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hit formatting of electrothermal with phase field input file
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Refs #128
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Armando Pabon committed Jun 27, 2024
1 parent 726f8ee commit 995d992
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Showing 6 changed files with 74 additions and 49 deletions.
Original file line number Diff line number Diff line change
Expand Up @@ -88,7 +88,8 @@ initial_temperature = 873 #roughly 600C where the pyrometer kicks in
initial_condition = 2.0e-10 #in units eV/((nV)^2-s-nm)
block = 'powder_compact'
[]
[microapp_potential] #converted to microapp electronVolts units
[microapp_potential]
#converted to microapp electronVolts units
block = 'powder_compact'
[]
[E_x]
Expand Down Expand Up @@ -616,10 +617,8 @@ initial_temperature = 873 #roughly 600C where the pyrometer kicks in
gap_conductivity_function_variable = temperature
normal_smoothing_distance = 0.1
[]
[]

##Thermal Contact between gapped graphite die components
[ThermalContact]
[upper_plunger_spacer_gap_thermal]
type = GapHeatTransfer
primary = spacer_facing_upper_plunger
Expand Down Expand Up @@ -698,10 +697,8 @@ initial_temperature = 873 #roughly 600C where the pyrometer kicks in
gap_conductivity_function_variable = temperature
normal_smoothing_distance = 0.1
[]
[]

## Thermal Contact between touching components of powder and die
[ThermalContact]
[upper_plunger_powder_thermal]
type = GapHeatTransfer
primary = bottom_upper_plunger
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Original file line number Diff line number Diff line change
Expand Up @@ -69,11 +69,13 @@ initial_field = 10 #from the engineering scale, starting value 10 V/m
[]
[T]
[]
[Q_joule] #Problem units of eV/nm^3/s
[Q_joule]
#Problem units of eV/nm^3/s
order = CONSTANT
family = MONOMIAL
[]
[Q_joule_SI] #SI units of J/m^3/s
[Q_joule_SI]
#SI units of J/m^3/s
order = CONSTANT
family = MONOMIAL
[]
Expand Down
Original file line number Diff line number Diff line change
Expand Up @@ -88,7 +88,8 @@ initial_temperature = 873 #roughly 600C where the pyrometer kicks in
initial_condition = 2.0e-10 #in units eV/((nV)^2-s-nm)
block = 'powder_compact'
[]
[microapp_potential] #converted to microapp electronVolts units
[microapp_potential]
#converted to microapp electronVolts units
block = 'powder_compact'
[]
[E_x]
Expand Down Expand Up @@ -152,7 +153,8 @@ initial_temperature = 873 #roughly 600C where the pyrometer kicks in
# family = MONOMIAL
# order = FIRST
# []
[Q_from_sub] #this will be in eV/m/s, will need unit conversion to J/m^3/s based on phase-field domain size
[Q_from_sub]
#this will be in eV/m/s, will need unit conversion to J/m^3/s based on phase-field domain size
order = FIRST
family = LAGRANGE
[]
Expand Down Expand Up @@ -625,10 +627,8 @@ initial_temperature = 873 #roughly 600C where the pyrometer kicks in
gap_conductivity_function_variable = temperature
normal_smoothing_distance = 0.1
[]
[]

##Thermal Contact between gapped graphite die components
[ThermalContact]
[upper_plunger_spacer_gap_thermal]
type = GapHeatTransfer
primary = spacer_facing_upper_plunger
Expand Down Expand Up @@ -707,10 +707,8 @@ initial_temperature = 873 #roughly 600C where the pyrometer kicks in
gap_conductivity_function_variable = temperature
normal_smoothing_distance = 0.1
[]
[]

