Modeling noncoplanarity effects on thermal performance of computer chips

2007 12th International Symposium on Advanced Packaging Materials: Processes, Properties, and Interfaces Pub Date : 2007-10-01 DOI:10.1109/ISAPM.2007.4419927

Ninad Bhave, Nicole Okamoto

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引用次数: 1

Abstract

A project was undertaken to investigate the effects of noncoplanarity (the absence of perfect surface flatness) on heat transfer in computer chip packages. The goal of the project was to determine the level of model complexity required to accurately determine thermal contact resistance in the presence of non-coplanarity and to determine a method to accurately model these effects using conventional finiteelement and CFD packages. Various types of air gaps were modeled and results tabulated. It was found that heat transfer within gaps on the order of tens of microns could be analyzed by “scaling-up” the model so that minimum cell size of the meshing software was no longer an issue. The scaled and unscaled results agreed to within 97%. Published data and the CFD model results agreed to within 96%. While noncoplanarity was shown to have a significant effect on the thermal contact resistance, it was shown that a complex model of the thermal interface material is not needed for an accurate simulation.

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非共面性对计算机芯片热性能的影响

一个项目进行了调查的影响非共面性(缺乏完美的表面平面)对传热的计算机芯片封装。该项目的目标是确定在非共面情况下精确确定热接触电阻所需的模型复杂性水平，并确定一种使用传统有限元和CFD软件包精确模拟这些影响的方法。对不同类型的气隙进行了建模，并将结果制成表格。结果发现，可以通过“放大”模型来分析数十微米量级的间隙内的传热，从而使网格划分软件的最小单元尺寸不再是一个问题。缩放和未缩放的结果一致在97%以内。已发表的数据与CFD模型结果的一致性在96%以内。虽然非共面性对热接触电阻有显著影响，但研究表明，不需要复杂的热界面材料模型来进行精确的模拟。

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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来源期刊

2007 12th International Symposium on Advanced Packaging Materials: Processes, Properties, and Interfaces

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