多孔介质中孔隙尺度的颗粒传输。第 1 部分：非解析-解析四向耦合 CFD-DEM

IF 3.8 2区物理与天体物理 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

Journal of Computational Physics Pub Date : 2024-10-29 DOI:10.1016/j.jcp.2024.113540

Laurez Maya Fogouang , Laurent André , Cyprien Soulaine

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引用次数: 0

摘要

计算流体动力学--离散元法（CFD-DEM）是一种强大的方法，可在孔隙尺度上模拟颗粒在多孔介质中的流动，从而破解颗粒传输和滞留之间复杂的相互作用。文献中通常使用两种不同的 CFD-DEM 方法：非解析法（颗粒小于网格单元尺寸）和解析法（颗粒大于网格单元尺寸）。在本文中，我们提出了一种新颖的 CFD-DEM 耦合方法，它结合了非解析耦合和解析耦合两种方法。我们的新建模技术可以模拟多孔材料特有的复杂孔隙形态中的颗粒流动。它依靠高效的搜索策略来寻找颗粒覆盖的网格单元，并对流固动量交换项进行适当计算。计算模型的稳健性和高效性通过已有参考解（分析或实验解）的案例得以证明。新的非解析-解析四向耦合 CFD-DEM 被用于研究颗粒的筛分和架桥导致的孔隙堵塞和渗透率降低。

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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Particulate transport in porous media at pore-scale. Part 1: Unresolved-resolved four-way coupling CFD-DEM

Computational Fluid Dynamics - Discrete Element Method (CFD-DEM) is a powerful approach to simulate particulate flow in porous media at the pore-scale, and hence decipher the complex interplay between particle transport and retention. Two separate CFD-DEM approaches are commonly used in the literature: the unresolved (particle smaller than the grid cell size) and the resolved (particle bigger than the grid cell size) approach. In this paper, we propose a novel CFD-DEM coupling approach that combines both unresolved and resolved coupling. Our new modeling technique allows for the simulation of particulate flows in complex pore morphology characteristic of porous materials. It relies on an efficient searching strategy to find grid cells covered by the particles and on an appropriate calculation of the fluid-solid momentum exchange term. The robustness and efficiency of the computational model are demonstrated using cases for which reference solutions – analytical or experimental – exist. The new unresolved-resolved four-way coupling CFD-DEM is used to investigate pore-clogging and permeability reduction due to the sieving and bridging of particles.

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来源期刊

Journal of Computational Physics 物理-计算机：跨学科应用

CiteScore

7.60

自引率

14.60%

发文量

763

审稿时长

5.8 months

期刊介绍： Journal of Computational Physics thoroughly treats the computational aspects of physical problems, presenting techniques for the numerical solution of mathematical equations arising in all areas of physics. The journal seeks to emphasize methods that cross disciplinary boundaries. The Journal of Computational Physics also publishes short notes of 4 pages or less (including figures, tables, and references but excluding title pages). Letters to the Editor commenting on articles already published in this Journal will also be considered. Neither notes nor letters should have an abstract.