Journal of Theoretical
and Applied Mechanics
55, 4, pp. 1355-1368, Warsaw 2017
DOI: 10.15632/jtam-pl.55.4.1355
and Applied Mechanics
55, 4, pp. 1355-1368, Warsaw 2017
DOI: 10.15632/jtam-pl.55.4.1355
Finite element analysis of a superelastic shape memory alloy considering the effect of plasticity
In the present study, a shape memory alloy (SMA) phenomenological constitutive model is
proposed that is capable of describing SMA superelastic behavior and the plasticity effect.
The phase transformation constitutive model, by using strain and temperature as control
variables to judge the phase transformation points in order to avoid the complexity of trans-
formation correction, incorporates plasticity described by the von Mises isotropic hardening
model. Further, the proposed model is implemented into the finite element package ANSYS
by the user subroutine USERMAT. The results produced by the proposed model of simu-
lated superelastic and plasticity behavior are compared with experimental data taken from
the literature.
proposed that is capable of describing SMA superelastic behavior and the plasticity effect.
The phase transformation constitutive model, by using strain and temperature as control
variables to judge the phase transformation points in order to avoid the complexity of trans-
formation correction, incorporates plasticity described by the von Mises isotropic hardening
model. Further, the proposed model is implemented into the finite element package ANSYS
by the user subroutine USERMAT. The results produced by the proposed model of simu-
lated superelastic and plasticity behavior are compared with experimental data taken from
the literature.
Keywords: SMAs, superelasticity, plasticity, constitutive law, finite element analysis