自然启发增强微观尺度传热在宏观几何

A. L. Goh, K. Ooi, U. Stimming
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引用次数: 4

摘要

为了满足电子工业对散热的高要求,引入了增强型微通道散热器。然而,与微加工技术相关的复杂性和高成本证明它们不适合用于传统的热交换器。因此,在宏观几何中实现微尺度通道的动机随之而来。在本研究中,环形微通道是通过将平均直径19.4 mm的圆柱形插片同心固定在内径20 mm的圆柱形管道内形成的。本文着眼于传热增强技术使用插入的自然启发型材。基于传统理论进行CFD模拟,预测了长度为30 mm、平均水力直径为600 μm、恒热输入为500 W时微通道内的传热和流动特性。在4 L/min (0.0667 kg/s)流速条件下,榴莲型、倒立鱼鳞型、鱼鳞型和平原型的对流换热系数分别为33.7、32.7、30.4和26.2 kW/m2·K。相对于Plain剖面,其增产幅度分别为29%、25%和16%。此外,在倒鱼鳞剖面下,8 L/min (0.133 kg/s)的流量条件下,对流换热系数达到59.2 kW/m2·K。发现压降值很容易满足市售泵。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Nature-inspired enhanced microscale heat transfer in macro geometry
To meet the high cooling demand in the electronics industry, enhanced microchannel heat sinks were introduced. However, the intricacies and high costs associated with microfabrication technologies prove them unsuitable for application in conventional heat exchangers. Hence, the motivation to implement microscale passages in macro geometries ensues. In this study, the annular microchannel is formed by securing a cylindrical insert of mean diameter 19.4 mm concentrically within a cylindrical pipe of internal diameter 20 mm. The paper looks at heat transfer enhancement techniques using inserts of nature-inspired profiles. CFD simulations based on conventional theory were carried out to predict the heat transfer and flow characteristics in the microchannel, for length of 30 mm, mean hydraulic diameter of 600 μm, and under constant heat input of 500 W. Under flow condition of 4 L/min (0.0667 kg/s), convective heat transfer coefficient values of 33.7, 32.7, 30.4 and 26.2 kW/m2·K are obtained for the Durian, Inverted Fish Scale, Fish Scale and Plain profiles respectively. This corresponds to an enhancement of 29%, 25% and 16% respectively, relative to the Plain profile. In addition, using Inverted Fish Scale profile, flow condition of 8 L/min (0.133 kg/s) yield a significant convective heat transfer coefficient value of 59.2 kW/m2·K. The pressure drop values are found to be easily met by a commercially available pump.
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