Numerical Investigation of the Two-Component Suspension Filtration in a Porous Medium Taking into Account Changes in the Characteristics of the Porous Medium

Q3 Engineering WSEAS Transactions on Fluid Mechanics Pub Date : 2023-12-22 DOI:10.37394/232013.2023.18.20

B. Fayziev, Jamol Makhmudov, Jabbor Mustofoqulov, T. Begmatov, Rakhmon Safarov

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Abstract

The paper explores a mathematical model of the filtration of dual-component suspension within a porous medium characterized by two distinct zones. This model encompasses mass balance equations of suspended particles, kinetic equations of deposition formation for both reversible and irreversible deposition types for each suspension component, and incorporates Darcy’s law. In order to solve the problem, we formulate a numerical algorithm for computer-based experimentation on the basis of the finite difference method. Through the analysis of numerical findings, we establish key features of two component suspension filtration within a porous medium. Furthermore, we examine the effects of model parameters on the transport and deposition of suspended particles in a two-component suspension within porous media. The polydispersity of the suspension and the multi-stage nature of deposition kinetics can induce effects that differ from those typically observed in the transport of onecomponent suspensions with single-stage particle deposition kinetics.

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考虑到多孔介质特性变化的多孔介质双组分悬浮过滤数值研究

本文探讨了双组分悬浮液在多孔介质中过滤的数学模型，多孔介质的特点是有两个不同的区域。该模型包括悬浮颗粒的质量平衡方程、每种悬浮成分的可逆和不可逆沉积类型的沉积形成动力学方程，并结合了达西定律。为了解决这个问题，我们在有限差分法的基础上制定了一种基于计算机实验的数值算法。通过对数值结果的分析，我们确定了多孔介质中双组分悬浮过滤的主要特征。此外，我们还研究了模型参数对多孔介质中双组分悬浮液中悬浮颗粒的传输和沉积的影响。悬浮液的多分散性和沉积动力学的多阶段性会产生不同于单组分悬浮液单阶段颗粒沉积动力学的典型传输效果。

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来源期刊

WSEAS Transactions on Fluid Mechanics Engineering-Computational Mechanics

CiteScore

1.50

自引率

0.00%

发文量

期刊介绍： WSEAS Transactions on Fluid Mechanics publishes original research papers relating to the studying of fluids. We aim to bring important work to a wide international audience and therefore only publish papers of exceptional scientific value that advance our understanding of this particular area. The research presented must transcend the limits of case studies, while both experimental and theoretical studies are accepted. It is a multi-disciplinary journal and therefore its content mirrors the diverse interests and approaches of scholars involved with multiphase flow, boundary layer flow, material properties, wave modelling and related areas. We also welcome scholarly contributions from officials with government agencies, international agencies, and non-governmental organizations.