## Thermal Contact between touching components of powder and die
[ThermalContact]
[upper_plunger_powder_thermal]
type = GapHeatTransfer
primary = bottom_upper_plunger
Expand Down
Original file line number Diff line number Diff line change
Expand Up @@ -44,16 +44,20 @@ initial_voltage = 0.0001
[]
[dV]
[]
[Tx_AEH] #Temperature used for the x-component of the AEH solve
[Tx_AEH]
#Temperature used for the x-component of the AEH solve
initial_condition = ${initial_temperature}
[]
[Ty_AEH] #Temperature used for the y-component of the AEH solve
[Ty_AEH]
#Temperature used for the y-component of the AEH solve
initial_condition = ${initial_temperature}
[]
[Vx_AEH] #Voltage potential used for the x-component of the AEH solve
[Vx_AEH]
#Voltage potential used for the x-component of the AEH solve
initial_condition = ${initial_voltage}
[]
[Vy_AEH] #Voltage potential used for the y-component of the AEH solve
[Vy_AEH]
#Voltage potential used for the y-component of the AEH solve
initial_condition = ${initial_voltage}
[]
[]
Expand Down Expand Up @@ -91,7 +95,8 @@ initial_voltage = 0.0001
[]
[T]
[]
[Q_joule] #Problem units of eV/nm^3/s
[Q_joule]
#Problem units of eV/nm^3/s
order = CONSTANT
family = MONOMIAL
[]
Expand Down Expand Up @@ -176,25 +181,29 @@ initial_voltage = 0.0001
variable = 'Tx_AEH Ty_AEH Vx_AEH Vy_AEH'
[]
[]
[fix_AEH_Tx] #Fix Tx_AEH at a single point
[fix_AEH_Tx]
#Fix Tx_AEH at a single point
type = PostprocessorDirichletBC
variable = Tx_AEH
postprocessor = T_postproc
boundary = 1000
[]
[fix_AEH_Ty] #Fix Ty_AEH at a single point
[fix_AEH_Ty]
#Fix Ty_AEH at a single point
type = PostprocessorDirichletBC
variable = Ty_AEH
postprocessor = T_postproc
boundary = 1000
[]
[fix_AEH_Vx] #Fix Tx_AEH at a single point
[fix_AEH_Vx]
#Fix Tx_AEH at a single point
type = PostprocessorDirichletBC
variable = Vx_AEH
postprocessor = V_postproc
boundary = 1000
[]
[fix_AEH_Vy] #Fix Ty_AEH at a single point
[fix_AEH_Vy]
#Fix Ty_AEH at a single point
type = PostprocessorDirichletBC
variable = Vy_AEH
postprocessor = V_postproc
Expand Down Expand Up @@ -528,7 +537,8 @@ initial_voltage = 0.0001
diffusivity = electrical_conductivity
args = 'phi'
[]
[heat_x] #Following kernels are for AEH approach to calculate thermal cond.
[heat_x]
#Following kernels are for AEH approach to calculate thermal cond.
type = HeatConduction
variable = Tx_AEH
[]
Expand All @@ -546,7 +556,8 @@ initial_voltage = 0.0001
variable = Ty_AEH
component = 1
[]
[voltage_x] #The following four kernels are for AEH approach to calculate electrical cond.
[voltage_x]
#The following four kernels are for AEH approach to calculate electrical cond.
type = HeatConduction
variable = Vx_AEH
diffusion_coefficient = electrical_conductivity
Expand Down Expand Up @@ -654,14 +665,16 @@ initial_voltage = 0.0001
type = Receiver
default = ${initial_voltage}
[]
[k_x_AEH] #Effective thermal conductivity in x-direction from AEH
[k_x_AEH]
#Effective thermal conductivity in x-direction from AEH
type = HomogenizedThermalConductivity
chi = 'Tx_AEH Ty_AEH'
row = 0
col = 0
execute_on = TIMESTEP_END
[]
[k_y_AEH] #Effective thermal conductivity in y-direction from AEH
[k_y_AEH]
#Effective thermal conductivity in y-direction from AEH
type = HomogenizedThermalConductivity
chi = 'Tx_AEH Ty_AEH'
row = 1
Expand All @@ -673,15 +686,17 @@ initial_voltage = 0.0001
pp_coefs = '0.5 0.5'
pp_names = 'k_x_AEH k_y_AEH'
[]
[sigma_x_AEH] #Effective electrical conductivity in x-direction from AEH
[sigma_x_AEH]
#Effective electrical conductivity in x-direction from AEH
type = HomogenizedThermalConductivity
chi = 'Vx_AEH Vy_AEH'
row = 0
col = 0
execute_on = TIMESTEP_END
diffusion_coefficient = electrical_conductivity
[]
[sigma_y_AEH] #Effective electrical conductivity in y-direction from AEH
[sigma_y_AEH]
#Effective electrical conductivity in y-direction from AEH
type = HomogenizedThermalConductivity
chi = 'Vx_AEH Vy_AEH'
row = 1
Expand Down
Original file line number Diff line number Diff line change
Expand Up @@ -93,7 +93,8 @@ initial_temperature = 873 #roughly 600C where the pyrometer kicks in
initial_condition = 2.0e-10 #in units eV/((nV)^2-s-nm)
block = 'powder_compact'
[]
[microapp_potential] #converted to microapp electronVolts units
[microapp_potential]
#converted to microapp electronVolts units
block = 'powder_compact'
[]
[E_x]
Expand All @@ -112,7 +113,8 @@ initial_temperature = 873 #roughly 600C where the pyrometer kicks in
block = 'powder_compact'
[]

[Q_from_sub] #this will be in eV/m/s, will need unit conversion to J/m^3/s based on phase-field domain size
[Q_from_sub]
#this will be in eV/m/s, will need unit conversion to J/m^3/s based on phase-field domain size
order = FIRST
family = LAGRANGE
[]
Expand Down Expand Up @@ -629,10 +631,8 @@ initial_temperature = 873 #roughly 600C where the pyrometer kicks in
gap_conductivity_function_variable = temperature
normal_smoothing_distance = 0.1
[]
[]

##Thermal Contact between gapped graphite die components
[ThermalContact]
[upper_plunger_spacer_gap_thermal]
type = GapHeatTransfer
primary = spacer_facing_upper_plunger
Expand Down Expand Up @@ -711,10 +711,8 @@ initial_temperature = 873 #roughly 600C where the pyrometer kicks in
gap_conductivity_function_variable = temperature
normal_smoothing_distance = 0.1
[]
[]

