Non-affine fiber reorientation in finite inelasticity

TL;DR

This paper develops a thermodynamically consistent model for anisotropic soft materials with fibers, capturing large inelastic deformations and fiber reorientation, addressing limitations of existing models regarding natural state uniqueness.

Contribution

It introduces a novel inelastic model that accounts for fiber reorientation and natural state evolution, ensuring frame-indifference and thermodynamic consistency.

Findings

Model captures fiber reorientation during inelastic deformation

Incorporates flow rules for viscoelasticity and growth

Addresses natural state non-uniqueness in fiber-reinforced materials

Abstract

This paper introduces a model for the mechanical response of anisotropic soft materials undergoing large inelastic deformations. The composite is constituted by a soft isotropic matrix reinforced with stiff fibres, that can evolve independently from each other. The constitutive equations are provided in terms of the free energy density and the dissipation density which are both required to be thermodynamically consistent and structurally frame-indifferent, i.e., they must be independent of a rotation overimposed on the natural state. This is in contrast to many of the currently used inelastic models for soft fiber-reinforced materials which do not deal with the lack of uniqueness of the natural state. A constraint between the inelastic spin of the matrix and the rotation spin of the fibre is introduced to fully determined the natural state. The resulting flow rules of the inelastic processes incorporate some typical scenarios including viscoelasticity and growth.