Package-level Si-based micro-jet impingement cooling solution with multiple drainage micro-trenches

2014 IEEE 16th Electronics Packaging Technology Conference (EPTC) Pub Date : 2014-12-01 DOI:10.1109/EPTC.2014.7028284

Yong Han, B. L. Lau, Hengyun Zhang, Xiaowu Zhang

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引用次数: 23

Abstract

High heat flux removal is a major consideration in the design of a number of microelectronic devices. A Si micro cooler, combining the merits of both micro-channels and jet impingement, has been developed to dissipate the heat flux for the IC chip. Multiple drainage micro-trenches (MDMT) have been designed inside the cooler to avoid the negative cross-flow effect between the nearby nozzles. The effect of the micro-trench width on the required pressure drop is analyzed. Three types of nozzle/trench arrangements are studied. Several simulations are conducted to study the thermal effect of the distance between nozzle and trench, when the same pumping power is supplied. Without cross-flow effect, full developed jet impingement can be achieved for each nozzle. With 0.2W pumping power, the spatially average heat transfer coefficient is around 15×104W/m2K. To dissipate 350W/cm2 heat flux uniformly loaded on the Si chip, the designed micro cooler can maintain the maximum chip temperature rise lower than 25°C, and low temperature variation within the chip. The designed cooler with MDMT is also quite effective for cooling the chip with concentrated heat fluxes.

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封装级硅基多排水微沟微射流冲击冷却解决方案

在许多微电子器件的设计中，高热流通量的去除是一个主要的考虑因素。结合微通道和射流冲击的优点，开发了一种硅微冷却器来散热芯片。冷却器内部设计了多个排水微沟(MDMT)，以避免相邻喷嘴之间的负交叉流效应。分析了微沟槽宽度对所需压降的影响。研究了三种喷嘴/沟槽布置方式。在相同泵送功率的情况下，对喷嘴与沟槽距离的热效应进行了仿真研究。在没有交叉流效应的情况下，每个喷嘴都可以实现充分发展的射流冲击。当泵送功率为0.2W时，空间平均换热系数约为15×104W/m2K。为使350W/cm2的热流均匀散去加载在硅片上，所设计的微冷却器能保持芯片最大温升低于25℃，且芯片内部温度变化小。设计的带有MDMT的冷却器对集中热流的芯片也有很好的冷却效果。

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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2014 IEEE 16th Electronics Packaging Technology Conference (EPTC)

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