Mixed Convective Heat Transfer in a Lid-Driven Concentric Trapezoidal Enclosure: Numerical Simulation

IF 0.8 Q3 ENGINEERING, MULTIDISCIPLINARY

International Journal of Engineering Research in Africa Pub Date : 2022-05-20 DOI:10.4028/p-kybe41

O. Olayemi, K. Al‐Farhany, S. E. Ibitoye, A. Obalalu

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引用次数: 7

Abstract

This study investigates the implications of the area ratio (AR) and Grashof number (Gr) on fluid flow properties and heat transfer due to mixed convection around heated trapezoidal blocks located concentrically inside a larger trapezium driven by a lid. The outer trapezium's upper and lower horizontal walls are moving in opposite directions. The model developed was solved using the finite element technique. The inner walls of the trapezium are retained at an isothermal temperature, while the slanted outer walls of the trapezium are perfectly insulated. The upper and lower walls of the enclosure are subjected to normalized sinusoidal temperatures. Grashof number in the range of 103£Gr£105 and area ratios ( ) of , and were investigated. The simulation outcomes are displayed as stream function, isothermal contours, and local Nusselt number. Considering the interval of for the inner block, the Nusselt number increase with diminishing area ratio for the upper wall, while the response of the lower wall to Gr variation is a function of the AR considered. At the bottom wall of the outer trapezium, results showed that the rate of heat transfer was not significantly affected by changes in area ratio. Furthermore, as the AR reduces, the heat transmission along the top wall of the outer trapezium improves with the Grashof number, with the least and peak heat transfer enhancements occurring at 50 % and 100 % percent of the wall length, respectively.

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混合对流换热在一个盖子驱动的同心梯形外壳:数值模拟

本研究研究了面积比（AR）和格拉绍夫数（Gr）对流体流动特性和热传递的影响，这是由于加热的梯形块周围的混合对流，该块同心位于由盖子驱动的较大梯形内。外梯形的上下水平墙正朝着相反的方向移动。利用有限元技术对所建立的模型进行了求解。梯形的内壁保持在等温温度下，而梯形的倾斜外壁完全绝缘。外壳的上壁和下壁受到标准化正弦温度的影响。Grashof数在103英镑Gr英镑105英镑的范围内，和的面积比（）进行了调查。模拟结果显示为流函数、等温等值线和局部努塞尔数。考虑到内块的间隔，上壁的努塞尔数随着面积比的减小而增加，而下壁对Gr变化的响应是所考虑的AR的函数。在外梯形的底壁处，结果表明，面积比的变化对传热速率没有显著影响。此外，随着AR的减少，沿着外梯形顶壁的热传递随着Grashof数的增加而改善，最小和峰值传热增强分别发生在壁长的50%和100%处。

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

International Journal of Engineering Research in Africa ENGINEERING, MULTIDISCIPLINARY-

CiteScore

1.80

自引率

14.30%

发文量

期刊介绍： "International Journal of Engineering Research in Africa" is a peer-reviewed journal which is devoted to the publication of original scientific articles on research and development of engineering systems carried out in Africa and worldwide. We publish stand-alone papers by individual authors. The articles should be related to theoretical research or be based on practical study. Articles which are not from Africa should have the potential of contributing to its progress and development.