Journal of Propulsion Technology ›› 2013, Vol. 34 ›› Issue (10): 1321-1329.

• Ship Propulsion • Previous Articles     Next Articles

Numerical Investigation and Topological Analysis of Plasma Flow Control on a Highly Loaded Compressor Cascade

  

  1. Engineering College, Science and Technology on Plasma Dynamics Laboratory, Xi’an 710038,China;Engineering College, Science and Technology on Plasma Dynamics Laboratory, Xi’an 710038,China;The Fourth Flight College of the Air Force, The Chinese People’s Liberation Army, Shijiazhuang 050000,China
  • Published:2021-08-15

高负荷压气机叶栅等离子体流动控制数值仿真与拓扑分析

王学德1,赵小虎1,王路成2   

  1. 空军工程大学 等离子体动力学重点实验室,陕西 西安 710038;空军工程大学 等离子体动力学重点实验室,陕西 西安 710038;中国人民解放军 空军第四飞行学院,河北 石家庄 050000
  • 作者简介:王学德(1966—),男,硕士,副教授,研究领域为等离子体流动控制。E-mail:wxd1966@126.com
  • 基金资助:
    国家自然科学基金(50906100,10972236)。

Abstract: In order to find the influence law and mechanism of plasma flow control, flow structure and topology structure of highly loaded compressor cascade with and without plasma aerodynamic actuation (PAA) were studied. Results show that the area, where PAA prevents flow separation most effectively, is located at the verge of triangular region with high total pressure loss and main flow. The solid surface topology structure and distribution of singular points are changed with different PAA layouts, but the number relation between saddle and node points keeps constant. The streamwise PAA on the suction surface can mainly change the flow characteristic at midspan, but has weak impact on corner separation. The pitchwise PAA on the endwall can reduce the accumulation of low-energy fluids at the suction surface and endwall corner by inhibiting the cross flow, and then change the blade loading distribution in spanwise direction. The control effect of streamwise PAA on the suction surface combined with pitchwise PAA on the endwall is among the best. 

Key words: Plasma aerodynamic actuation; Compressor; Cascade; Topology structure; Corner

摘要: 为揭示叶栅等离子体流动控制的影响规律与作用机理,对等离子体气动激励前后高负荷压气机叶栅内部流动和拓扑结构进行了对比研究。结果表明:等离子体气动激励抑制叶栅流动分离的作用效果最明显的区域位于总压损失区域与主流区域的边界上;不同等离子体气动激励布局,对固壁面拓扑结构以及奇点总数的影响规律不同;吸力面流向激励通过增强附面层流体抵抗逆压梯度的能力,可以改善叶栅中间叶高流动特性;端壁横向激励通过抑制横向流动,抑制角区流动分离能力较强,并改变叶片展向的负荷分布;组合激励结合了吸力面流向激励和端壁横向激励的作用优势,因而提高叶栅气动性能、降低流动损失的效果最好。 

关键词: 等离子体气动激励;压气机;叶栅;拓扑结构;角区 