利用成分-体积均质化方法模拟陶瓷基复合材料的非线性行为

IF 3.4 3区材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

Mechanics of Materials Pub Date : 2024-10-16 DOI:10.1016/j.mechmat.2024.105179

Yuhan Zhao , Shaojing Dong , Xiuli Shen

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引用次数: 0

摘要

陶瓷基复合材料的非线性行为受到界面脱粘和纤维拉断的影响。本文提出了成分-体积均质化方法（CVHM），以取代传统的束均质化方法，从而利用有限元方法对编织结构中的跨元素脱粘行为进行建模。基于 CVHM，我们建立了纤维与基体之间相对运动的弹性关系，以及成分的弹性构成关系。此外，还开发了计算拉出和多轴载荷下纤维束微观局部应力的方法。基于上述研究，我们开发了一种使用 CVHM 分析编织复合材料应力-应变关系的程序。为了验证所提出的方法，我们估算了二维平织陶瓷基复合材料的非线性行为，并将结果与实验数据进行了比较。研究了界面剪切强度（ISS）和纤维极限拉伸强度（UTS）对非线性行为的影响。

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Nonlinear behavior simulation of ceramic-matrix composites using constituent-volume homogenization method

The nonlinear behavior of ceramic-matrix composites is affected by interface debonding and fiber pull-out. In this paper, we propose the constituent-volume homogenization method (CVHM) to replace the conventional bundle homogenization method, in order to model the behavior of trans-element debonding in woven structures using finite element method. Based on the CVHM, we establish the elastic relation of the relative motion between the fiber and the matrix, and the elastic constitutive relations for the constituents. Methods have also been developed to calculate the microscopic local stress of bundle under pull-out and multiaxial loads. Based on the above studies, we develop a procedure to analyze the stress-strain relation of braided composites using the CVHM. To validate the proposed method, we estimate the nonlinear behavior of the 2D plain-weave ceramic-matrix composites and compare the results with experimental data. The influence of interface shear strength (ISS) and the fiber ultimate tensile strength (UTS) on the nonlinear behavior is investigated.

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来源期刊

Mechanics of Materials 工程技术-材料科学：综合

CiteScore

7.60

自引率

5.10%

发文量

243

审稿时长

46 days

期刊介绍： Mechanics of Materials is a forum for original scientific research on the flow, fracture, and general constitutive behavior of geophysical, geotechnical and technological materials, with balanced coverage of advanced technological and natural materials, with balanced coverage of theoretical, experimental, and field investigations. Of special concern are macroscopic predictions based on microscopic models, identification of microscopic structures from limited overall macroscopic data, experimental and field results that lead to fundamental understanding of the behavior of materials, and coordinated experimental and analytical investigations that culminate in theories with predictive quality.