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SolidModel.C File Reference

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Functions

template<>
InputParameters validParams< SolidModel > ()
 

Function Documentation

template<>
InputParameters validParams< SolidModel > ( )

Definition at line 27 of file SolidModel.C.

Referenced by validParams< AbaqusCreepMaterial >(), validParams< AbaqusUmatMaterial >(), validParams< CLSHPlasticMaterial >(), validParams< Elastic >(), validParams< LinearStrainHardening >(), validParams< PLC_LSH >(), and validParams< PowerLawCreep >().

28 {
29  MooseEnum formulation(
30  "Nonlinear3D NonlinearRZ AxisymmetricRZ SphericalR Linear PlaneStrain NonlinearPlaneStrain");
31  MooseEnum compute_method("NoShearRetention ShearRetention");
32 
33  InputParameters params = validParams<Material>();
34  params.addParam<std::string>(
35  "appended_property_name", "", "Name appended to material properties to make them unique");
36  params.addParam<Real>("bulk_modulus", "The bulk modulus for the material.");
37  params.addParam<Real>("lambda", "Lame's first parameter for the material.");
38  params.addParam<Real>("poissons_ratio", "Poisson's ratio for the material.");
39  params.addParam<FunctionName>("poissons_ratio_function",
40  "Poisson's ratio as a function of temperature.");
41  params.addParam<Real>("shear_modulus", "The shear modulus of the material.");
42  params.addParam<Real>("youngs_modulus", "Young's modulus of the material.");
43  params.addParam<FunctionName>("youngs_modulus_function",
44  "Young's modulus as a function of temperature.");
45  params.addParam<Real>("thermal_expansion", "The thermal expansion coefficient.");
46  params.addParam<FunctionName>("thermal_expansion_function",
47  "Thermal expansion coefficient as a function of temperature.");
48  params.addCoupledVar("temp", "Coupled Temperature");
49  params.addParam<Real>(
50  "stress_free_temperature",
51  "The stress-free temperature. If not specified, the initial temperature is used.");
52  params.addParam<Real>("thermal_expansion_reference_temperature",
53  "Reference temperature for mean thermal expansion function.");
54  MooseEnum cte_function_type("instantaneous mean");
55  params.addParam<MooseEnum>("thermal_expansion_function_type",
56  cte_function_type,
57  "Type of thermal expansion function. Choices are: " +
58  cte_function_type.getRawNames());
59  params.addParam<std::vector<Real>>("initial_stress",
60  "The initial stress tensor (xx, yy, zz, xy, yz, zx)");
61  params.addParam<std::string>(
62  "cracking_release",
63  "abrupt",
64  "The cracking release type. Choices are abrupt (default) and exponential.");
65  params.addParam<Real>("cracking_stress",
66  0.0,
67  "The stress threshold beyond which cracking occurs. Must be positive.");
68  params.addParam<Real>(
69  "cracking_residual_stress",
70  0.0,
71  "The fraction of the cracking stress allowed to be maintained following a crack.");
72  params.addParam<Real>("cracking_beta", 1.0, "The coefficient used in the exponetional model.");
73  params.addParam<MooseEnum>(
74  "compute_method", compute_method, "The method used in the stress calculation.");
75  params.addParam<FunctionName>(
76  "cracking_stress_function", "", "The cracking stress as a function of time and location");
77  params.addParam<std::vector<unsigned int>>(
78  "active_crack_planes", "Planes on which cracks are allowed (0,1,2 -> x,z,theta in RZ)");
79  params.addParam<unsigned int>(
80  "max_cracks", 3, "The maximum number of cracks allowed at a material point.");
81  params.addParam<Real>("cracking_neg_fraction",
82  "The fraction of the cracking strain at which a "
83  "transitition begins during decreasing strain to "
84  "the original stiffness.");
85  params.addParam<MooseEnum>("formulation",
86  formulation,
87  "Element formulation. Choices are: " + formulation.getRawNames());
88  params.addParam<std::string>("increment_calculation",
89  "RashidApprox",
90  "The algorithm to use when computing the "
91  "incremental strain and rotation (RashidApprox or "
92  "Eigen). For use with Nonlinear3D/RZ formulation.");
93  params.addParam<bool>("large_strain",
94  false,
95  "Whether to include large strain terms in "
96  "AxisymmetricRZ, SphericalR, and PlaneStrain "
97  "formulations.");
98  params.addParam<bool>("compute_JIntegral", false, "Whether to compute the J Integral.");
99  params.addParam<bool>(
100  "compute_InteractionIntegral", false, "Whether to compute the Interaction Integral.");
101  params.addParam<bool>("store_stress_older",
102  false,
103  "Parameter which indicates whether the older "
104  "stress state, required for HHT time "
105  "integration, needs to be stored");
106  params.addCoupledVar("disp_r", "The r displacement");
107  params.addCoupledVar("disp_x", "The x displacement");
108  params.addCoupledVar("disp_y", "The y displacement");
109  params.addCoupledVar("disp_z", "The z displacement");
110  params.addCoupledVar("strain_zz", "The zz strain");
111  params.addCoupledVar("scalar_strain_zz", "The zz strain (scalar variable)");
112  params.addParam<std::vector<std::string>>(
113  "dep_matl_props", "Names of material properties this material depends on.");
114  params.addParam<std::string>("constitutive_model", "ConstitutiveModel to use (optional)");
115  params.addParam<bool>("volumetric_locking_correction",
116  true,
117  "Set to false to turn off volumetric locking correction");
118  return params;
119 }