Convection Heat Transfer from Heated Thin Cylinders Inside a Ventilated Enclosure

Semiconductor Science and Information Devices Pub Date : 2022-07-15 DOI:10.30564/ssid.v4i2.4719

A. Riaz, A. Ibrahim, M. Bashir, Muhammad Abdullah, Ajmal Shah, A. Quddus

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Abstract

Experimental study was conducted to determine the effect of velocity of axial fan, outlet vent height, position, area, and aspect ratio (h/w) of ventilated enclosure on convection heat transfer. Rectangular wooden ventilated enclosure having top and front transparent wall was made up of Perspex for visualization, and internal physical dimensions of box were 200 mm × 200 mm × 400 mm. Inlet vent was at bottom while outlet vents were at the side and top wall. Electrically heated cylindrical heat source having 6.1 slenderness ratio was fabricated and hanged at the centre of the enclosure. To calculate heat transfer rates, thermocouples were attached to the inner surface of heat source with silica gel. Heat source was operated at constant heat flux in order to quantify the effect of velocity of air on heat transfer. It was observed that average Nusselt number was increased from 68 to 216 by changing velocity from 0 to 3.34 m/s at constant modified Grashof number i.e. 5.67E+09. While variation in outlet height at the front wall did not affect heat transfer in forced convection region. However, Nusselt number decreased to 5% by changing the outlet position from top to the front wall or by 50% reduction in outlet area during forced convection. Mean rise in temperature of enclosure increased from 8.19 K to 9.40 K by increasing aspect ratio of enclosure from 1.5 to 2 by operating heat source at constant heat flux i.e. 541.20 w/m2.

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在通风的外壳内加热薄圆筒的对流传热

实验研究了轴流风机的转速、排气口高度、通风罩的位置、面积和展弦比(h/w)对对流换热的影响。矩形木质通风框，顶部和前部的透明墙由有机玻璃制成，便于视觉化，箱体内部物理尺寸为200mm × 200mm × 400mm。进风口在底部，出风口在侧面和顶部。制造长细比为6.1的电加热圆柱形热源，并悬挂在外壳的中心。为了计算传热速率，用硅胶将热电偶附着在热源的内表面。为了量化空气流速对传热的影响，热源在恒热流密度下运行。在修正Grashof数为5.67E+09的恒定条件下，将速度从0改变到3.34 m/s，平均努塞尔数从68增加到216。而前壁面出口高度的变化对强制对流区换热没有影响。然而，通过将出口位置从顶部改变到前壁面或在强制对流时将出口面积减少50%，努塞尔数下降到5%。当热源的热流密度为541.20 w/m2时，将围护结构的长径比从1.5增加到2，围护结构的平均温升从8.19 K增加到9.40 K。

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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