Entropy Generation Analysis OF Mhd Micropolar – Nanofluid Flow Over A Moved And Permeable Vertical Plate

Q3 Chemical Engineering International Journal of Applied Mechanics and Engineering Pub Date : 2024-03-26 DOI:10.59441/ijame/175807

N. Bouaziz, Reda Allouaoui, Abderaouf Mesbah, Amina Manal Bouaziz

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Abstract

The work's goal is to learn more about how a magnetic field, Brownian motion, and thermophoresis diffusion influence convective heat transfer in a micropolar-nanofluid flow's laminar boundary layer. Near a vertically moving, permeable plate, the complex fluid is subjected to MHD. The MATLAB application bvp4c was utilized to simplify the governing nonlinear and coupled equations for the micropolar-nanofluid, leading to the solution of the ensuing ordinary differential equations (ODEs). Graphs have been used to analyze the effect of different relevant active factors on the flow field and temperature. The results demonstrate that the micro-rotation of the nanoparticles taken into account and in suspension becomes significant for the complex fluid in the presence of the magnetic field. Analysis of the generation entropy shows that the surface is a significant source of irreversibility. There is no discernible effect of micropolarity on the relationship between Brownian and thermophoresis numbers and entropy generation.

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移动和渗透垂直板上的 Mhd 微极性 - 纳米流体流动的熵生成分析

这项工作的目标是进一步了解磁场、布朗运动和热泳扩散如何影响微极性纳米流体流层状边界层中的对流传热。在垂直移动的可渗透板附近，复合流体受到 MHD 的作用。利用 MATLAB 应用程序 bvp4c 简化了微-纳流体的非线性和耦合控制方程，从而求解了随后的常微分方程（ODEs）。利用图表分析了不同相关活动因素对流场和温度的影响。结果表明，在磁场存在的情况下，考虑到悬浮中的纳米粒子的微旋转对于复杂流体来说变得非常重要。对生成熵的分析表明，表面是不可逆的重要来源。微极性对布朗运动和热泳数与熵生成之间的关系没有明显影响。

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来源期刊

International Journal of Applied Mechanics and Engineering Engineering-Civil and Structural Engineering

CiteScore

1.50

自引率

0.00%

发文量

审稿时长

35 weeks

期刊介绍： INTERNATIONAL JOURNAL OF APPLIED MECHANICS AND ENGINEERING is an archival journal which aims to publish high quality original papers. These should encompass the best fundamental and applied science with an emphasis on their application to the highest engineering practice. The scope includes all aspects of science and engineering which have relevance to: biomechanics, elasticity, plasticity, vibrations, mechanics of structures, mechatronics, plates & shells, magnetohydrodynamics, rheology, thermodynamics, tribology, fluid dynamics.