半结晶聚合物的多尺度建模和微机械特性

Chenxu Jiang , Jia Zhou , Peng Jiang , Changqing Miao
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引用次数: 0

摘要

这项研究提出了预测半结晶聚合物微机械性能的多尺度模型。半结晶聚合物通常为球状晶体结构,但并非完全径向对称。在球晶生长的初始阶段,其结构表现为具有一定取向的多层晶片,即片状结构。叶片结构的大小和取向受各种加工参数的影响。以往的研究认为球沸石是完全径向对称的结构,忽略了结构各向异性对力学性能的影响。在这项工作中,首先模拟了不同初始取向的单一球粒体的微观结构。晶体塑性组成模型和 Arruda-Boyce 模型分别用于描述晶体薄片和无定形薄片的微观力学行为。在单个球粒体变形行为的基础上,利用 Voronoi 网格描述了多球粒体的特征,观察了拉伸条件下不均匀塑性变形和层间变形的演变。实现了从微观建模到中观建模的跨尺度分析。这项工作所显示的结果加深了人们对半结晶聚合物微观机械特性的理解,进而为提高其在制造过程中的抗断裂性提供了理论指导。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Multi-Scale Modelling And Micromechanical Properties Of Semi-Crystalline Polymers

This work proposed multi-scale modelling to predict the micromechanical properties of semi-crystalline polymers. Semi-crystalline polymers are usually spherulitic crystal structure, which is, however, not completely radially symmetric. In the initial stage of spherulite growth, its structure is manifested as multilayer wafers with a certain orientation namely sheaf structure. The size and orientation of sheaf structure are affected by various processing parameters. Previous research considered spherulite as completely radially symmetric structures, ignoring the effects of structures anisotropy on mechanical properties. In this work, the microstructure of single spherulite was first modelled with different initial orientations. The crystal plasticity constitutive model together with the Arruda-Boyce model was used to describe the micromechanical behaviors of the crystalline lamellae and amorphous lamellae, respectively. Based on the deformation behaviors of single spherulite, the Voronoi tessellation was then used to characterize the multi-spherulites, the evolution of inhomogeneous plastic deformation and inter-lamellae deformation was observed under tension. Achieving the cross-scale analysis from micro-modeling to meso-modeling. The results shown by this work improve the understanding of the micromechanical properties of semi-crystalline polymers, which, in turn, provides theoretical guides to improve their fracture resistance in manufacturing.

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