OGS
Column.prj
<
OpenGeoSysProject
>
<
meshes
>
<
mesh
>column_domain.vtu</mesh>
<
mesh
>column_physical_group_top.vtu</mesh>
<
mesh
>column_physical_group_right.vtu</mesh>
<
mesh
>column_physical_group_bottom.vtu</mesh>
<
mesh
>column_physical_group_left.vtu</mesh>
</meshes>
<
processes
>
<
process
>
<
name
>THERMO_HYDRO_MECHANICS</name>
<
type
>
THERMO_HYDRO_MECHANICS
</type>
<
integration_order
>4</integration_order>
<constitutive_relation>
<type>
LinearElasticIsotropic
</type>
<
youngs_modulus
>E</youngs_modulus>
<
poissons_ratio
>nu</poissons_ratio>
</constitutive_relation>
<
process_variables
>
<
displacement
>displacement</displacement>
<
pressure
>pressure</pressure>
<
temperature
>temperature</temperature>
</process_variables>
<
secondary_variables
>
<
secondary_variable
internal_name
="sigma"
output_name
="sigma"
type
="static" />
<
secondary_variable
internal_name
="epsilon"
output_name
="epsilon"
type
="static" />
</secondary_variables>
<
specific_body_force
>0 0</specific_body_force>
</process>
</processes>
<
media
>
<
medium
id
="0">
<
phases
>
<
phase
>
<
type
>
AqueousLiquid
</type>
<
properties
>
<
property
>
<
name
>specific_heat_capacity</name>
<
type
>
Constant
</type>
<
value
>4186.0</value>
</property>
<
property
>
<
name
>thermal_conductivity</name>
<
type
>
Constant
</type>
<
value
>0.582</value>
</property>
<
property
>
<
name
>density</name>
<
type
>
Function
</type>
<
value
>
<
expression
>1000</expression>
</value>
<
dvalue
>
<
variable_name
>temperature</variable_name>
<
expression
>-3.0e-4*1000</expression>
</dvalue>
<
dvalue
>
<
variable_name
>liquid_phase_pressure</variable_name>
<
expression
>0.303e-9*1000</expression>
</dvalue>
</property>
<
property
>
<
name
>viscosity</name>
<
type
>
Constant
</type>
<
value
>1.e-3</value>
</property>
</properties>
</phase>
<
phase
>
<
type
>
Solid
</type>
<
properties
>
<
property
>
<
name
>thermal_osmosis_coefficient</name>
<
type
>
Constant
</type>
<
value
>2.7e-10 0 0 2.7e-10</value>
</property>
<
property
>
<
name
>density</name>
<
type
>
Constant
</type>
<
value
>2610</value>
</property>
<
property
>
<
name
>thermal_conductivity</name>
<
type
>
Constant
</type>
<
value
>3.29</value>
</property>
<
property
>
<
name
>specific_heat_capacity</name>
<
type
>
Constant
</type>
<
value
>937</value>
</property>
<
property
>
<
name
>thermal_expansivity</name>
<
type
>
Constant
</type>
<
value
>1.0e-6</value>
</property>
</properties>
</phase>
</phases>
<
properties
>
<
property
>
<
name
>permeability</name>
<
type
>
Constant
</type>
<
value
>5e-17 0 0 5e-17</value>
</property>
<
property
>
<
name
>porosity</name>
<
type
>
Constant
</type>
<
value
>0.375</value>
</property>
<
property
>
<
name
>biot_coefficient</name>
<
type
>
Constant
</type>
<
value
>0.9999728813559</value>
</property>
<
property
>
<
name
>thermal_conductivity</name>
<
type
>
EffectiveThermalConductivityPorosityMixing
</type>
</property>
</properties>
</medium>
</media>
<
time_loop
>
<
processes
>
<
process
ref
="THERMO_HYDRO_MECHANICS">
<
nonlinear_solver
>basic_newton</nonlinear_solver>
<
convergence_criterion
>
<
type
>
PerComponentDeltaX
</type>
<
norm_type
>NORM2</norm_type>
<
abstols
>1e-5 1e-5 1e-5 1e-5</abstols>
</convergence_criterion>
<
time_discretization
>
<
type
>
BackwardEuler
</type>
</time_discretization>
<
time_stepping
>
<
type
>
FixedTimeStepping
</type>
<
t_initial
>0</t_initial>
<
t_end
>7.2E6</t_end>
<
timesteps
>
<
pair
>
<
repeat
>5</repeat>
<
delta_t
>3600</delta_t>
</pair>
<
pair
>
<
repeat
>10</repeat>
<
delta_t
>7200</delta_t>
</pair>
<
pair
>
<
repeat
>1</repeat>
<
delta_t
>10000</delta_t>
</pair>
<
pair
>
<
repeat
>10</repeat>
<
delta_t
>10000</delta_t>
</pair>
<
pair
>
<
repeat
>10</repeat>
<
delta_t
>50000</delta_t>
</pair>
<
pair
>
<
repeat
>15</repeat>
<
delta_t
>100000</delta_t>
</pair>
<
pair
>
<
repeat
>9</repeat>
<
delta_t
>200000</delta_t>
</pair>
<
pair
>
