主板传热建模方法

Conference on High Density Microsystem Design and Packaging and Component Failure Analysis, 2006. HDP'06. Pub Date : 2006-06-27 DOI:10.1109/HDP.2006.1707563

Kar Mun Ng, K. R. Shah

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引用次数: 1

摘要

提出了一种用于预测球栅阵列封装温度的主板传导的标准建模方法。结果表明，准确的热预测需要MB内单个铜层和FR4层的离散表示，而不是一个有效块。MB信号层由一组平行的铜走线组成，并由正交各向异性层表示，以捕获沿走线方向敏感的热传导。通过增加FR4层的通平面电导率，可以捕捉到MB中通孔过孔的作用。该方法使用一组具有正交异性导热系数的棱柱和/或多边形块，可以在现有的计算流体动力学(CFD)和传热工具中实现。建立了一个mb级的测试装置，在一系列气流条件下验证了所提出的建模方法，结果表明，模型结果与测试数据吻合，最大误差为14%

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Motherboard heat transfer modeling methodology

A standard modeling method to represent conduction in motherboard (MB) for predicting a ball-grid array package temperature is developed. It is shown that discrete representation of individual copper and FR4 layers within MB rather than an effective block is needed for accurate thermal prediction. The MB signal layers consists of set of parallel copper traces and are represented by orthotropic layer to capture direction-sensitive thermal conduction along the traces. The role of through-hole vias in MB is captured by augmenting the through-plane conductivity of FR4 layers. The methodology uses a set of prismatic and/or polygon blocks with orthotropic thermal conductivities and can be implemented in existing computational fluid dynamic (CFD) and heat transfer tools. A MB-level test set-up is developed to validate the proposed modeling methodology under a range of airflow conditions and it is shown that the model results match the test data with maximum error of 14%

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Conference on High Density Microsystem Design and Packaging and Component Failure Analysis, 2006. HDP'06.

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