Thermal analysis of MHD unsteady Darcy‐Forchheimer thin film flow in a porous system

Gomathy G, B. Rushi Kumar
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Abstract

This study has investigated a Darcy‐Forchheimer thin film flow over an extended horizontal surface with thermal radiation and chemical reaction effects. The governing time‐dependent equations have been non‐dimensionalized using similarity transformations and solved numerically using the fourth‐order Runge‐Kutta method and the shooting technique. The influence of magnetohydrodynamics, non‐uniform heat sourcing, viscous heat radiation, and chemical reactions on temperature, velocity, skin friction, Nusselt, and Sherwood numbers has been examined. Results have shown that porous media, magnetic field, and transient effects decrease the velocity profile, while thermal radiation and variable thermal properties enhance temperature distributions. Findings have indicated that the magnetic field and porosity enhance the skin friction coefficient whereas the heat transfer rate increases with Eckert number and Prandtl number. Rising the chemical reaction parameter from 0.2 to 0.5 rises the mass transfer rate by approximately 9.85%. The thermal analysis of MHD Darcy‐Forchheimer thin film flow in a porous system has been crucial for understanding heat transfer and fluid dynamics in complex environments. It helped in optimizing various engineering processes, such as cooling systems, filtration, and energy conversion, by providing insights into temperature distribution, convective heat transfer, and fluid behavior. This analysis has aided in designing efficient and reliable systems with improved performance and reduced energy consumption.
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多孔系统中 MHD 非稳态达西-福克海默薄膜流的热分析
本研究探讨了具有热辐射和化学反应效应的延伸水平表面上的达西-福克海默薄膜流。利用相似变换对随时间变化的支配方程进行了非尺寸化处理,并使用四阶 Runge-Kutta 方法和射击技术进行了数值求解。研究了磁流体力学、非均匀热源、粘性热辐射和化学反应对温度、速度、表皮摩擦、努塞尔特数和舍伍德数的影响。结果表明,多孔介质、磁场和瞬态效应会降低速度曲线,而热辐射和可变热特性会增强温度分布。研究结果表明,磁场和多孔性增强了表皮摩擦系数,而传热速率则随着埃克特数和普朗特数的增加而增加。将化学反应参数从 0.2 提高到 0.5,可使传质率提高约 9.85%。多孔系统中 MHD 达西-福克海默薄膜流的热分析对于理解复杂环境中的传热和流体动力学至关重要。通过深入了解温度分布、对流传热和流体行为,它有助于优化冷却系统、过滤和能源转换等各种工程流程。这种分析有助于设计高效可靠的系统,提高性能并降低能耗。
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