swh:1:snp:f521c49ab17ef7db6ec70b2430e1ed203f50383f
Tip revision: d1f8740e1b116bc0738b9922552bad6c092f56a3 authored by Lars Bilke on 28 June 2021, 07:20:52 UTC
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Tip revision: d1f8740
CreateThermoMechanicalPhaseFieldProcess.cpp
/**
* \file
* \copyright
* Copyright (c) 2012-2021, OpenGeoSys Community (http://www.opengeosys.org)
* Distributed under a Modified BSD License.
* See accompanying file LICENSE.txt or
* http://www.opengeosys.org/project/license
*
*/
#include "CreateThermoMechanicalPhaseFieldProcess.h"
#include <cassert>
#include "MaterialLib/SolidModels/CreateConstitutiveRelation.h"
#include "MaterialLib/SolidModels/MechanicsBase.h"
#include "ParameterLib/Utils.h"
#include "ProcessLib/Output/CreateSecondaryVariables.h"
#include "ProcessLib/Utils/ProcessUtils.h"
#include "ThermoMechanicalPhaseFieldProcess.h"
#include "ThermoMechanicalPhaseFieldProcessData.h"
namespace ProcessLib
{
namespace ThermoMechanicalPhaseField
{
template <int DisplacementDim>
std::unique_ptr<Process> createThermoMechanicalPhaseFieldProcess(
std::string name,
MeshLib::Mesh& mesh,
std::unique_ptr<ProcessLib::AbstractJacobianAssembler>&& jacobian_assembler,
std::vector<ProcessVariable> const& variables,
std::vector<std::unique_ptr<ParameterLib::ParameterBase>> const& parameters,
std::optional<ParameterLib::CoordinateSystem> const&
local_coordinate_system,
unsigned const integration_order,
BaseLib::ConfigTree const& config)
{
//! \ogs_file_param{prj__processes__process__type}
config.checkConfigParameter("type", "THERMO_MECHANICAL_PHASE_FIELD");
DBUG("Create ThermoMechanicalPhaseFieldProcess.");
INFO(
"Solve the coupling with the staggered scheme,"
"which is the only option for TM-Phasefield in the current code");
// Process variable.
//! \ogs_file_param{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__process_variables}
auto const pv_config = config.getConfigSubtree("process_variables");
std::vector<std::vector<std::reference_wrapper<ProcessVariable>>>
process_variables;
int heat_conduction_process_id = 0;
int mechanics_related_process_id = 1;
int phase_field_process_id = 2;
auto process_variable_T = findProcessVariables(
variables, pv_config,
{//! \ogs_file_param_special{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__process_variables__temperature}
"temperature"});
process_variables.push_back(std::move(process_variable_T));
ProcessVariable* variable_T =
&process_variables[process_variables.size() - 1][0].get();
auto process_variable_u = findProcessVariables(
variables, pv_config,
{//! \ogs_file_param_special{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__process_variables__displacement}
"displacement"});
process_variables.push_back(std::move(process_variable_u));
ProcessVariable* variable_u =
&process_variables[process_variables.size() - 1][0].get();
auto process_variable_ph = findProcessVariables(
variables, pv_config,
{//! \ogs_file_param_special{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__process_variables__phasefield}
"phasefield"});
process_variables.push_back(std::move(process_variable_ph));
ProcessVariable* variable_ph =
&process_variables[process_variables.size() - 1][0].get();
DBUG("Associate displacement with process variable '{:s}'.",
variable_u->getName());
if (variable_u->getNumberOfGlobalComponents() != DisplacementDim)
{
OGS_FATAL(
"Number of components of the process variable '{:s}' is different "
"from the displacement dimension: got {:d}, expected {:d}",
variable_u->getName(),
variable_u->getNumberOfGlobalComponents(),
DisplacementDim);
}
DBUG("Associate phase field with process variable '{:s}'.",
variable_ph->getName());
if (variable_ph->getNumberOfGlobalComponents() != 1)
{
OGS_FATAL(
"Phasefield process variable '{:s}' is not a scalar variable but "
"has {:d} components.",
variable_ph->getName(),
variable_ph->getNumberOfGlobalComponents());
}
DBUG("Associate temperature with process variable '{:s}'.",
variable_T->getName());
if (variable_T->getNumberOfGlobalComponents() != 1)
{
OGS_FATAL(
"Temperature process variable '{:s}' is not a scalar variable but "
"has {:d} components.",
variable_T->getName(),
variable_T->getNumberOfGlobalComponents());
}
auto solid_constitutive_relations =
MaterialLib::Solids::createConstitutiveRelations<DisplacementDim>(
parameters, local_coordinate_system, config);
auto const phasefield_parameters_config =
//! \ogs_file_param{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__phasefield_parameters}
config.getConfigSubtree("phasefield_parameters");
auto const thermal_parameters_config =
//! \ogs_file_param{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__thermal_parameters}
config.getConfigSubtree("thermal_parameters");
// Residual stiffness
auto const& residual_stiffness = ParameterLib::findParameter<double>(
phasefield_parameters_config,
//! \ogs_file_param_special{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__phasefield_parameters__residual_stiffness}
"residual_stiffness", parameters, 1, &mesh);
DBUG("Use '{:s}' as residual stiffness.", residual_stiffness.name);
// Crack resistance
auto const& crack_resistance = ParameterLib::findParameter<double>(
phasefield_parameters_config,
//! \ogs_file_param_special{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__phasefield_parameters__crack_resistance}
"crack_resistance", parameters, 1, &mesh);
