According to the variation of VGs shedding vortex, when x/c=0.20-0.25, the shedding vortex intensity is relatively large downstream of VGs, and the vortex dissipation velocity is slow. In conclusion, when the VGs are installed at x/c=0.20-0.25, the aerodynamic performance of the blade section can be improved best. © 2022, Solar Energy Periodical Office Co., Ltd. All right reserved.
引用
收藏
页码:253 / 258
页数:5
相关论文
共 12 条
  • [1] TIMMER W A., Wind tunnel results for a 25% thick wind turbine blade airfoil, European Community Wind Energy Conference, (1993)
  • [2] ZHONG Y C, CHEN X., The influence of geometric parameters of triangle embedded vortex generator on its vortex, Journal of aeronautical dynamics, 11, 3, pp. 241-244, (1996)
  • [3] ALLAN B G, YAO C, LIN J C., Numerical simulations of vortex generator vanes and jets on a flat plate, 1st Flow Control Conference, (2002)
  • [4] ZHANG J, ZHANG B Q, YAN W C, Et al., Experimental study on boundary layer separation of supercritical airfoil controlled by micro vortex generator, Experimental fluid dynamics, 19, 3, pp. 58-60, (2005)
  • [5] LIN J C., Review of research on low-profile vortex generators to control boundary-layer separation, Progress in aerospace sciences, 38, pp. 389-420, (2002)
  • [6] BALDACCHINO D, FERREIRA C, TAVERNIER D D, Et al., Experimental parameter study for passive vortex generators on a 30% thick airfoil, Wind energy, 21, 9, pp. 745-765, (2018)
  • [7] ZHANG L, YANG K, XU J Z., Effects on wind turbine airfoils by vortex generators, Journal of engineering thermophysics, 31, 5, pp. 749-752, (2010)
  • [8] WANG Y, GUO P C, LI C, Et al., Influence of vortex generator on aerodynamic characteristics of wind turbine wing, Energy saving technology, 37, 4, pp. 296-302, (2019)
  • [9] ZHU C Y, WANG T G, WU J H., Numerical investigation of passive vortex generators on a wind turbine airfoil undergoing pitch oscillations, Energies, 12, 4, pp. 1-19, (2019)
  • [10] ZHAO Z Z, SU D C, WANG T G, Et al., Simulation study on the effect of vortex generators on dynamic stall, Journal of mechanical engineering, 55, 24, pp. 203-209, (2019)
12