<
repeat
>10</repeat>
<
delta_t
>400000</delta_t>
</pair>
<
pair
>
<
repeat
>4</repeat>
<
delta_t
>500000</delta_t>
</pair>
<
pair
>
<
repeat
>10</repeat>
<
delta_t
>1000000</delta_t>
</pair>
<
pair
>
<
repeat
>5</repeat>
<
delta_t
>2000000</delta_t>
</pair>
<
pair
>
<
repeat
>25</repeat>
<
delta_t
>2000000</delta_t>
</pair>
<
pair
>
<
repeat
>10</repeat>
<
delta_t
>10000000</delta_t>
</pair>
</timesteps>
</time_stepping>
</process>
</processes>
<
output
>
<
type
>
VTK
</type>
<
prefix
>Column</prefix>
<
timesteps
>
<
pair
>
<
repeat
>1</repeat>
<
each_steps
>68</each_steps>
</pair>
</timesteps>
<
variables
>
<
variable
>displacement</variable>
<
variable
>pressure</variable>
<
variable
>temperature</variable>
<
variable
>sigma</variable>
<
variable
>epsilon</variable>
</variables>
</output>
</time_loop>
<
parameters
>
<
parameter
>
<
name
>E</name>
<
type
>
Function
</type>
<
expression
>2.88e6</expression>
</parameter>
<
parameter
>
<
name
>nu</name>
<
type
>
Constant
</type>
<
value
>0.2</value>
</parameter>
<
parameter
>
<
name
>T0</name>
<
type
>
Constant
</type>
<
value
>300</value>
</parameter>
<
parameter
>
<
name
>displacement0</name>
<
type
>
Constant
</type>
<
values
>0 0</values>
</parameter>
<
parameter
>
<
name
>pressure_ic</name>
<
type
>
Constant
</type>
<
values
>0</values>
</parameter>
<
parameter
>
<
name
>dirichlet0</name>
<
type
>
Constant
</type>
<
value
>0</value>
</parameter>
<
parameter
>
<
name
>temperature_ic</name>
<
type
>
Constant
</type>
<
value
>300</value>
</parameter>
<
parameter
>
<
name
>pressure_bc_left</name>
<
type
>
Constant
</type>
<
value
>0</value>
</parameter>
<
parameter
>
<
name
>temperature_bc_left</name>
<
type
>
Constant
</type>
<
value
>350</value>
</parameter>
</parameters>
<
process_variables
>
<
process_variable
>
<
name
>displacement</name>
<
components
>2</components>
<
order
>1</order>
<
initial_condition
>displacement0</initial_condition>
<
boundary_conditions
>
<
boundary_condition
>
<
mesh
>column_physical_group_bottom</mesh>
<
type
>
Dirichlet
</type>
<
component
>1</component>
<
parameter
>dirichlet0</parameter>
</boundary_condition>
<
boundary_condition
>
<
mesh
>column_physical_group_left</mesh>
<
type
>
Dirichlet
</type>
<
component
>0</component>
<
parameter
>dirichlet0</parameter>
</boundary_condition>
<
boundary_condition
>
<
mesh
>column_physical_group_top</mesh>
<
type
>
Dirichlet
</type>
<
component
>1</component>
<
parameter
>dirichlet0</parameter>
</boundary_condition>
</boundary_conditions>
</process_variable>
<
process_variable
>
<
name
>pressure</name>
<
components
>1</components>
<
order
>1</order>
<
initial_condition
>pressure_ic</initial_condition>
<
boundary_conditions
>
<
boundary_condition
>
<
mesh
>column_physical_group_left</mesh>
<
type
>
Dirichlet
</type>
<
component
>0</component>
<
parameter
>pressure_bc_left</parameter>
</boundary_condition>
</boundary_conditions>
</process_variable>
<
process_variable
>
<
name
>temperature</name>
<
components
>1</components>
<
order
>1</order>
<
initial_condition
>temperature_ic</initial_condition>
<
boundary_conditions
>
<
boundary_condition
>
<
mesh
>column_physical_group_left</mesh>
<
type
>
Dirichlet
</type>
<
component
>0</component>
<
parameter
>temperature_bc_left</parameter>
</boundary_condition>
</boundary_conditions>
</process_variable>
</process_variables>
<
nonlinear_solvers
>
<
nonlinear_solver
>
<
name
>basic_newton</name>
<
type
>
Newton
</type>
<
max_iter
>50</max_iter>
<
linear_solver
>general_linear_solver</linear_solver>
</nonlinear_solver>
</nonlinear_solvers>
<
linear_solvers
>
<
linear_solver
>
<
name
>general_linear_solver</name>
<
eigen
>
<
solver_type
>SparseLU</solver_type>
<
scaling
>true</scaling>
</eigen>
</linear_solver>
</linear_solvers>
</OpenGeoSysProject>
OGS CTests—Project Files
ThermoHydroMechanics
Linear
ThermoOsmosis
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