微极流体通过多孔拉伸/收缩片与质量蒸腾:一种分析方法

Q3 Engineering

WSEAS Transactions on Fluid Mechanics Pub Date : 2023-07-19 DOI:10.37394/232013.2023.18.3

Rishu Garg, Jitender Singh, U. S. Mahabaleshwar, Okhunjon Sayfidinov, G. Bognár

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引用次数: 0

摘要

本文研究了磁流体力学条件下微极流体在拉伸或收缩薄片上的流动。这种流动用高度非线性偏微分方程来描述。利用相似变换技术，将控制流体流动的偏微分方程简化为非线性偏微分方程系统，从而进一步得到封闭形式的解析解。讨论了在各种无量纲参数组合下，微旋转对表面摩擦系数的影响、速度的无量纲形式以及拉伸或收缩片附近的温度流场。数值结果表明，微极流的加速或减速取决于质量蒸腾的数值和多孔板的渗透率。随着微旋度的增加，切向流速和角流速也会增加。此外，还观察到微旋转的增加增加了表面摩擦系数。

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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Micropolar Fluid Flow Through a Porous Stretching/Shrinking Sheet with Mass Transpiration: An Analytical Approach

In this paper, the flow of a micropolar fluid over a stretching or shrinking sheet is investigated under magnetohydrodynamic (MHD) conditions. Such a flow is described by highly nonlinear PDEs. Using the similarity transformation technique, the PDEs governing the flow are reduced to a system of nonlinear ODEs, which further allows a closed-form analytical solution. The effect of the microrotation on the skin friction coefficient, the dimensionless forms of the velocity, and the temperature flow fields in the neighborhood of the stretching or shrinking sheet are discussed for various combinations of the dimensionless parameters. The numerical results reveal that the micropolar flow may accelerate or deaccelerate depending upon the numerical values of the mass transpiration and the permeability of the porous sheet. An increase in the tangential and the angular flow velocities is found to occur with an increase in the microrotation. Further, it is observed that the increase in the microrotation increases the skin friction coefficient.

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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.