Investigation of the effect of PCB inner copper layer plastic deformation on solder joint fatigue simulations of mechanical cyclic bending tests

2021 27th International Workshop on Thermal Investigations of ICs and Systems (THERMINIC) Pub Date : 2021-09-23 DOI:10.1109/THERMINIC52472.2021.9626524

Maofen Zhang, Y. S. Chan, Martin Richard Niessner, P. Altieri-Weimar, B. Wunderle

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引用次数: 1

Abstract

Microelectronic packages undergo both thermal and mechanical loading during application, which can affect solder joint lifetime. Therefore, solder joint fatigue under both cycling thermal loading and mechanical bending should be assessed. This can be done by finite element simulation method during early design stage. An accurate finite element simulation model is needed to describe the fatigue of the solder joint and derive lifetime predictions. Especially in mechanical cycle bending test simulation, the PCB mechanical properties are a key factor for accurate description of the loading on the solder joint. In this study, a multilayer FR4 PCB is used, including several copper layers, which undergo plastic deformation under bending. Copper plasticity is included in the finite element model and calibrated using force-displacement data from the bending tests. It is found that PCB inner copper plasticity should not be neglected, otherwise the loading on the solder joint would be overestimated and the lifetime prediction inaccurate.

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PCB内铜层塑性变形对机械循环弯曲试验中焊点疲劳模拟的影响

微电子封装在应用过程中会受到热载荷和机械载荷的影响，从而影响焊点的使用寿命。因此，应评估循环热载荷和机械弯曲下的焊点疲劳。这可以在设计初期通过有限元模拟方法来实现。需要一个精确的有限元仿真模型来描述焊点的疲劳状态并进行寿命预测。特别是在机械循环弯曲试验模拟中，PCB的力学性能是准确描述焊点载荷的关键因素。在本研究中，使用多层FR4 PCB，包括几层铜层，在弯曲下发生塑性变形。铜的塑性包含在有限元模型中，并使用弯曲试验的力-位移数据进行校准。发现PCB内铜的塑性不可忽视，否则会高估焊点上的载荷，导致寿命预测不准确。

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

2021 27th International Workshop on Thermal Investigations of ICs and Systems (THERMINIC)

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