Computational Study of Mach Number Effects on Dynamic Stall

Volume 1: Fluid Mechanics Pub Date : 2019-07-28 DOI:10.1115/ajkfluids2019-5336

Taesoon Kim, Seungtae Kim, Jiseop Lim, Junkyu Kim, S. Jee

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引用次数: 3

Abstract

A rotorcraft main-rotor blade experiences a broad range of the Mach number in high-speed forward flights or rapid maneuvering conditions. Near the boundary of the flight envelope, the rotor blade often encounters severe dynamic stall which limits the overall aerodynamic performance. Of interest here is effects of the Mach number on the dynamic stall. A rotor airfoil, VR-12, is computationally investigated for both static and dynamic stall conditions with varying the Mach number from 0.2 to 0.4. For the small enough Mach number 0.2, both static and dynamic stall are significantly influenced by flow separation due to adverse pressure gradient. For the highest Mach number 0.4, compressibility near the leading edge is no longer negligible, forming a shock there. The shock-induced separation occurs near the leading edge, which dominates both the static and dynamic stall at the high Mach number. At the intermediate Mach number 0.3, it is observed that both adverse pressure gradient and the shock affect the stall. Current computations are conducted with the unsteady Reynolds-averaged Navier Stokes approach with the Spalart-Allmaras model. Numerical results are compared to relevant wind-tunnel test data.

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马赫数对动态失速影响的计算研究

在高速前飞或快速机动条件下，旋翼机主旋翼叶片的马赫数变化范围较大。在飞行包线边界附近，旋翼叶片经常遇到严重的动态失速，这限制了整体气动性能。这里有趣的是马赫数对动态失速的影响。一个转子翼型，VR-12，计算研究了静态和动态失速条件下变化的马赫数从0.2到0.4。在马赫数足够小的0.2条件下，由于逆压梯度导致的流动分离对静、动失速都有显著影响。在最高马赫数0.4时，前缘附近的可压缩性不再可以忽略不计，在那里形成激波。激波分离主要发生在前缘附近，在高马赫数时，激波分离对静失速和动失速都起主导作用。在中间马赫数0.3时，观察到逆压梯度和激波对失速都有影响。目前的计算采用非定常reynolds -average Navier Stokes方法和Spalart-Allmaras模型进行。数值结果与相关风洞试验数据进行了比较。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Volume 1: Fluid Mechanics

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