Peridynamic modeling of nonlocal degrading interfaces in composites

IF 3.2 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Forces in mechanics Pub Date : 2023-02-01 DOI:10.1016/j.finmec.2022.100124
Marie Laurien , Ali Javili , Paul Steinmann
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引用次数: 5

Abstract

When modeling composite materials at small scales, the consideration of nonlocal effects is fundamental. In addition, the overall response of matrix-inclusion composites is strongly affected by the behavior of the interface between inclusion and matrix. This can be attributed to a possible detachment of the constituents as well as the high interface-to-volume ratio especially for nano-sized inclusions. Peridynamics is a nonlocal theory that is suitable to introduce a length-scale into a continuum description and take into account nonlocal interactions. Complex interface models within a peridynamic framework are, however, rarely studied. The objective of this work is to present a modeling approach to nonlocal interfaces accounting for opening and degradation within the framework of continuum-kinematics-inspired peridynamics (CPD). The proposed method is employed to study nonlocal effects in matrix-inclusion composites with focus on the effect of nonlocal interfaces. In our approach, the nonlocal interface is modeled as a finite thickness interface, i.e. a region where the subdomains overlap. Within this region, the constituents are pair-wise connected through interface bonding forces that follow a characteristic force-opening law. In computational experiments, our model captures the influence of the strength and size of the interface as well as the inclusion volume fraction on the overall response. In particular, nonlocality manifests itself through a “smaller–stiffer” material behavior and an increased influence of the interface, which highlights the importance of an appropriate nonlocal interface model.

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复合材料非局部降解界面的周动力学建模
在对复合材料进行小尺度建模时,非局部效应的考虑是至关重要的。此外,基体-包体复合材料的整体响应受包体与基体界面行为的强烈影响。这可以归因于可能的组分分离以及高界面体积比,特别是纳米尺寸的包裹体。周期动力学是一种适用于在连续体描述中引入长度尺度并考虑非局部相互作用的非局部理论。然而,在周动力框架内的复杂界面模型很少被研究。本工作的目的是提出一种在连续运动学激励周动力学(CPD)框架内考虑开放和退化的非局部界面的建模方法。将该方法应用于基体-包体复合材料的非局部效应研究,重点研究了非局部界面的影响。在我们的方法中,非局部界面被建模为一个有限厚度的界面,即子域重叠的区域。在该区域内,组分通过遵循特征力打开定律的界面结合力成对连接。在计算实验中,我们的模型捕获了界面强度和尺寸以及夹杂物体积分数对整体响应的影响。特别是,非定域性通过“更小的刚性”材料行为和界面的影响增加而表现出来,这突出了适当的非定域性界面模型的重要性。
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来源期刊
Forces in mechanics
Forces in mechanics Mechanics of Materials
CiteScore
3.50
自引率
0.00%
发文量
0
审稿时长
52 days
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