Shape Memory Alloy
The Shape Memory Alloy feature is used to model stress-strain relationships which are nonlinear even at infinitesimal strains. This material model requires the Nonlinear Structural Materials Module.
By adding the following subnodes to the Shape Memory Alloy node you can incorporate other effects:
Note: Some options are only available with certain COMSOL products (see https://www.comsol.com/products/specifications/)
See also Shape Memory Alloy in the Structural Mechanics Theory chapter.
Model Inputs
From the Temperature T list, select an existing temperature variable from a heat transfer interface (for example, Temperature (ht)), if any temperature variables exist, or select User defined to enter a value or expression for the temperature.
If any material in the model has a temperature dependent mass density, and From material is selected for the density, the Volume reference temperature list will appear in the Model Input section. You can also select User defined to enter a value or expression for the reference temperature locally.
Default Model Inputs and Model Input in the COMSOL Multiphysics Reference Manual.
Coordinate System Selection
The Global coordinate system is selected by default. The Coordinate system list contains any additional coordinate systems that the model includes (except boundary coordinate systems). The coordinate system is used when stresses or strains are presented in a local system. The coordinate system must have orthonormal coordinate axes, and be defined in the material frame. Many of the possible subnodes inherit the coordinate system settings.
Shape Memory Alloy
Select a Shape memory alloy model from the list: Lagoudas or Souza-Auricchio.
Lagoudas
For Lagoudas, the Shape memory alloy reference temperature T0, the Poisson’s ratio ν, and the Density ρ are taken From material. For User defined enter other values or expressions.
For Austenite, select a material from the list. The Young’s modulus EA and the Heat capacity at constant pressure Cp,A are taken from the selected material. For Martensite, select a material from the list. The Young’s modulus EM and the Heat capacity at constant pressure Cp,M are taken from the selected material. For User defined enter other values or expressions.
Under Phase transformation parameters, select which Transformation parameters will describe the phase transitions: Temperature or Stress.
When Temperature is selected from the Transformation parameters list, enter the Martensite start temperature Ms, the Martensite finish temperature Mf, the Slope of martensite limit curve CM, the Austenite start temperature As, the Austenite finish temperature Af, and the Slope of austenite limit curve CA.
When Stress is selected from the Transformation parameters list, enter the Martensite start stress σMs, the Martensite finish stress σMf, the Slope of martensite limit curve CM, the Austenite start stress σAs, the Austenite finish stress σAf, the Slope of austenite limit curve CA, and the Measurement temperature Tσ.
Under the Maximum transformation strain list select Constant to directly enter the Maximum transformation strain εtr,max, or Exponential law to specify a stress-dependent maximum transformation strain. Under Exponential law, enter the Initial maximum transformation strain εtr,min, the Ultimate transformation strain εtr,sat, the Critical stress σcrit, and the Saturation exponent k. Enter the Calibration stress level σ*.
Under Phase transformation kinetics, select the Transformation function from the list: Quadratic, Cosine, Smooth or User defined.
For Smooth, enter the smoothing parameters η1, η2, η3, and η4.
For User defined enter the Yield stress σys, the Forward transformation law, and the Reverse transformation law.
Souza–Auricchio
For Souza-Auriccio the defaults for the Poisson’s ratio ν and Density ρ, are taken From material. For User defined enter other values or expressions.
For Austenite, select a material from the list. The Young’s modulus EA is taken from the selected material. For Martensite, select a material from the list. The Young’s modulus EM is taken from the selected material. For User defined enter other values or expressions.
Under Phase transformation parameters, enter the Reference temperature T*, the Slope of limit curve β, the Maximum transformation strain εtr,max, the Elastic domain radius σ0, the Hardening modulus Hk, and the Indicator function coefficient γ.
Initial Transformation State
For Laogudas model, enter the Initial martensite volume fraction, the Initial transformation strain tensor, the Initial martensite volume fraction at reverse point, and the Initial transformation strain tensor at reverse point.
For the Souza–Auricchio model, enter the Initial transformation strain tensor.
Geometric Nonlinearity
If a study step is geometrically nonlinear, the default behavior is to use a large strain formulation in all domains. There are, however, some cases when the use of a small strain formulation for a certain domain is needed. In those cases, select the Force linear strains check box. When selected, a small strain formulation is always used, independently of the setting in the study step. The check box is not selected by default to conserve the properties of the model.
When a geometrically nonlinear formulation is used, the elastic deformations used for computing the stresses can be obtained in two different ways if inelastic deformations are present: additive decomposition and multiplicative decomposition. The default is to use multiplicative decomposition. Select Additive strain decomposition to change to an assumption of additivity.
Energy Dissipation
You can select to compute and store various energy dissipation variables in a time dependent analysis. Doing so will add extra degrees of freedom to the model.
To display this section, click the Show More Options button () and select Advanced Physics Options in the Show More Options dialog box.
Select the Calculate dissipated energy check box as needed to compute the energy dissipated.
Location in User Interface
Context Menus
Ribbon
Physics tab with Solid Mechanics selected: