混合层的不稳定性:连续介质击穿中的动量和热输运

Vishnu Mohan, A. Sameen, Balaji Srinivasan, Sharath S. Girimaji
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引用次数: 0

摘要

我们研究了在理想连续介质条件下表现出开尔文-亥姆霍兹不稳定性的混合层流连续介质击穿状态下的动量和热输运。使用Grad 13力矩模型,因为它提供了过渡状态下流动物理的充分描述(Knudsen数的二阶精确)。给出了二维可压缩平行剪切流在击穿条件下的解析解。结果表明,黏性应力和热通量对纳维-斯托克斯-傅立叶系统的偏离随马赫数的变化遵循两种不同的标度形式。在低马赫数时,所有应力和热流分量的偏离仅取决于克努森数。在高马赫数下,剪切应力和横向热流的标度取决于努森数和马赫数的乘积。正应力分别取决于克努森数和马赫数。用统一的气体动力学格式对不同稀薄度的可压缩混合层进行数值模拟,验证了标度结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Instability of mixing layers: Momentum and thermal transport in the continuum breakdown regime
We examine the momentum and thermal transport in the continuum breakdown regime of a mixing layer flow, which exhibits Kelvin-Helmholtz instability under ideal continuum conditions. The Grad 13 moment model is used as it provides an adequate description of the flow physics (second-order accurate in Knudsen number) in the transition regime. Analytical solutions are developed under breakdown conditions for two-dimensional, compressible, parallel shear flows. It is shown that the deviation of viscous stress and heat flux from the Navier-Stokes-Fourier system follows two different scaling regimes depending upon the Mach number. At low Mach numbers, the departure of all stress and heat-flux components depends only upon the Knudsen number. At high Mach number, the scaling of shear stress and transverse heat flux depends on the product of the Knudsen and Mach numbers. The normal stresses depend individually on the Knudsen and Mach number. The scaling results are verified against numerical simulations of compressible mixing layers performed using the unified gas kinetic scheme for various degrees of rarefaction.
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