Effect of Chemistry on Viscoelastic Properties of Moulding Compounds

K. Jansen, L. Ernst, H. Bressers
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引用次数: 1

Abstract

The present state-of-the-art in simulation of stresses in electronic packages is to model the moulding compound as a viscoelastic material. That means that stresses during packaging and subsequent thermomechanical loading are allowed to relax partially. Such an approach was seen to improve thermomechanical predictions considerably compared to the previously used temperature dependent elastic models. Therefore viscoelastic simulations are now becoming the standard for the modelling of packaging stresses and viscoelastic characterization of new moulding compound materials is now routinely being performed by most of the companies involved with packaging of electronic components. A problem is, however, that the viscoelastic data of moulding compounds turns out to be quite sensitive to variations in the compound chemistry and that this chemistry may vary slightly from batch to batch. Since these variations do not have a large effect on the room temperature properties (like the modulus) they often remain undetected by the standard quality tests. In order to anticipate to these problems it is desirable to develop a fundamental understanding of what parameters influence the viscoelastic properties of thermosets. A quantitative model, such as will be presented in this paper, has the additional advantage that it can be used for the selection of moulding compounds with optimized viscoelastic properties
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化学对模塑材料粘弹性的影响
目前电子封装应力模拟的最新技术是将成型化合物作为粘弹性材料进行建模。这意味着在包装和随后的热机械加载过程中的应力被允许部分放松。与以前使用的依赖温度的弹性模型相比,这种方法被认为大大改善了热力学预测。因此,粘弹性模拟现在已成为包装应力建模的标准,而新成型复合材料的粘弹性特性现在已被大多数涉及电子元件包装的公司常规执行。然而,一个问题是,成型化合物的粘弹性数据对化合物化学成分的变化非常敏感,而且这种化学成分可能在批次之间略有不同。由于这些变化对室温性能(如模量)没有很大影响,因此标准质量测试通常无法检测到它们。为了预测这些问题,需要对影响热固性材料粘弹性的参数有一个基本的了解。定量模型,如将在本文中提出,具有额外的优势,它可以用于选择具有优化粘弹性性能的成型化合物
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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