Multiscale Modeling of the Impact Response of Triaxially Braided Polymer Matrix Composites, Including Effects of Adiabatic Heating

American Society for Composites 2018 Pub Date : 2018-11-07 DOI:10.12783/ASC33/25997

C. Sorini, A. Chattopadhyay, R. Goldberg

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Abstract

Significant local temperature rises often accompany the high rate deformation of polymer matrix composites. In the case of impact loading, heat is generated locally within the polymer matrix due to plastic dissipation, but the rapid nature of the loading precludes significant heat transfer from occurring; ballistic impact loading can therefore be regarded as fully adiabatic. In this paper, the development of a synergistic multiscale approach to simulate the architecturally dependent impact response of polymer matrix composites with complex fiber tow architectures is presented and applied to a representative triaxially braided composite material system. To approximate the heterogeneity of the composite braid architecture at the highest analysis length scale, a subcell-based approach is utilized whereby the mesoscale repeating unit cell of the material is discretized in-plane into an assemblage of laminated composite subcell regions, with stacking sequences determined from the braid architecture. Each unidirectional layer of the laminated composite subcells are modeled with the generalized method of cells micromechanics theory, where a nonisothermal viscoplastic constitutive model is employed to model the rate, temperature, and pressure dependent polymer matrix. Matrix temperature rises due to inelastic deformation are computed. in matrix elastic properties are determined from neat resin dynamic mechanical analysis data. The commercial transient dynamic finite element code LS-DYNA is utilized to conduct simulations of quasi-static coupon tests and flat panel impact tests performed on a T700/PR520 [0°/60°/–60°] triaxially braided composite. Good agreement is found between simulations and experiments. It is expected that, once progressive damage and failure are incorporated into the multiscale scheme, the incorporation of adiabatic heating affects will greatly improve the predictive capability of current models.

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包括绝热加热影响的三轴编织聚合物基复合材料冲击响应的多尺度建模

显著的局部温度升高往往伴随着高速率的聚合物基复合材料的变形。在冲击载荷的情况下，由于塑性耗散，热量在聚合物基体内部局部产生，但载荷的快速性质阻止了大量热量传递的发生;因此，可以认为弹道冲击载荷是完全绝热的。本文提出了一种协同多尺度方法来模拟具有复杂纤维束结构的聚合物基复合材料的结构相关冲击响应，并将其应用于具有代表性的三轴编织复合材料体系。为了在最高分析长度尺度上近似复合编织结构的异质性，利用基于亚单元的方法，将材料的中尺度重复单元在平面内离散为层压复合材料亚单元区域的集合，并根据编织结构确定堆叠顺序。采用细胞微力学理论的广义方法对层合复合材料亚细胞的每一单向层进行了建模，其中采用非等温粘塑性本构模型对速率、温度和压力相关的聚合物基体进行了建模。计算了非弹性变形引起的基体温升。根据纯树脂动态力学分析数据确定了基体的弹性性能。利用商用瞬态动态有限元代码LS-DYNA对T700/PR520[0°/60°/ -60°]三轴编织复合材料进行准静态粘片试验和平板冲击试验模拟。仿真结果与实验结果吻合较好。如果将渐进性损伤和破坏纳入多尺度方案，那么考虑绝热影响将大大提高现有模型的预测能力。

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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American Society for Composites 2018

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