Journal ArticleDOI
BEM analysis of crack onset and propagation along fiber–matrix interface under transverse tension using a linear elastic–brittle interface model
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In this article, the behavior of the fiber-matrix interface under transverse tension is studied by means of a new linear elastic-brittle interface model, which is modeled by a continuous distribution of linear-elastic springs.Abstract:
The behavior of the fiber–matrix interface under transverse tension is studied by means of a new linear elastic–brittle interface model. Similar models, also called weak or imperfect interface models, are frequently applied to describe the behavior of adhesively bonded joints. The interface is modeled by a continuous distribution of linear-elastic springs which simulates the presence of a thin adhesive layer (interphase). In the present work a new linear elastic–brittle constitutive law for the continuous distribution of springs is introduced. In this law the normal and tangential stresses across the undamaged interface are, respectively, proportional to the relative normal and tangential displacements. This model not only allows for the study of crack growth but also for the study of crack onset. An important feature of this law is that it takes into account the variation of the fracture toughness with the fracture mode mixity of a crack growing along the interface between bonded solids, in agreement with previous experimental results. The present linear elastic–brittle interface model is implemented in a 2D boundary element method (BEM) code to carry out micromechanical analysis of the fiber–matrix interface failure in fiber-reinforced composite materials. It is considered that the behavior of the fiber–matrix interphase can be modeled by the present model although, strictly speaking, there is usually no intermediate material between fiber and matrix. A linear-elastic isotropic behavior of both fiber and matrix is assumed, the fiber being stiffer than the matrix. The failure mechanism of an isolated fiber under transverse tension, i.e., the onset and growth of the fiber–matrix interface crack, is studied. The present model shows that failure along the interface initiates with an abrupt onset of a partial debonding between the fiber and the matrix, caused by presence of the maximum radial stress at the interface, and this debonding further develops as a crack growing along the interface.read more
Citations
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Journal ArticleDOI
Recent Advances and Emerging Applications of the Boundary Element Method
Yijun Liu,Subrata Mukherjee,Naoshi Nishimura,Martin Schanz,Wenjing Ye,Alok Sutradhar,Ernian Pan,Ney Augusto Dumont,Attilio Frangi,Andrés Sáez +9 more
TL;DR: The paper aims to review the major research achievements in the last decade, the current status, and the future directions of the BEM in the next decade.
Journal ArticleDOI
Finite Fracture Mechanics at elastic interfaces
TL;DR: In this article, the authors provided a method to determine the load causing delamination along an interface in a composite structure based on elastic interface model, according to which the interface is equivalent to a bed of linear elastic springs, and on Finite Fracture Mechanics, a crack propagation criterion recently proposed for homogeneous structures.
Journal ArticleDOI
Crack onset and growth at the fibre–matrix interface under a remote biaxial transverse load. Application of a coupled stress and energy criterion
Vladislav Mantic,I.G. García +1 more
TL;DR: In this paper, a theoretical model for prediction of the critical load generating a crack onset at the fibre-matrix interface under a remote biaxial transverse load is presented, focused on the tension dominated failure.
Journal ArticleDOI
A nonlinear finite thickness cohesive interface element for modeling delamination in fibre-reinforced composite laminates
TL;DR: In this paper, a nonlinear finite thickness cohesive interface model for delamination analysis of fiber-reinforced composite laminates relying on the solid shell concept is proposed. And the inelastic material behavior of the interface is modeled using two standard nonlinear decohesion laws: (i) an exponential-based and (ii) a polynomial-based interface laws.
Journal ArticleDOI
Fiber-size effects on the onset of fiber–matrix debonding under transverse tension: A comparison between cohesive zone and finite fracture mechanics models
TL;DR: In this article, the authors compared the critical load for debond onset obtained by a Cohesive Zone Model combined with contact mechanics and by a Finite Fracture Mechanics model based on a coupled stress and energy criterion.
References
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Journal ArticleDOI
A Continuum Model for Void Nucleation by Inclusion Debonding
TL;DR: In this paper, a boundary value problem simulating a periodic array of rigid spherical inclusions in an isotropically hardening elastic-viscoplastic matrix is analyzed and the effect of the triaxiality of the imposed stress state on nucleation is studied and the numerical results are related to the description of void nucleation within a phenomenological constitutive framework.
A continuum model for void nucleation by inclusion debonding
TL;DR: In this article, a boundary value problem simulating a periodic array of rigid spherical inclusions in an isotropically hardening elastic-viscoplastic matrix is analyzed and the effect of the triaxiality of the imposed stress state on nucleation is studied and the numerical results are related to the description of void nucleation within a phenomenological constitutive framework.