Modeling of cyclic creep in the finite strain range using a nested multiplicative split

TL;DR

This paper introduces a comprehensive finite strain cyclic creep model that incorporates damage evolution, large strain kinematics, and load reversal effects, validated through FEM simulations of aluminium alloy experiments.

Contribution

It presents a novel phenomenological model for cyclic creep at finite strains using a nested multiplicative split, coupled with damage evolution, and validated with experimental data.

Findings

Model accurately predicts cyclic creep behavior.

Numerical implementation in MSC.MARC shows good agreement with experiments.

The model captures all three stages of creep including transient effects.

Abstract

A new phenomenological model of cyclic creep is proposed which is suitable for applications involving finite creep deformations of the material. The model accounts for the the effect of the transient increase of the creep strain rate upon the load reversal. In order to extend the applicability range of the model, the creep process is fully coupled to the classical Kachanov-Rabonov damage evolution. As a result, the proposed model describes all the three stages of creep. Large strain kinematics is described in a geometrically exact manner using the assumption of a nested multiplicative split, originally proposed by Lion for finite strain plasticity. The model is thermodynamically admissible, objective, and w-invariant. Implicit time integration of the proposed evolution equations is discussed. The corresponding numerical algorithm is implemented into the commercial FEM code MSC.MARC. Using this code, the model is validated using real experimental data on cyclic torsion of a thick-walled tubular specimen made of the D16T aluminium alloy. The numerically computed stress distribution exhibits a "skeletal point" within the specimen.