采用边界元法研究磁场对多孔波浪形水道粘性流的影响

Vishal Chhabra, Chandra Shekhar Nishad, Manoj Sahni
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摘要

本研究旨在探讨在低雷诺数条件下,均匀倾斜磁场对稳定的粘性不可压缩流体通过多孔波浪形通道的二维流动的影响。我们考虑了一个具有正弦曲线壁面、充满完全饱和多孔介质的通道。假定多孔介质是均质和各向同性的。流经多孔介质的粘性流动受布林克曼方程控制,其中粘性力占主导地位。这样,我们就可以在波浪形通道壁上假设无滑动边界条件。我们采用基于非原始变量(即流函数-涡度变量)的边界元法(BEM)来求解布林克曼方程。此外,我们还考虑了非常小的磁雷诺数,以消除磁诱导方程。我们分析了哈特曼数、孔隙率的增加以及磁场倾角、波幅和达西数的减小会导致水平速度的减小,而哈特曼数、孔隙率、波幅的增加以及达西数和磁场倾角的减小会导致垂直速度的增加。此外,在高波幅和低哈特曼数条件下,多孔波浪形水道的波峰附近会出现流动逆转现象。所提出的研究具有广泛的应用前景,如用于精确靶向药物的药物输送系统、用于调节人工心脏血流以降低血液凝结风险的磁流体泵等。
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Effect of magnetic field on viscous flow through porous wavy channel using boundary element method
The study aims to investigate the effect of uniform inclined magnetic field on two‐dimensional flow of a steady, viscous incompressible fluid at low Reynolds number through a porous wavy channel. We consider a channel having sinusoidal walls filled with a fully saturated porous medium. The porous regime is assumed to be homogenous and isotropic. The viscous flow through a porous regime is governed by Brinkman equation, where the viscous forces are dominant. This allows us to assume the no‐slip boundary conditions at the walls of the wavy channel. Boundary element method (BEM) based on non‐primitive variables namely, stream function‐vorticity variables is used to solve the Brinkman equation. Further, we consider a very small magnetic Reynolds number to eliminate the magnetic‐induced equation. We analyzed that an increase in Hartman number, porosity, and reduction in inclination angle of magnetic field, wave amplitude, and Darcy number led to a reduction in horizontal velocity, whereas an increase in Hartman number, porosity, wave amplitude, and decrease in Darcy number and angle of inclination of magnetic field led to an increase in vertical velocity. Moreover, the flow reversal phenomena occur in the vicinity of the crest regime of the porous wavy channel for high wave amplitude and low Hartman number. The proposed investigation has widespread applications, such as drug delivery systems to target the drug precisely, magneto‐hydrodynamic pumps to regulate the blood flow in artificial hearts to reduce the risk of blood clotting, and so forth.
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