槽分布对超声速湍流通道流动的影响

IF 1.5 4区工程技术 Q3 MECHANICS

Journal of Turbulence Pub Date : 2023-06-12 DOI:10.1080/14685248.2023.2224019

YaLu Fu, Qingqing Zhou, M. Yu, H. Su, Qilong Guo, Xianxu Yuan

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引用次数: 0

摘要

本文通过直接数值模拟研究了壁面凹槽的分布对体积马赫数为3.0的超音速湍流通道流中湍流统计、湍流动能传输和流动结构的影响。研究发现，沟槽的存在导致靠近壁的湍流动能增强，并在缓冲层上方减少湍流动能。密度和温度波动也被增强，但仅在缓冲层内，在缓冲层之上可以忽略凹槽的影响。然而，压力波动显著增加，这归因于墙壁上的扰动产生的来自墙壁的辐射声波。相平均压力的倾角与马赫数有关，这一事实证实了这种推断。然而，声学和动力学过程似乎是解耦的，导致湍流动能传输中的压力膨胀项微不足道。

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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Effects of groove distributions on supersonic turbulent channel flows

This paper investigates the influences of the distribution of the grooves on the wall on the turbulent statistics, transport of turbulent kinetic energy, and flow structures in supersonic turbulent channel flows at the bulk Mach number of 3.0 by performing direct numerical simulations. It is found that the existence of the grooves leads to the enhancement of the turbulent kinetic energy close to the wall and the abatement thereof above the buffer layer. The density and temperature fluctuations are also enhanced, but only within the buffer layer, above which the influences of the grooves can be disregarded. The pressure fluctuations, however, are significantly increased, which is attributed to the radiated acoustic waves from the wall generated by the disturbances on the wall. Such inference is substantiated by the fact that the inclination angles of the phase averaged pressure are related to the Mach number. Nevertheless, the acoustic and dynamic processes seem to be decoupled, leading to insignificant pressure-dilatation terms in the transport of turbulent kinetic energy.

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来源期刊

Journal of Turbulence 物理-力学

CiteScore

3.90

自引率

5.30%

发文量

审稿时长

6-12 weeks

期刊介绍： Turbulence is a physical phenomenon occurring in most fluid flows, and is a major research topic at the cutting edge of science and technology. Journal of Turbulence ( JoT) is a digital forum for disseminating new theoretical, numerical and experimental knowledge aimed at understanding, predicting and controlling fluid turbulence. JoT provides a common venue for communicating advances of fundamental and applied character across the many disciplines in which turbulence plays a vital role. Examples include turbulence arising in engineering fluid dynamics (aerodynamics and hydrodynamics, particulate and multi-phase flows, acoustics, hydraulics, combustion, aeroelasticity, transitional flows, turbo-machinery, heat transfer), geophysical fluid dynamics (environmental flows, oceanography, meteorology), in physics (magnetohydrodynamics and fusion, astrophysics, cryogenic and quantum fluids), and mathematics (turbulence from PDE’s, model systems). The multimedia capabilities offered by this electronic journal (including free colour images and video movies), provide a unique opportunity for disseminating turbulence research in visually impressive ways.