DBUG("Use '{:s}' as crack resistance.", crack_resistance.name);
// Crack length scale
auto const& crack_length_scale = ParameterLib::findParameter<double>(
phasefield_parameters_config,
//! \ogs_file_param_special{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__phasefield_parameters__crack_length_scale}
"crack_length_scale", parameters, 1, &mesh);
DBUG("Use '{:s}' as crack length scale.", crack_length_scale.name);
// Kinetic coefficient
auto const& kinetic_coefficient = ParameterLib::findParameter<double>(
phasefield_parameters_config,
//! \ogs_file_param_special{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__phasefield_parameters__kinetic_coefficient}
"kinetic_coefficient", parameters, 1, &mesh);
DBUG("Use '{:s}' as kinetic coefficient.", kinetic_coefficient.name);
// Solid density
auto const& solid_density = ParameterLib::findParameter<double>(
config,
//! \ogs_file_param_special{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__reference_solid_density}
"solid_density", parameters, 1, &mesh);
DBUG("Use '{:s}' as solid density parameter.", solid_density.name);
// Linear thermal expansion coefficient
auto const& linear_thermal_expansion_coefficient =
ParameterLib::findParameter<double>(
thermal_parameters_config,
//! \ogs_file_param_special{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__thermal_parameters__linear_thermal_expansion_coefficient}
"linear_thermal_expansion_coefficient", parameters, 1, &mesh);
DBUG("Use '{:s}' as linear thermal expansion coefficient.",
linear_thermal_expansion_coefficient.name);
// Specific heat capacity
auto const& specific_heat_capacity = ParameterLib::findParameter<double>(
thermal_parameters_config,
//! \ogs_file_param_special{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__thermal_parameters__specific_heat_capacity}
"specific_heat_capacity", parameters, 1, &mesh);
DBUG("Use '{:s}' as specific heat capacity.", specific_heat_capacity.name);
// Thermal conductivity
auto const& thermal_conductivity = ParameterLib::findParameter<double>(
thermal_parameters_config,
//! \ogs_file_param_special{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__thermal_parameters__thermal_conductivity}
"thermal_conductivity", parameters, 1, &mesh);
DBUG("Use '{:s}' as thermal conductivity parameter.",
thermal_conductivity.name);
// Residual thermal conductivity
auto const& residual_thermal_conductivity = ParameterLib::findParameter<
double>(
thermal_parameters_config,
//! \ogs_file_param_special{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__thermal_parameters__residual_thermal_conductivity}
"residual_thermal_conductivity", parameters, 1, &mesh);
DBUG("Use '{:s}' as residual thermal conductivity parameter.",
residual_thermal_conductivity.name);
// Reference temperature
const auto reference_temperature =
//! \ogs_file_param{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__reference_temperature}
config.getConfigParameter<double>("reference_temperature");
// Specific body force
Eigen::Matrix<double, DisplacementDim, 1> specific_body_force;
{
std::vector<double> const b =
//! \ogs_file_param{prj__processes__process__THERMO_MECHANICAL_PHASE_FIELD__specific_body_force}
config.getConfigParameter<std::vector<double>>(
"specific_body_force");
if (specific_body_force.size() != DisplacementDim)
{
OGS_FATAL(
"The size of the specific body force vector does not match the "
"displacement dimension. Vector size is {:d}, displacement "
"dimension is {:d}",
specific_body_force.size(), DisplacementDim);
}
std::copy_n(b.data(), b.size(), specific_body_force.data());
}
ThermoMechanicalPhaseFieldProcessData<DisplacementDim> process_data{
materialIDs(mesh),
std::move(solid_constitutive_relations),
residual_stiffness,
crack_resistance,
crack_length_scale,
kinetic_coefficient,
solid_density,
linear_thermal_expansion_coefficient,
specific_heat_capacity,
thermal_conductivity,
residual_thermal_conductivity,
specific_body_force,
reference_temperature};
SecondaryVariableCollection secondary_variables;
ProcessLib::createSecondaryVariables(config, secondary_variables);
return std::make_unique<ThermoMechanicalPhaseFieldProcess<DisplacementDim>>(
std::move(name), mesh, std::move(jacobian_assembler), parameters,
integration_order, std::move(process_variables),
std::move(process_data), std::move(secondary_variables),
mechanics_related_process_id, phase_field_process_id,
heat_conduction_process_id);
}
template std::unique_ptr<Process> createThermoMechanicalPhaseFieldProcess<2>(
std::string name,
MeshLib::Mesh& mesh,
std::unique_ptr<ProcessLib::AbstractJacobianAssembler>&& jacobian_assembler,
std::vector<ProcessVariable> const& variables,
std::vector<std::unique_ptr<ParameterLib::ParameterBase>> const& parameters,
std::optional<ParameterLib::CoordinateSystem> const&
local_coordinate_system,
unsigned const integration_order,
BaseLib::ConfigTree const& config);
template std::unique_ptr<Process> createThermoMechanicalPhaseFieldProcess<3>(
std::string name,
MeshLib::Mesh& mesh,
std::unique_ptr<ProcessLib::AbstractJacobianAssembler>&& jacobian_assembler,
std::vector<ProcessVariable> const& variables,
std::vector<std::unique_ptr<ParameterLib::ParameterBase>> const& parameters,
std::optional<ParameterLib::CoordinateSystem> const&
local_coordinate_system,
unsigned const integration_order,
BaseLib::ConfigTree const& config);
} // namespace ThermoMechanicalPhaseField
} // namespace ProcessLib