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倾斜界面角度对可压缩瑞利-泰勒不稳定性的影响:基于离散玻尔兹曼方法的数值研究

Effects of Inclined Interface Angle on Compressible Rayleigh-Taylor Instability: A Numerical Study Based on the Discrete Boltzmann Method.

作者信息

Chen Bailing, Lai Huilin, Lin Chuandong, Li Demei

机构信息

School of Mathematics and Statistics, Key Laboratory of Analytical Mathematics and Applications (Ministry of Education), Fujian Key Laboratory of Analytical Mathematics and Applications (FJKLAMA), Center for Applied Mathematics of Fujian Province (FJNU), Fujian Normal University, Fuzhou 350117, China.

Sino-French Institute of Nuclear Engineering and Technology, Sun Yat-sen University, Zhuhai 519082, China.

出版信息

Entropy (Basel). 2023 Dec 5;25(12):1623. doi: 10.3390/e25121623.

DOI:10.3390/e25121623
PMID:38136503
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10742810/
Abstract

Rayleigh-Taylor (RT) instability is a basic fluid interface instability that widely exists in nature and in the engineering field. To investigate the impact of the initial inclined interface on compressible RT instability, the two-component discrete Boltzmann method is employed. Both the thermodynamic non-equilibrium (TNE) and hydrodynamic non-equilibrium (HNE) effects are studied. It can be found that the global average density gradient in the horizontal direction, the non-organized energy fluxes, the global average non-equilibrium intensity and the proportion of the non-equilibrium region first increase and then reduce with time. However, the global average density gradient in the vertical direction and the non-organized moment fluxes first descend, then rise, and finally descend. Furthermore, the global average density gradient, the typical TNE intensity and the proportion of non-equilibrium region increase with increasing angle of the initial inclined interface. Physically, there are three competitive mechanisms: (1) As the perturbed interface elongates, the contact area between the two fluids expands, which results in an increasing gradient of macroscopic physical quantities and leads to a strengthening of the TNE effects. (2) Under the influence of viscosity, the perturbation pressure waves on both sides of the material interface decrease with time, which makes the gradient of the macroscopic physical quantity decrease, resulting in a weakening of the TNE strength. (3) Due to dissipation and/or mutual penetration of the two fluids, the gradient of macroscopic physical quantities gradually diminishes, resulting in a decrease in the intensity of the TNE.

摘要

瑞利 - 泰勒(RT)不稳定性是一种基本的流体界面不稳定性,广泛存在于自然界和工程领域。为了研究初始倾斜界面可压缩RT不稳定性的影响,采用了双组分离散玻尔兹曼方法。对热力学非平衡(TNE)和流体动力学非平衡(HNE)效应都进行了研究。可以发现,水平方向的全局平均密度梯度、无组织能量通量、全局平均非平衡强度和非平衡区域的比例随时间先增加后减小。然而,垂直方向的全局平均密度梯度和无组织矩通量先下降,然后上升,最后下降。此外,全局平均密度梯度、典型TNE强度和非平衡区域的比例随着初始倾斜界面角度的增加而增加。从物理角度来看,存在三种竞争机制:(1)随着扰动界面伸长,两种流体之间的接触面积扩大,这导致宏观物理量的梯度增加,并导致TNE效应增强。(2)在粘性影响下,材料界面两侧的扰动压力波随时间减小,这使得宏观物理量的梯度减小,导致TNE强度减弱。(3)由于两种流体的耗散和/或相互渗透,宏观物理量的梯度逐渐减小,导致TNE强度降低。

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本文引用的文献

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Discrete Boltzmann modeling of Rayleigh-Taylor instability: Effects of interfacial tension, viscosity, and heat conductivity.瑞利-泰勒不稳定性的离散玻尔兹曼建模:界面张力、粘度和热导率的影响。
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