Calculation of Thermally Induced Mechanical Stresses in Encapsulated Assemblies

IEEE Transactions on Parts, Materials and Packaging Pub Date : 1970-12-01 DOI:10.1109/TPMP.1970.1136267

E. Baker

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引用次数: 5

Abstract

A procedure is given for the calculation of thermally induced mechanical stresses in electronic assemblies. This procedure can be used to calculate both elastic and plastic deformation during thermal cycling of multielement assemblies with complex configurations and heterogeneous material properties. It will give the strain (or stress) in each element at any temperature in the thermal cycle as the element undergoes elastic deformation, captive plastic deformation, or thermal ratchet. Several encapsulated systems were analyzed to demonstrate the applicability of the calculations to real assemblies. In one example, it was demonstrated that encapsulated electronic systems are subject to thermal ratchet. For the environmental temperatures used, it was shown that the assembly would grow (or ratchet) on each thermal cycle until one of the elements broke. It was found that thermal ratchet could be avoided by either decreasing or increasing the thickness of the encapsulant. In another example, a foamed cordwood module was analyzed to determine the effect of lead length on the stresses developed in a glass-cased component. It was shown that a small increase in the length of the component's leads significantly increased the stresses in the component.

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封装组件中热致机械应力的计算

给出了电子组件中热致机械应力的计算方法。该程序可用于计算具有复杂结构和非均质材料特性的多单元构件在热循环过程中的弹性和塑性变形。在热循环的任何温度下，当元件经历弹性变形、俘获塑性变形或热棘轮时，它将给出每个元件的应变(或应力)。对几个封装系统进行了分析，验证了计算结果对实际装配件的适用性。在一个例子中，它证明了封装的电子系统受到热棘轮。对于所使用的环境温度，结果表明，在每个热循环中，组件会增长(或棘轮)，直到其中一个元素断裂。通过减小或增加包封剂的厚度，可以避免热棘轮的产生。在另一个例子中，分析了一个泡沫芯木模块，以确定引线长度对玻璃外壳组件中产生的应力的影响。结果表明，构件引线长度的小幅增加显著增加了构件中的应力。

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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IEEE Transactions on Parts, Materials and Packaging

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