UVCuniaxial (Updated Voce-Chaboche)

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This command is used to construct an Updated Voce-Chaboche (UVC) material for uniaxial stress states. This material is a refined version of the classic nonlinear isotropic/kinematic hardening material model based on the Voce isotropic hardening law and the Chaboche kinematic hardening law. The UVC model contains an updated isotropic hardening law, with parameter constraints, to simulate the permanent decrease in yield stress with initial plastic loading associated with the discontinuous yielding phenomenon in mild steels. Details regarding the model, and implementation, can be found in the cited references at the end.

uniaxialMaterial UVCuniaxial $matTag $E $fy $QInf $b $DInf $a $N $C1 $gamma1 <$C2 $gamma2 $C3 $gamma3 … $C8 $gamma8>

$matTag Integer tag identifying the material.
$E Elastic modulus of the steel material.
$fy Initial yield stress of the steel material.
$QInf Maximum increase in yield stress due to cyclic hardening (isotropic hardening).
$b Isotropic hardening saturation rate, b > 0.
$DInf Saturation rate of yield stress difference, a > 0. If DInf == 0, then a is arbitrary (but still a > 0).
$a Employed adaptive numerical algorithm (default value NM = 1; 1 = Dormand-Prince54, 2=adaptive finite difference)
$N Number of backstresses to define, N >= 1.
$C1 Kinematic hardening parameter associated with backstress component 1.
$gamma1 Saturation rate of kinematic hardening associated with backstress component 1.
<$C2 $gamma2 $C3 $gamma3 … $C8 $gamma8> Additional backstress parameters, up to 8 may be specified. If C is specified, then the corresponding gamma must also be specified. Note that only the first N backstresses will be read by the parser.

Examples:

1. Input parameters:

References:

[1] Hartloper, A. R., de Castro e Sousa A., and Lignos D.G. (2019). "Sensitivity of Simulated Steel Column Instabilities to Plasticity Model Assumptions". 12th Canadian Conference on Earthquake Engineering, Quebec City, QC, Canada.
[2] Hartloper, A. R., de Castro e Sousa A., and Lignos D.G. (2019). "A Nonlinear Isotropic/Kinematic Hardening Model for Materials with Discontinuous Yielding". Report No. 271062, Resilient Steel Structures Laboratory (RESSLab), EPFL, Lausanne, Switzerland.