Evolution of interfacial debonding of a unidirectional graphite/polyimide composite under off-axis loading

•A finite-volume micromechanics model was developed for composites with cohesive zone interface.•Inelastic behavior was characterized by assuming shear-dominated interfacial degradation as the cause of nonlinearity.•Homogenized response and concomitant localized stresses are calculated with little e...

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Bibliographic Details
Published inEngineering fracture mechanics Vol. 230; p. 106947
Main Authors Tu, Wenqiong, Chen, Qiang
Format Journal Article
LanguageEnglish
Published New York Elsevier Ltd 01.05.2020
Elsevier BV
Subjects
Algorithms
Brittleness
Cohesive zone model
Computer simulation
Damage
Evolution
Finite-volume homogenization
Graphite
In-situ properties
Interfacial debonding
Micromechanics
Model accuracy
Nonlinearity
Particle swarm optimization
Stress transfer
Viscoelasticity
Viscoplasticity
Micromechanics
In-situ properties
Cohesive zone model
Finite-volume homogenization
Interfacial debonding
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Summary:•A finite-volume micromechanics model was developed for composites with cohesive zone interface.•Inelastic behavior was characterized by assuming shear-dominated interfacial degradation as the cause of nonlinearity.•Homogenized response and concomitant localized stresses are calculated with little effort.•Physically realistic interfacial parameters were identified that produced good correlation with the experimental response. In this communication, the inelastic behavior of a unidirectional graphite/polyimide composite, whose constituent phases are both elastic and brittle, is characterized based on the hypothesis of shear-dominated fiber/matrix interfacial degradation as the primary cause of the observed nonlinearity. To accommodate a combined thermo-mechanical multiaxial loading in the off-axis specimens, the finite-volume direct averaging micromechanics (FVDAM) with damage evolution capability is established within a unified framework that uses discontinuity functions in conjunction with the bilinear cohesive-zone model. Meanwhile, the stand-alone FVDAM homogenization approach is combined with the particle swarm optimization algorithm to identify consistent in-situ fiber and matrix properties. The accuracy and efficiency of the present model with deduced properties are validated by comparing the simulated stress-strain responses against the experimental data in the literature with various fiber orientations and good agreements are obtained for all cases. Concomitant local stress distributions at different load steps are examined to demonstrate the stress transfer mechanism from the region of the damage interface to the surrounding matrix. For the first time, this study reveals that the off-axis dependent nonlinearity in this material system comprised of elastic fibers and brittle, linearly elastic matrix may be accurately captured using a damage evolution model rather than plasticity, viscoelasticity or viscoplasticity approaches typically employed for the matrix phase.
ISSN:0013-7944
1873-7315
DOI:10.1016/j.engfracmech.2020.106947