Unsteady MHD-radiative thin film flow with heat transfer over a stretching surface in porous media

IF 2.8 Q2 THERMODYNAMICS
Heat Transfer Pub Date : 2024-07-09 DOI:10.1002/htj.23122
G. Gomathy, B. Rushi Kumar
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引用次数: 0

Abstract

This study conducts a computational analysis to explore how magnetic fields, radiation, heat, and mass transfer collectively influence a horizontal stretching sheet within a porous medium. The research focuses on elucidating the dynamics of thin film flow through the formulation of time-dependent equations and subsequent transformation of fluid flow equations into ordinary differential equations via similarity transformation. The numerical solution is attained employing the Runge–Kutta fourth-order method coupled with a shooting technique. MATLAB software is utilized to generate graphs and numerical values, offering a detailed representation of engineering-relevant physical quantities in tabular form. The investigation revealed notable trends associated with varying parameters. Increasing unsteadiness parameters lead to a reduction in velocity, temperature, and concentration fields, while the temperature distribution demonstrates a positive correlation with radiation parameters. Moreover, elevated Prandtl numbers and unsteadiness parameters correspond to augmented heat and mass flux, respectively. Of particular significance is the observed heightened heat transfer rate during the transition from a Prandtl number of 1 (representing air) to 2 (representing oil), alongside an increased mass transfer rate with the escalation in Schmidt number from 0.62 (representing hydrogen) to 0.78 (representing ammonia). A comparative analysis of the numerical findings with existing literature demonstrates excellent agreement, affirming the validity and relevance of the present study. These insights offer valuable implications for understanding and optimizing heat and mass transfer processes in porous media, with potential applications in various engineering and scientific domains.

多孔介质拉伸表面上带有热传递的非稳态 MHD 辐射薄膜流
本研究通过计算分析,探讨磁场、辐射、热量和质量传递如何共同影响多孔介质中的水平拉伸薄片。研究的重点是通过制定随时间变化的方程,以及随后通过相似性变换将流体流动方程转化为常微分方程,来阐明薄膜流动的动力学。数值求解采用 Runge-Kutta 四阶方法和射击技术。利用 MATLAB 软件生成图表和数值,以表格形式详细介绍了与工程相关的物理量。调查显示了与参数变化相关的显著趋势。不稳定性参数的增加会导致速度场、温度场和浓度场的减小,而温度分布则与辐射参数呈正相关。此外,普朗特数和不稳定参数的升高分别对应于热通量和质量通量的增加。特别重要的是,在普朗特数从 1(代表空气)升至 2(代表油)的过程中,观察到传热速率增加,同时随着施密特数从 0.62(代表氢气)升至 0.78(代表氨气),传质速率增加。数值结果与现有文献的对比分析表明两者非常吻合,从而肯定了本研究的有效性和相关性。这些见解为理解和优化多孔介质中的传热和传质过程提供了有价值的启示,并有可能应用于各种工程和科学领域。
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
Heat Transfer
Heat Transfer THERMODYNAMICS-
CiteScore
6.30
自引率
19.40%
发文量
342
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