Optimization study of stacked micro-channel heat sinks for micro-electronic cooling

ITherm 2002. Eighth Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (Cat. No.02CH37258) Pub Date : 2002-08-07 DOI:10.1109/ITHERM.2002.1012490

Xiaojin Wei, Y. Joshi

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引用次数: 173

Abstract

With smaller inlet flow velocity, a micro-channel stack requires less pumping power to remove a certain amount of heat than a single-layered micro-channel, because it provides a larger heat transfer area. A simple thermal resistance network model was developed to evaluate the overall thermal performance of a stacked micro-channel heat sink. Based on this simple model, in this study, a single objective minimization of overall thermal resistance is carried out using genetic algorithms. The aspect ratio, fin thickness and the ratio of channel width to fin thickness are the variables to be optimized, subject to constraints of maximum pressure drop (4 bar) and maximum volumetric flow rate (1000 ml/min). During the optimization, the overall dimensions, number of layers and pumping power (product of pressure drop and flow rate) are fixed. The study indicates that reduction in thermal resistance can be achieved by optimizing the channel configuration. The effects of number of layers in the stack, pumping power per unit area, and the channel length are investigated.

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微电子冷却用堆叠式微通道散热片的优化研究

由于入口流速较小，与单层微通道相比，微通道堆栈需要更少的泵送功率来去除一定量的热量，因为它提供了更大的传热面积。建立了一个简单的热阻网络模型来评估堆叠微通道散热器的整体热性能。基于这个简单的模型，在本研究中，使用遗传算法实现了整体热阻的单目标最小化。在最大压降(4 bar)和最大体积流量(1000 ml/min)的约束下，长宽比、鳍片厚度和通道宽度与鳍片厚度之比是需要优化的变量。在优化过程中，总体尺寸、层数和泵送功率(压降与流量的乘积)是固定的。研究表明，通过优化通道结构可以降低热阻。研究了层数、单位面积抽运功率、通道长度等因素对系统性能的影响。

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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ITherm 2002. Eighth Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (Cat. No.02CH37258)

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