Abstract
A constitutive law was developed based on the evolutionary yield function to account for the evolution of anisotropy induced by the plastic deformation. For the effective description of anisotropy, the yield stress function and plastic potential were separately defined based on the non-associated flow rule. In particular, for the description of the equivalent status, the accumulated plastic work was employed as an alternative to the accumulated plastic strain. Numerical formulations based on the plastic work were also derived in case the hardening rule, as well as the evolution of the plastic potential and yield stress function, were defined in terms of the plastic work. The developed constitutive law was characterized using the mechanical properties of the multi-phase BAO QP980 steel and niobium sheets at room temperature. From the uniaxial tension tests and the balanced biaxial tension test, separate sets of anisotropic coefficients for each of the plastic potential and yield stress functions were obtained as a function of the plastic work. By comparing with non-evolving yield functions, the importance of the developed constitutive law to properly describe the evolution of the plastic potential and yield function were validated.
Highlights
New sheet metal alloys are continuously being developed to meet the mechanical properties required for various industries
A constitutive law to describe the evolution of anisotropy induced by the plastic deformation was developed developed based on the evolutionary yield function
A constitutive law was developed based on the evolutionary yield function to account for the evolution of anisotropy induced by the plastic deformation
Summary
New sheet metal alloys are continuously being developed to meet the mechanical properties required for various industries. Be used in the non-associated flow rule to define the plastic potential and the yield stress function. Comparison of the calculated strain-rate potentials based on crystal plasticity simulations and isotropic version of the Yld2000-2D function. The evolution of the yield stress function was defined using a less complicated model the evolution of the yield stress function was defined using a less complicated model and independent of of the plastic potential, improved improved accuracy accuracy in in the prediction of the uniaxial tension independent stress–strain curves was observed compared with the associated flow flow rule rule models. For. For effective description, the deformation plastic potential as well as their evolutions were were separately defined based yield stress stress function functionand andthe the plastic potential as well as their evolutions separately defined on the on non-associated flow rule.
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