Application of a geometrically nonlinear elastoplastic gradient-enhanced damage model with incremental potential to composite microstructures

IF 1.1 4区工程技术 Q3 MATERIALS SCIENCE, CHARACTERIZATION & TESTING Archives of Mechanics Pub Date : 2021-10-20 DOI:10.24423/AOM.3813

H. Boussetta, J. Dittmann, S. Wulfinghoff

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Abstract

The prediction of inelastic processes like plastic deformations and cracks within the microstructure of modern man-made materials by realistic, yet simple and efficient continuum models remains a major task in material modelling. For this purpose, gradient-extended standard dissipative solids represent one of the most promising model classes, which is also formulated and applied in this work to investigate microscopic failure mechanisms in three exemplary three-dimensional composite microstructures. The model combines geometrically nonlinear isotropic elastoplasticity with an isotropic damage model with gradient-extension. For the numerical treatment, a variational constitutive update algorithm based on the exponential map is applied. The model is used to provide insight into the microscopic failure of a brittle woven composite material, a particle-reinforced plastic and a carbon fiber reinforced composite. The influence of different microstructural and material parameters on the overall failure behavior is characterized. Adaptive meshing is used to enable a refined numerical resolution of the cracked regions.

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几何非线性增量势弹塑性梯度增强损伤模型在复合材料微结构中的应用

在现代人造材料的微观结构中，用现实的、简单而有效的连续体模型预测塑性变形和裂纹等非弹性过程仍然是材料建模中的一个主要任务。为此，梯度扩展的标准耗散固体代表了最有前途的模型类别之一，它也被制定并应用于本工作中，以研究三个示例性三维复合微观结构的微观破坏机制。该模型将几何非线性各向同性弹塑性与梯度扩展的各向同性损伤模型相结合。对于数值处理，采用了一种基于指数映射的变分本构更新算法。该模型用于研究脆性编织复合材料、颗粒增强塑料和碳纤维增强复合材料的微观破坏。研究了不同的微观组织和材料参数对整体破坏行为的影响。采用自适应网格法对裂纹区域进行精细的数值解析。

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来源期刊

Archives of Mechanics 工程技术-材料科学：表征与测试

CiteScore

1.40

自引率

12.50%

发文量

审稿时长

>12 weeks

期刊介绍： Archives of Mechanics provides a forum for original research on mechanics of solids, fluids and discrete systems, including the development of mathematical methods for solving mechanical problems. The journal encompasses all aspects of the field, with the emphasis placed on: -mechanics of materials: elasticity, plasticity, time-dependent phenomena, phase transformation, damage, fracture; physical and experimental foundations, micromechanics, thermodynamics, instabilities; -methods and problems in continuum mechanics: general theory and novel applications, thermomechanics, structural analysis, porous media, contact problems; -dynamics of material systems; -fluid flows and interactions with solids. Papers published in the Archives should contain original contributions dealing with theoretical, experimental, or numerical aspects of mechanical problems listed above. The journal publishes also current announcements and information about important scientific events of possible interest to its readers, like conferences, congresses, symposia, work-shops, courses, etc. Occasionally, special issues of the journal may be devoted to publication of all or selected papers presented at international conferences or other scientific meetings. However, all papers intended for such an issue are subjected to the usual reviewing and acceptance procedure.