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Phase-field modeling of fracture in viscoelastic–viscoplastic thermoset nanocomposites under cyclic and monolithic loading

Behrouz Arash, Shadab Zakavati, Betim Bahtiri, Maximilian Jux, Raimund Rolfes

2024Engineering With Computers9 citationsDOIOpen Access PDF

Abstract

Abstract In this study, a finite deformation phase-field formulation is developed to investigate the effect of hygrothermal conditions on the viscoelastic–viscoplastic fracture behavior of epoxy nanocomposites under cyclic and monolithic loading. The formulation incorporates a definition of the Helmholtz free energy, which considers the effect of nanoparticles, moisture content, and temperature. The free energy is additively decomposed into a deviatoric equilibrium, a deviatoric non-equilibrium, and a volumetric contribution. The proposed derivation offers a realistic modeling of damage and viscoplasticity mechanisms in the nanocomposites by coupling the phase-field damage model and a viscoelastic–viscoplastic model. Numerical simulations are conducted to study the cyclic force–displacement response of both dry and saturated boehmite nanoparticle (BNP)/epoxy samples, considering BNP contents and temperature. Comparing numerical results with experimental data shows good agreement at various BNP contents. In addition, the predictive capability of the phase-field model is evaluated through simulations of notched nanocomposite plates subjected to monolithic tensile and shear loading.

Topics & Concepts

Thermosetting polymerViscoplasticityViscoelasticityMaterials scienceComposite materialNanocompositeFracture (geology)Field (mathematics)Structural engineeringFinite element methodConstitutive equationMathematicsEngineeringPure mathematicsNumerical methods in engineeringComposite Material MechanicsMaterial Properties and Failure Mechanisms
Phase-field modeling of fracture in viscoelastic–viscoplastic thermoset nanocomposites under cyclic and monolithic loading | Litcius