Magneto Hydrodynamic Nanofluid Flow over Convectively Heated Plate on Radially Stretching Sheet Embedded on Porous Media

The Dhaka University Journal of Science Pub Date : 2023-09-11 DOI:10.59952/tuj.v5i3.271

Kulow Alou Alai, Maurine Maraka Wafula, Lawrence Njau

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Abstract

Fluid flow through this media is a key component in a wide range of activities like the generation of fluids from subsurface reservoirs and subterranean water resource restoration. Consequently, the study’s goal is to investigate the motion of Magneto Hydro Dynamics (MHD) nanofluids across a convectively heated plate superimposed on a radially expanding sheet embedded in a porous media. The model is formulated and non dimensionalized using similarity variables. By employing the shooting technique to transform the boundary conditions and, the R-K scheme in MATLAB bvp4c, the system of ODEs is solved. The results obtained are displayed in graphs and others in tables. The results indicate that with increasing porosity, magnetism, and surface rotation, the flow primary velocity decreases while the temperature profile surges. The findings from this study will provide beneficial theoretical insight into what parameters should be varied for maximum profit in several sectors like the power engineering sector, aerodynamic combination, drug recovery systems, and water solar heating systems.

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磁流体动力学纳米流体在对流加热板上径向拉伸嵌入多孔介质

通过这种介质的流体流动是地下储层流体生成和地下水资源恢复等广泛活动的关键组成部分。因此，该研究的目标是研究磁流体动力学(MHD)纳米流体在对流加热板上的运动，该板叠加在嵌入多孔介质的径向膨胀板上。该模型是公式化和无因次化使用相似变量。采用射击技术对边界条件进行变换，并在MATLAB bvp4c中采用R-K格式对系统进行求解。得到的结果以图表的形式显示，其他的以表格的形式显示。结果表明，随着孔隙度、磁性和表面旋转的增加，流体的一次流速减小，而温度曲线上升。这项研究的结果将提供有益的理论见解，以了解在电力工程领域、空气动力学组合、药物回收系统和水太阳能加热系统等几个领域，应该改变哪些参数以获得最大利润。

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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The Dhaka University Journal of Science

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