Monte-Carlo Simulation of Compatibilization by Network-Building and Catalytic Interface Reactions in Two-Component Injection Molding

A. John, J. Nagel, G. Heinrich
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引用次数: 3

Abstract

Adhesion of immiscible polymers during two-component injection molding can be improved by transreactions of properly functionalized molecules in situ by exploitation of the thermal energy of the melts. These reactions must pro- vide a sufficient conversion of reactive monomers in the short cooling time down to the glass temperature. Furthermore, as much as possible interconnecting chemical links on the molecular level have to be created between the components within the small spatial region of the interdiffusion interface width. To investigate these processes, we performed Monte- Carlo (MC) simulations based on the three-dimensional coarse-grained Bond Fluctuation Model (BFM) including a ther- mal interaction potential in r 6 with energy = 0.1 kBT . We compared a simple Split type reaction, which is capable of network-forming, with a catalytic interface reactive process both exhibiting different values of activation energy. The main process of the catalytic reaction system is identical to the simple Split reaction as described in a previous paper, but now a reactive monomer creating process is prefixed. For the reacting systems different physical properties like consump- tion, radius of gyration, concentration profiles or the distribution of the degree of polymerization were calculated as a function of time. Additionally, several functions for the description of the adhesive strength on the molecular level were adopted and calculated depending on reaction type, activation energy and degree of consumption, respectively. From the results, those chemical reaction types were deduced, which should be most suitable for compatibilization intentions in two-component injection molding.
双组分注射成型中网络构建和催化界面反应相容化的蒙特卡罗模拟
在双组分注射成型过程中,可以利用熔体的热能,使适当功能化的分子在原位发生反应,从而改善非混相聚合物的粘附性。这些反应必须在较短的冷却时间内使活性单体充分转化到玻璃温度。此外,在相互扩散界面宽度的小空间区域内,必须在组分之间创建尽可能多的分子水平上的相互连接的化学链接。为了研究这些过程,我们基于三维粗粒度键波动模型(BFM)进行了蒙特卡罗(MC)模拟,其中包括r6中能量= 0.1 kBT的热相互作用势。我们比较了具有成网能力的简单分裂型反应和具有不同活化能的催化界面反应。催化反应体系的主要过程与前一篇文章中描述的简单分裂反应相同,但现在增加了一个反应性单体生成过程。对于反应体系的不同物理性质,如消耗、旋转半径、浓度分布或聚合度的分布作为时间的函数进行了计算。另外,根据反应类型、活化能和消耗程度,采用了分子水平上描述粘接强度的几个函数,并分别进行了计算。根据实验结果,推导出了最适合于双组分注射成型中增容意图的化学反应类型。
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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