模拟分散颗粒流动的动力学理论的发展与应用

IF 1.8 3区 工程技术 Q3 ENGINEERING, MECHANICAL
M. Reeks
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引用次数: 5

摘要

这篇弗里曼学者的文章回顾了动力学理论的公式和应用,用于模拟湍流气体流动中小颗粒的输运和分散。该理论经过许多作者的发展和完善,现在形成了模拟复杂颗粒流的合理基础。讨论了该方法的形式和方法,所涉及的动力学方程的闭合选择保证了高斯载流场的精确闭合的可实现性和完备性。介绍了历史发展以及单粒子动力学方程如何解决关于粒子质量、动量和动能/应力的输运方程(所谓的连续统方程)的闭合问题以及将分散相作为流体处理的问题。与湍流气动驱动力和界面应力相关的质量通量在非均匀湍流中既具有弥散性又具有对流性,这意味着近壁湍流边界层中颗粒浓度的积累和小分离时颗粒对浓度的增加。说明了这种方法如何处理流动粒子悬浮液的自然壁边界条件,并给出了粒子散射和重力沉降的部分吸收表面的例子;这种方法如何揭示了发展中的剪切流中存在对梯度扩散以及湍流对重力沉降的影响(Maxey效应)。特别考虑了紊流边界层中粒子输运和沉积的一般问题,包括粒子再悬浮。最后,回顾了单分散和双分散粒子流的粒子对公式的应用,并通过碰撞对粒子连续方程组的影响和粒子聚类的粒子碰撞核以及湍流小尺度下随机不相关运动(RUM)的程度来比较两者之间的差异。双分散颗粒悬浮液的包含意味着应用于多分散流动和颗粒尺寸分布的演变。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The Development and Application of a Kinetic Theory for Modeling Dispersed Particle Flows
This Freeman Scholar article reviews the formulation and application of a kinetic theory for modeling the transport and dispersion of small particles in turbulent gas-flows. The theory has been developed and refined by numerous authors and now forms a rational basis for modeling complex particle laden flows. The formalism and methodology of this approach are discussed and the choice of closure of the kinetic equations involved ensures realizability and well posedness with exact closure for Gaussian carrier flow fields. The historical development is presented and how single-particle kinetic equations resolve the problem of closure of the transport equations for particle mass, momentum, and kinetic energy/stress (the so-called continuum equations) and the treatment of the dispersed phase as a fluid. The mass fluxes associated with the turbulent aerodynamic driving forces and interfacial stresses are shown to be both dispersive and convective in inhomogeneous turbulence with implications for the build-up of particles concentration in near wall turbulent boundary layers and particle pair concentration at small separation. It is shown how this approach deals with the natural wall boundary conditions for a flowing particle suspension and examples are given of partially absorbing surfaces with particle scattering and gravitational settling; how this approach has revealed the existence of contra gradient diffusion in a developing shear flow and the influence of the turbulence on gravitational settling (the Maxey effect). Particular consideration is given to the general problem of particle transport and deposition in turbulent boundary layers including particle resuspension. Finally, the application of a particle pair formulation for both monodisperse and bidisperse particle flows is reviewed where the differences between the two are compared through the influence of collisions on the particle continuum equations and the particle collision kernel for the clustering of particles and the degree of random uncorrelated motion (RUM) at the small scales of the turbulence. The inclusion of bidisperse particle suspensions implies the application to polydisperse flows and the evolution of particle size distribution.
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来源期刊
CiteScore
4.60
自引率
10.00%
发文量
165
审稿时长
5.0 months
期刊介绍: Multiphase flows; Pumps; Aerodynamics; Boundary layers; Bubbly flows; Cavitation; Compressible flows; Convective heat/mass transfer as it is affected by fluid flow; Duct and pipe flows; Free shear layers; Flows in biological systems; Fluid-structure interaction; Fluid transients and wave motion; Jets; Naval hydrodynamics; Sprays; Stability and transition; Turbulence wakes microfluidics and other fundamental/applied fluid mechanical phenomena and processes
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