A damage mechanics model for quasi brittle materials based on the structured deformation theory

TL;DR

This paper develops a damage mechanics model for quasi-brittle materials using structured deformation theory within thermodynamics, incorporating crack behavior and yielding criteria to predict material response.

Contribution

It introduces a novel damage model based on structured deformation theory that accounts for crack shape, friction, and cohesion, improving prediction accuracy for quasi-brittle materials.

Findings

Model aligns with Kupfer's concrete database

Predicts crack orientation and damage evolution

Incorporates Mohr-Coulomb yield surface

Abstract

The structured deformation theory is used within the thermodynamics of irreversible processes framework in order to build a damage model relevant for quasi-brittle materials. The cracks are supposed smeared in the body and their shape is assumed to be sinusoidal. The convex of elasticity supposes a limitation of the thermodynamic force associated to the relative sliding of the crack lips. This limitation consists of both some equivalent to the Coulomb's friction and a cohesive force issued from the Barenblatt approach. This leads to an initial yield surface that can be expressed as the Mohr-Coulomb criterion, known to be relevant for such materials in term of initial yield surface and prediction of the crack orientation. The evolution law introduces an hardening and softening function that, combined to the rest of the framework, allows the description of the stress to strain evolution. The results are identified and compared to the Kupfer's database on concrete.