MHD Slip Flow and Heat Transfer with Ohmic Heating between a Rotating Solid Disk and Stationary Permeable Disk

Journal of Electrical and Computer Engineering Innovations Pub Date : 2022-09-01 DOI:10.4028/p-d6t7o5

S. Gunakala, V. Job, Maraika Alexander

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Abstract

In this paper, the axially-symmetric MHD (magnetohydrodynamic) slip fluid flow and heat transfer between a rotating disk and a stationary permeable disk has been examined. The physical system is comprised of a free-fluid region with an underlying fluid-saturated porous bed with a solid base. The fluid flow within the free-fluid region is modeled using the Navier-Stokes equation, whereas the flow within the porous bed is described using the Brinkman equation. The governing equations of fluid flow and heat transfer, along with the associated boundary conditions, are reduced to a system of ordinary differential equations using suitable similarity transformations. A series expansion technique is then employed in order to obtain analytical approximations for the velocity and temperature distributions. The results produced in this study are presented in graphical form. Unless otherwise stated, the following non-dimensional values are used for the numerical calculations: Hartmann number M=1, Reynolds number R=0.1, Darcy parameter beta=0.05, thermal conductivity ratio lambda=0.5, Eckert number Ec=10, slip parameter N^*=0.05, eta=1, and Prandtl numbers Pr_1=Pr_2=10. The influence of the Darcy parameter, Hartmann number and thermal conductivity ratio on the flow velocity and fluid temperature are investigated.

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旋转实心圆盘和静止可渗透圆盘之间的滑动流动和欧姆加热传热

本文研究了轴对称磁流体滑移流体在旋转圆盘和静止可渗透圆盘之间的流动和传热问题。该物理系统由一个自由流体区域组成，该区域具有具有固体基础的下伏流体饱和多孔床。自由流体区域内的流体流动使用Navier-Stokes方程进行建模，而多孔床内的流动使用Brinkman方程进行描述。流体流动和传热的控制方程以及相关的边界条件，通过适当的相似变换简化为常微分方程组。然后采用级数展开技术，以获得速度和温度分布的解析近似。本研究的结果以图表形式呈现。除非另有说明，以下无量纲值用于数值计算:哈特曼数M=1，雷诺数R=0.1，达西参数β =0.05，导热系数λ =0.5，埃克特数Ec=10，滑移参数N^*=0.05, eta=1，普朗特数Pr_1=Pr_2=10。研究了达西参数、哈特曼数和导热系数对流体流速和温度的影响。

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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来源期刊

Journal of Electrical and Computer Engineering Innovations

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审稿时长

12 weeks