Experimentation on Optimal Configuration and Size of Thin Cylinders in Natural Convection

Semiconductor Science and Information Devices Pub Date : 2022-08-04 DOI:10.30564/ssid.v4i2.4720

A. Riaz, A. Ibrahim, M. Bashir, Masroor Asghar, Muhammad Abdullah, Ajmal Shah

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Abstract

In this paper, an experimental study of laminar, steady state natural convection heat transfer from heated thin cylinders in an infinite air medium has been reported. Two electrically heated cylinders having the same slenderness ratio (L/D) i.e. 6.1 but different diameters i.e. 3.8 cm and 5.08 cm were used. 105 experiments were carried out to study the effect of diameter and inclination angle of thin cylinder on natural convection heat transfer. After mandatory corrections of radiation and endcap heat losses, convective heat transfer results were presented in the form of local and average dimensionless numbers. For vertical configuration of thin cylinder, Nusselt number was varied from 52.99 to 95.10 corresponding to 1.28×108≤Ra*L≤1.08×1010. While for horizontal configuration,Nusselt number was varied from 10.74 to 17.78 corresponding to 9.42×104≤Ra*D≤8.17×106. Results were compared with the published data and found satisfactory as the maximum percentage difference was only 3.09%. The essence of research is that the heat transfer coefficient increases with decrease in diameter and increase in inclination angle. Smoke flow visualization was done to capture patterns of fluid flow. Finally, comparison was made to quantify increase in Nusselt number from slender cylinder as compared to the flat plate.

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自然对流条件下薄圆柱的优化配置与尺寸试验

本文报道了在无限空气介质中加热薄圆柱体的层流、稳态自然对流换热的实验研究。使用两个长细比相同(L/D)为6.1但直径不同(3.8 cm和5.08 cm)的电热气缸。通过105个实验研究了细圆柱直径和倾角对自然对流换热的影响。在对辐射和末端热损失进行强制校正后，对流换热结果以局部和平均无因次数的形式呈现。对于薄圆筒的垂直构型，Nusselt数在52.99 ~ 95.10之间变化，对应1.28×108≤Ra*L≤1.08×1010。水平配置时，Nusselt数为10.74 ~ 17.78，对应9.42×104≤Ra*D≤8.17×106。结果与已发表的资料比较，最大百分比差异仅为3.09%，令人满意。研究的实质是传热系数随直径的减小和倾角的增大而增大。烟流可视化是为了捕捉流体流动的模式。最后，与平板相比，细长圆柱体对努塞尔数的增加进行了量化比较。

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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Semiconductor Science and Information Devices

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