Numerical exploration on n-decane nanofluid based MHD mixed convection in a lid driven cavity: impact of magnetic field and thermal radiation

Q1 Chemical Engineering

International Journal of Thermofluids Pub Date : 2025-04-14 DOI:10.1016/j.ijft.2025.101209

Umme Habiba , M.N. Hudha , Badhan Neogi , Saiful Islam , M.M. Rahman

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Abstract

Due to efficient heat transfer properties, nanofluids have become the core of research in the present world in the sectors of engineering, biotechnology, pharmaceutical industries, etc. The present work prioritizes the numerical assessment of n-decane/graphite nanofluid MHD mixed convective flow within a lid-driven trapezoidal barrier with radiation effect, where the left and right bottom, the side walls are kept thermally insulated, the upper wall (moving with uniform velocity, u₀) is in cold temperature (T_c) and a rectangular heater (with temperature, T_h) is placed in the middle of the bottom wall of the enclosure. The numerical executions of governing equations are conducted by finite element method. The resulting parameters, Hartmann number (Ha = 0, 30, 50 and 80), solid nanoparticle volume fraction (ϕ = 1 %, 5 %, 10 % and 15 %), radiation parameter (Rd = 0, 2, 3 and 4), Reynolds number (Re = 100, 200, 300 and 400) depict the result in terms of streamlines, isothermal contours, average Nusselt number (Nu_av), average velocity (V_av). It is noticed that the Hartmann number has a negative influence on fluid flow, which diminishes the vortex strength, average heat transfer rate and average velocity in all cases. In the present case, mixing additional solid nanoparticles in the base fluid augments the Nu_av that is being transferred from the source to the fluid, but it lessens the flow strength and average velocity. An increase in Rd elevates the streamline vortex strength and average velocity; in contrast, Nu_av is dropped by the Radiation parameter. The Reynolds number appears to have a positive impact on the overall phenomena as it gives rise to all the streamlined vortex strength, Nu_av and V_av. This study provides new insights into fluid flow characteristics and heat transfer enhancement in a hydrocarbon-based nanofluid system by combining the influence of thermal radiation and different magnetic field intensities in a distinctive manner. A new HVAC device can also be designed with this idea.

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盖驱动腔内正癸烷纳米流体MHD混合对流的数值研究：磁场和热辐射的影响

纳米流体具有高效的传热特性，已成为当今世界工程、生物技术、制药等领域的研究热点。本文重点研究了正癸烷/石墨纳米流体MHD混合对流在具有辐射效应的盖子驱动的梯形屏障内的数值计算，其中左右底部的侧壁保持绝热，上壁（匀速运动，0）处于低温（Tc），底部壁中间放置一个矩形加热器（温度，Th）。采用有限元法对控制方程进行数值求解。所得参数，哈特曼数（Ha = 0,30,50和80），固体纳米颗粒体积分数（φ = 1%, 5%， 10%和15%），辐射参数（Rd = 0,2,3和4），雷诺数（Re = 100,200, 300和400）描述了流线，等温轮廓，平均努塞尔数（nuusselt number, Nuav），平均速度（Vav）的结果。注意到哈特曼数对流体流动有负向影响，在所有情况下，哈特曼数都使涡流强度、平均换热速率和平均速度减小。在目前的情况下，在基液中加入额外的固体纳米颗粒，增加了从源流体转移到流体的Nuav，但降低了流动强度和平均速度。Rd的增大使流线涡强度和平均速度升高；相比之下，Nuav被辐射参数删除。雷诺数似乎对整体现象有积极的影响，因为它产生了所有流线型涡强度，Nuav和Vav。本研究通过结合热辐射和不同磁场强度的影响，以独特的方式为基于碳氢化合物的纳米流体系统的流体流动特性和传热增强提供了新的见解。一个新的暖通空调设备也可以用这个想法来设计。

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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