## Thermal Contact between touching components of powder and die
[ThermalContact]
[upper_plunger_powder_thermal]
type = GapHeatTransfer
primary = bottom_upper_plunger
Expand Down
Original file line number Diff line number Diff line change
Expand Up @@ -44,16 +44,20 @@ initial_voltage = 0.0001
[]
[dV]
[]
[Tx_AEH] #Temperature used for the x-component of the AEH solve
[Tx_AEH]
#Temperature used for the x-component of the AEH solve
initial_condition = 300
[]
[Ty_AEH] #Temperature used for the y-component of the AEH solve
[Ty_AEH]
#Temperature used for the y-component of the AEH solve
initial_condition = 300
[]
[Vx_AEH] #Voltage potential used for the x-component of the AEH solve
[Vx_AEH]
#Voltage potential used for the x-component of the AEH solve
initial_condition = ${initial_voltage}
[]
[Vy_AEH] #Voltage potential used for the y-component of the AEH solve
[Vy_AEH]
#Voltage potential used for the y-component of the AEH solve
initial_condition = ${initial_voltage}
[]
[]
Expand Down Expand Up @@ -91,7 +95,8 @@ initial_voltage = 0.0001
[]
[T]
[]
[Q_joule] #Problem units of eV/nm^3/s
[Q_joule]
#Problem units of eV/nm^3/s
order = CONSTANT
family = MONOMIAL
[]
Expand Down Expand Up @@ -157,25 +162,29 @@ initial_voltage = 0.0001
variable = 'Tx_AEH Ty_AEH Vx_AEH Vy_AEH'
[]
[]
[fix_AEH_Tx] #Fix Tx_AEH at a single point
[fix_AEH_Tx]
#Fix Tx_AEH at a single point
type = PostprocessorDirichletBC
variable = Tx_AEH
postprocessor = T_postproc
boundary = 1000
[]
[fix_AEH_Ty] #Fix Ty_AEH at a single point
[fix_AEH_Ty]
#Fix Ty_AEH at a single point
type = PostprocessorDirichletBC
variable = Ty_AEH
postprocessor = T_postproc
boundary = 1000
[]
[fix_AEH_Vx] #Fix Tx_AEH at a single point
[fix_AEH_Vx]
#Fix Tx_AEH at a single point
type = PostprocessorDirichletBC
variable = Vx_AEH
postprocessor = V_postproc
boundary = 1000
[]
[fix_AEH_Vy] #Fix Ty_AEH at a single point
[fix_AEH_Vy]
#Fix Ty_AEH at a single point
type = PostprocessorDirichletBC
variable = Vy_AEH
postprocessor = V_postproc
Expand Down Expand Up @@ -525,7 +534,8 @@ initial_voltage = 0.0001
diffusivity = electrical_conductivity
args = 'phi'
[]
[heat_x] #Following kernels are for AEH approach to calculate thermal cond.
[heat_x]
#Following kernels are for AEH approach to calculate thermal cond.
type = HeatConduction
variable = Tx_AEH
[]
Expand All @@ -543,7 +553,8 @@ initial_voltage = 0.0001
variable = Ty_AEH
component = 1
[]
[voltage_x] #The following four kernels are for AEH approach to calculate electrical cond.
[voltage_x]
#The following four kernels are for AEH approach to calculate electrical cond.
type = HeatConduction
variable = Vx_AEH
diffusion_coefficient = electrical_conductivity
Expand Down Expand Up @@ -658,14 +669,16 @@ initial_voltage = 0.0001
type = Receiver
default = ${initial_voltage}
[]
[k_x_AEH] #Effective thermal conductivity in x-direction from AEH
[k_x_AEH]
#Effective thermal conductivity in x-direction from AEH
type = HomogenizedThermalConductivity
chi = 'Tx_AEH Ty_AEH'
row = 0
col = 0
execute_on = TIMESTEP_END
[]
[k_y_AEH] #Effective thermal conductivity in y-direction from AEH
[k_y_AEH]
#Effective thermal conductivity in y-direction from AEH
type = HomogenizedThermalConductivity
chi = 'Tx_AEH Ty_AEH'
row = 1
Expand All @@ -677,15 +690,17 @@ initial_voltage = 0.0001
pp_coefs = '0.5 0.5'
pp_names = 'k_x_AEH k_y_AEH'
[]
[sigma_x_AEH] #Effective electrical conductivity in x-direction from AEH
[sigma_x_AEH]
#Effective electrical conductivity in x-direction from AEH
type = HomogenizedThermalConductivity
chi = 'Vx_AEH Vy_AEH'
row = 0
col = 0
execute_on = TIMESTEP_END
diffusion_coefficient = electrical_conductivity
[]
[sigma_y_AEH] #Effective electrical conductivity in y-direction from AEH
[sigma_y_AEH]
#Effective electrical conductivity in y-direction from AEH
type = HomogenizedThermalConductivity
chi = 'Vx_AEH Vy_AEH'
row = 1
Expand Down

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