Modeling and simulation of a single-mode multiphase Richtmyer–Meshkov instability with a large Stokes number

Meng, Baoqing; Zeng, Jiang; Tian, Buning; Zhou, Rui; Shen, Weidong

doi:10.1063/1.5129143

Cited by 7 publications

(2 citation statements)

References 33 publications

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“…我们使用基于欧拉-拉格朗日框架的 CMP-PIC 方法来模拟多相流 [23,24] ，该方法可以模拟从稀疏到稠密以及颗粒流的全流态流动。采用 Runge-Kutta 方法进行时间推进，使用 TVD 格式 [26] 来重构原始流动变量，应用 Harten 等人 [27] 提出的黎曼求解器来求解通量。将具有相似物理性质的颗粒打包为颗粒包，并使用软球模型计算颗粒之间的碰撞，方便相间耦合的计算，显著降低大规模颗粒群模拟所需的计算量。 CMP-PIC 方法广泛应用于激波-颗粒群作用和多相 RMI 等问题模拟中，取得良好的应用效果，该方法的验证可参考已发表论文 [16,17,23,28,29] [13,16,23] 的研究，在每个网格单元布置四个颗粒包，可保证网格内颗粒包分辨率的收敛。表 1 四种网格分辨率的详细信息 [16][17][18]22] 。界面的位置定义为空气体积分数 1 0.5…”

Section: 数值方法和网格无关性验证unclassified

“…St 数气体-颗粒流的研究工作，通过理论推导和数值验证，给出了混合区域宽度线性段的增长模型 [13][14][15][16] 。 1961 年，Saffman 等人 [14] 建立了稀疏气体-颗粒的控制方程，来描述携带小尘埃颗粒的气体运动。2010 年，Ukai 等人 [13] 对控制方程进行小扰动分析，推导了小 St 数的稀疏气体-颗粒流的混合区域宽度增长率的线性理论解，给出了多相 RMI 系统的 Atwood 数 m A ，用于描述多相流中界面两侧流体的等效密度差异。其中，等效密度是气体和颗粒根据体积分数加权计算得到的混合物密度。此后，众多学者将该模型推广到了非线性阶段和稠密流动的情况 [16][17][18] ，这些都反映了气粒耦合的影响。与纯气相的 RMI 问题不同 [19][20][21] ，颗粒参数对混合区域宽度演化有显著影响，流动系统的复杂性也高于经典 RMI，相应的理论模型及演化机理尚不成熟。因此，已有研究中也常采用数值模拟的手段对颗粒影响开展研究。根据 St 数的定义可知，颗粒的 St 数和其弛豫时间密切相关。数值模拟研究表明，颗粒的弛豫时间对流体的动力学行为具有显著影响。Ukai 等人对大 St 数的稀疏气体-颗粒流开展了数值模拟 [13] ，发现大尺寸颗粒并不会跟随流体运动，混合区域宽度增长速率与颗粒无关，与纯气相的增长模型相一致。 McFarland 等人对颗粒弛豫时间的影响规律也开展了详细的数值模拟研究 [22] 。他们通过改变颗粒半径来控制弛豫时间，结果表明，较大颗粒在向下游传播的过程中会使整个界面减速，导致混合区域宽度显著衰减。这一滞后效应抑制了涡的发展，使得不同颗粒半径的多相 RMI 中在界面处产生的涡不同。他们还指出， F o r R e v i e w O n l y 对于小弛豫时间下，Ukai 等人 [13] [23,24] [13,16]…”

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颗粒密度与半径影响下的多相rmi混合区域宽度极限理论模型及其规律探究

Si,

Meng,

Wang

et al. 2024

Sci. Sin.-Phys. Mech. Astron.

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Particle parameters have a significant impact on the evolution of the mixing zone width of the multiphase Richtmyer Meshkov instability (RMI), but the influence law remains to be explored. Based on the interface motion equation and integrating the influence of particle volume fraction, radius and gas viscosity parameters, this article proposes a dimensionless number Sd to characterize the effect of drag on the fluid velocity relaxation process. A growth model for the mixing zone width under extreme particle parameters is established based on the small-perturbation theory. The analysis showed that the combination of particle density and particle size determines the growth pattern of the mixing zone width. It shows exponential growth when the particle density is large, and linear growth when the radius is large or both are large. Further analysis revealed the influence of changes in particle parameters on the mixing zone width, and found that increasing the particle radius will promote the growth of the mixing zone width. The numerical simulation results verify the validity of the theoretical model and Sd number. The results indicate that the classical Stokes number (St) fails in predicting the growth of the mixing zone width, and the combination of St number and Sd number is the dominant dimensionless number for the evolution of multiphase RMI.

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Section: 数值方法和网格无关性验证unclassified

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颗粒密度与半径影响下的多相rmi混合区域宽度极限理论模型及其规律探究

Si,

Meng,

Wang

et al. 2024

Sci. Sin.-Phys. Mech. Astron.

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Numerical method for compressible gas-particle flow coupling using adaptive parcel refinement (APR) method on non-uniform mesh

Meng

Zeng

Chen

et al. 2022

Journal of Computational Physics

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Late-time turbulent mixing induced by multimode Richtmyer–Meshkov instability in cylindrical geometry

Zhang

et al. 2020

Physics of Fluids

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Turbulent mixing induced by Richtmyer–Meshkov instability (RMI) in convergent geometry widely exists in natural phenomena and in engineering applications. In the present work, high-resolution numerical simulations of RMI at a complete cylindrical interface, with the imploding shock wave initially passing from the heavy fluid to the light fluid, are presented. Two different initial perturbations are applied. The mixing zone finally reaches a convergence ratio Cr ≈ 1.6 in both cases. Compared to classical RM instability, the more complex wave system, as well as the geometrical effect induced by the radial movement of mixing fluid, modifies the evolution of the mixing zone. The growth rate of the mixing width is analyzed in terms of the stretching or compression effect and species-penetration effect. In a cylindrical geometry, the stretching or compression effect is mainly induced by the wave system and the nonplanar geometric environment. The late-time turbulent mixing width induced by the penetration effect scales as (t−t0)θ, as with the evolution of planar RMI. For both cases, the mass-fraction profiles are collapsed at the late time if the radial coordinate is first shifted with the spike-front position and then scaled by the mixing width. By analyzing the distribution of the bubble (spike) contour, the dominant bubble (spike) diameter [D¯b(s)] is obtained. The ratios [βb(s)] between the dominant bubble (spike) diameter and the bubble (spike) amplitude [Wb(s)] are calculated, and a stable ratio of spike βs is observed during the late stage. Meanwhile, the ratio of the bubble βb is greater than 1 at late time.

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Modeling and simulation of a single-mode multiphase Richtmyer–Meshkov instability with a large Stokes number

Cited by 7 publications

References 33 publications

颗粒密度与半径影响下的多相rmi混合区域宽度极限理论模型及其规律探究

颗粒密度与半径影响下的多相rmi混合区域宽度极限理论模型及其规律探究

Numerical method for compressible gas-particle flow coupling using adaptive parcel refinement (APR) method on non-uniform mesh

Late-time turbulent mixing induced by multimode Richtmyer–Meshkov instability in cylindrical geometry

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