Parallelization of a stochastic Euler-Lagrange model applied to large scale dense bubbly flows

Journal of Computational Physics: X Pub Date : 2020-09-01 DOI:10.1016/j.jcpx.2020.100058

S. Kamath , M.V. Masterov , J.T. Padding , K.A. Buist , M.W. Baltussen , J.A.M. Kuipers

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引用次数: 7

Abstract

A parallel and scalable stochastic Direct Simulation Monte Carlo (DSMC) method applied to large-scale dense bubbly flows is reported in this paper. The DSMC method is applied to speed up the bubble-bubble collision handling relative to the Discrete Bubble Model proposed by Darmana et al. (2006) [1]. The DSMC algorithm has been modified and extended to account for bubble-bubble interactions arising due to uncorrelated and correlated bubble velocities. The algorithm is fully coupled with an in-house CFD code and parallelized using the MPI framework. The model is verified and validated on multiple cores with different test cases, ranging from impinging particle streams to laboratory-scale bubble columns. The parallel performance is shown using two different large scale systems: with an uniform and a non-uniform distribution of bubbles. The hydrodynamics of a pilot-scale bubble column is analyzed and the effect of the column scale is reported via the comparison of bubble columns at three different scales.

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应用于大尺度稠密泡状流的随机欧拉-拉格朗日模型的并行化

本文提出了一种适用于大规模稠密泡状流的并行可扩展随机直接模拟蒙特卡罗（DSMC）方法。相对于Darmana等人提出的离散气泡模型，DSMC方法用于加快气泡-气泡碰撞处理。（2006）[1]。对DSMC算法进行了修改和扩展，以考虑由于不相关和相关的气泡速度引起的气泡-气泡相互作用。该算法与内部CFD代码完全耦合，并使用MPI框架进行并行化。该模型在多个具有不同测试案例的岩心上进行了验证和验证，测试案例包括撞击颗粒流和实验室规模的气泡柱。使用两种不同的大规模系统显示了并行性能：均匀和非均匀分布的气泡。分析了中试规模鼓泡塔的流体动力学，并通过对三种不同规模的鼓泡塔进行比较，报道了鼓泡塔规模的影响。

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