A compact cyclic plasticity model with parameter evolution

•Cyclic plasticity model with five basic parameters via potentials and internal variables.•Detailed development of plastic strain controlled by new shape parameter.•An evolution format is presented for the five model parameters.•Ability to accurately represent cyclic plasticity experiments is demons...

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Bibliographic Details
Published in:Mechanics of materials 2017-10, Vol.113, p.57-68
Main Authors: Krenk, S., Tidemann, L.
Format: Article
Language:English
Subjects:
Cyclic plasticity
Kinematic hardening
Material degradation
Model parameter evolution
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Summary:•Cyclic plasticity model with five basic parameters via potentials and internal variables.•Detailed development of plastic strain controlled by new shape parameter.•An evolution format is presented for the five model parameters.•Ability to accurately represent cyclic plasticity experiments is demonstrated. The paper presents a compact model for cyclic plasticity based on energy in terms of external and internal variables, and plastic yielding described by kinematic hardening and a flow potential with an additive term controlling the nonlinear cyclic hardening. The model is basically described by five parameters: external and internal stiffness, a yield stress and a limiting ultimate stress, and finally a parameter controlling the gradual development of plastic deformation. Calibration against numerous experimental results indicates that typically larger plastic strains develop than predicted by the Armstrong–Frederick model, contained as a special case of the present model for a particular choice of the shape parameter. In contrast to previous work, where shaping the stress-strain loops is derived from multiple internal stress states, this effect is here represented by a single parameter, and it is demonstrated that this simple formulation enables very accurate representation of experimental results. An extension of the theory to account for model parameter evolution effects, e.g. in the form of changing yield level, is included in the form of extended evolution equations for the model parameters. Finally, it is demonstrated that the model in combination with a simple parameter interpolation scheme enables representation of ratcheting effects.
ISSN:0167-6636
1872-7743
DOI:10.1016/j.mechmat.2017.07.012