Unsteady Numerical Investigation Strategy of Natural Convection in an Isosceles Superimposed Triangular Enclosure

Mechanics Pub Date : 2024-02-23 DOI:10.5755/j02.mech.34030

E. Benachour, Khadidja Asnoune, Mohammed Hasnat, B. Draoui

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Abstract

In energy applications, convection plays a dominant role in the transport of energy for the proper design in order to achieve higher heat transfer rates. Where the fluid motion is simply induced by density gradients. This study is concerned with transient natural convection in an isosceles-superimposed triangular enclosure. The inclination of the inclined partitions walls was θ =45°. Critical Rayleigh numbers have been obtained: Ra=106, especially for the fluid crushed between the two triangles where we can visualize the critical convection transaction between the air and water. The results in quantitative measurement of average Nusselt number change and qualitative visualization of streamline and isotherms are examined. The air and water streamlines and the temperature fields were obtained for the Rayleigh numbers 103 ≤ Ra ≤ 108 for both cases studied. Besides, the highest heat transfer performance is observed during the natural convection case of the water fluid, and the lowest heat is transferred when the fluid is dilatant. The triangular shape can greatly enhance the heat transfer from the bottom to the top at first in a smooth and harmonious manner, and then it turns into a more complex and disorderly shape when the water reaches high temperatures.

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等腰叠置三角形围护结构中自然对流的非稳态数值研究策略

在能源应用中，对流在能量传输中起着主导作用，正确的设计可实现更高的热传导率。在这种情况下，流体运动只是由密度梯度引起的。本研究涉及等腰叠置三角形围墙中的瞬态自然对流。倾斜隔墙的倾角为 θ =45°。得到了临界瑞利数：Ra=106，特别是在两个三角形之间的流体挤压处，我们可以看到空气和水之间的临界对流交易。对平均努塞尔特数变化的定量测量结果以及流线和等温线的定性可视化进行了研究。在雷利数 103 ≤ Ra ≤ 108 的两种情况下，都获得了空气和水的流线和温度场。此外，在水流体自然对流的情况下，热传递性能最高，而在流体膨胀的情况下，热传递性能最低。三角形可以极大地增强从底部到顶部的传热，起初是平滑而和谐的，当水达到高温时，它就会变成更加复杂和无序的形状。

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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Mechanics

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