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A micromechanics based elasto-plastic damage model for unidirectional composites under off-axis tensile loads

Yanchao Wang, Dong Chen, Nengwen Li, Huanquan Yuan, Zengyu Zhu, Yongxiang Li, Zheng‐Ming Huang

2020Scientific Reports14 citationsDOIOpen Access PDF

Abstract

Nonlinear properties of composite materials are essential for their engineering application. In this work, a three-phase micromechanics bridging model is employed to evaluate the nonlinear behavior of a composite from properties of fiber, matrix and interphase. It is assumed that the matrix elastoplasticity and the interface damage are two major sources of the nonlinearity. The former is described by the J2 flow rule. The latter is approximated by an interphase with stiffness degradation. For an interphase, an equivalent damage stress is introduced to account for the effect of normal and shear stress on the interface damage growth. Further, an explicit empirical equation is developed to relate the equivalent damage stress and the stiffness degradation of an interphase. The present elasto-plastic damage model is validated by comparing with experimental data of a series of composites under off-axis tensile loads.

Topics & Concepts

MicromechanicsInterphaseMaterials scienceComposite materialUltimate tensile strengthStiffnessComposite numberNonlinear systemPhysicsQuantum mechanicsGeneticsBiologyMechanical Behavior of CompositesComposite Material MechanicsNumerical methods in engineering