Creation of Conducting Networks of Particles in Polymer Melts by Chaotic Mixing

CAE and Intelligent Processing of Polymeric Materials Pub Date : 1997-11-16 DOI:10.1115/imece1997-0642

R. Danescu, D. Zumbrunnen

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Abstract

Chaotic mixing of a nonconducting thermoplastic melt and initially coarse clusters of conducting particles has been investigated to assess opportunities for the in-situ formation of extended particle networks. Upon capture by solidification, such extended networks may render the composite electrically conducting. Chaotic advection of small, spherical, non-interacting particles was studied computationally and experimentally ill a cavity formed between two offset cylinders. Numerical tracking of individual particles was performed under conditions where global chaotic mixing prevailed. Formation mechanisms were identified at various stages of mixing. After mixing, networks comprising interconnected particles were identified as electrical pathways. Micrographs of composites produced experimentally by two-dimensional chaotic mixing of thermoplastics with conducting carbon black showed structures resembling those predicted by the simulations and provided further insights into formation mechanisms. The electrical resistivity of the composites is also compared to composites produced by conventional means.

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聚合物熔体中混沌混合粒子导电网络的建立

研究了不导电的热塑性熔体和最初粗糙的导电颗粒团簇的混沌混合，以评估原位形成扩展颗粒网络的机会。通过凝固捕获后，这种扩展的网络可以使复合材料导电。用计算方法和实验方法研究了小球形非相互作用粒子在两个偏置圆柱间形成的空腔中的混沌平流。在全局混沌混合的情况下，对单个粒子进行了数值跟踪。在混合的不同阶段确定了形成机制。混合后，由相互连接的粒子组成的网络被确定为电通路。热塑性塑料与导电炭黑的二维混沌混合实验产生的复合材料的显微照片显示出与模拟预测相似的结构，并为形成机制提供了进一步的见解。该复合材料的电阻率也与传统方法生产的复合材料进行了比较。

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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CAE and Intelligent Processing of Polymeric Materials

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