INSFVMushyPorousFrictionFunctorMaterial

Computes the mushy zone porous resistance for solidification/melting problems.

This material computes the Darcy_coefficient and the Forchheimer_coefficient for a solidification problem. The model uses a mushy-zone approach to compute the friction coefficients.

The coefficients are defined as follows:

$var element = document.getElementById("moose-equation-03cf6950-7b53-4014-b713-226d6b2e1fc6");katex.render("D = \\frac{\\mu}{K} \\,,", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$

where the permeability $var element = document.getElementById("moose-equation-fff657c0-896e-4ffe-9525-ec8b1cefddf8");katex.render("K", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ is defined as follows:

$var element = document.getElementById("moose-equation-3e68da50-9662-4978-bfc9-36f3ab1264a1");katex.render("K = \\frac{f_l^3}{f_s^2 F_k c_s} \\,,", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$

where $var element = document.getElementById("moose-equation-0b7f42cd-fda9-4520-879a-f0abdeb32cd9");katex.render("f_l", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ and $var element = document.getElementById("moose-equation-d4d5901a-17b1-4bdb-8ec7-36f0b1d87ab5");katex.render("f_s", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ are the liquid and solid fraction, the switching function is defined as $var element = document.getElementById("moose-equation-21c8046a-4f80-450c-93ab-ceed324c5f5c");katex.render("F_k = 0.5 * \\operatorname{atan}(s (f_s - f_{s,crit}) / \\pi)", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ with $var element = document.getElementById("moose-equation-8958b4ab-6b6c-496b-a498-b5a5f5ef1e0e");katex.render("s=100", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ and $var element = document.getElementById("moose-equation-8a4735e4-5847-4b4f-bbfb-bb09076e311f");katex.render("f_{s,crit}=0.27", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ and $var element = document.getElementById("moose-equation-e200098e-89bc-470a-85e5-bff48f9099eb");katex.render("c_s = c / (\\lambda)^2", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ with $var element = document.getElementById("moose-equation-328f9c6d-eb74-449f-a52e-94fbf4e5e143");katex.render("c = 180", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ and the dendrite spacing is $var element = document.getElementById("moose-equation-f120b6a0-2290-4468-8438-ae5a8294a777");katex.render("\\lambda", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ . By default, we set $var element = document.getElementById("moose-equation-61fbf7e4-4916-4736-a3d7-5715b470d010");katex.render("\\lambda = 10^{-4}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ . However, this coefficient may be tuned by the user if experimental data is available.

The Forchheimer coefficient is defined as follows:

$var element = document.getElementById("moose-equation-e238f8e2-7683-45d1-83be-01c0d999196a");katex.render("F = C_F \\frac{\\rho_l}{\\sqrt{K}} \\,,", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$

where the Ergun coefficient is $var element = document.getElementById("moose-equation-1db1361b-d770-431a-8ab7-53130936b654");katex.render("C_F = 0.55", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ and $var element = document.getElementById("moose-equation-7a2525d5-b161-4f1f-b62e-b3d1e235c031");katex.render("\\rho_l", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ is the density of the liquid phase.

note

This material is compatible with INSFVMomentumFriction which multiplies the incoming Forchheimer coefficient by the velocity magnitude; it is incompatible with PINSFVMomentumFriction which assumes the incoming Forchheimer coefficient already includes multiplication by the velocity magnitude.

Input Parameters

liquid_fractionLiquid Fraction Functor. A functor is any of the following: a variable, a functor material property, a function, a post-processor, or a number.
C++ Type:MooseFunctorName
Controllable:No
Description:Liquid Fraction Functor. A functor is any of the following: a variable, a functor material property, a function, a post-processor, or a number.
muThe liquid dynamic viscosity. A functor is any of the following: a variable, a functor material property, a function, a post-processor, or a number.
C++ Type:MooseFunctorName
Controllable:No
Description:The liquid dynamic viscosity. A functor is any of the following: a variable, a functor material property, a function, a post-processor, or a number.
rho_lThe liquid density (not the mixture one). A functor is any of the following: a variable, a functor material property, a function, a post-processor, or a number.
C++ Type:MooseFunctorName
Controllable:No
Description:The liquid density (not the mixture one). A functor is any of the following: a variable, a functor material property, a function, a post-processor, or a number.

Required Parameters

blockThe list of blocks (ids or names) that this object will be applied
C++ Type:std::vector<SubdomainName>
Controllable:No
Description:The list of blocks (ids or names) that this object will be applied
boundaryThe list of boundaries (ids or names) from the mesh where this object applies
C++ Type:std::vector<BoundaryName>
Controllable:No
Description:The list of boundaries (ids or names) from the mesh where this object applies
constant_onNONEWhen ELEMENT, MOOSE will only call computeQpProperties() for the 0th quadrature point, and then copy that value to the other qps.When SUBDOMAIN, MOOSE will only call computeQpProperties() for the 0th quadrature point, and then copy that value to the other qps. Evaluations on element qps will be skipped
Default:NONE
C++ Type:MooseEnum
Options:NONE, ELEMENT, SUBDOMAIN
Controllable:No
Description:When ELEMENT, MOOSE will only call computeQpProperties() for the 0th quadrature point, and then copy that value to the other qps.When SUBDOMAIN, MOOSE will only call computeQpProperties() for the 0th quadrature point, and then copy that value to the other qps. Evaluations on element qps will be skipped
dendrite_spacing_scaling1e-4The dendrite spacing scaling. A functor is any of the following: a variable, a functor material property, a function, a post-processor, or a number.
Default:1e-4
C++ Type:MooseFunctorName
Controllable:No
Description:The dendrite spacing scaling. A functor is any of the following: a variable, a functor material property, a function, a post-processor, or a number.
execute_onALWAYSThe list of flag(s) indicating when this object should be executed, the available options include FORWARD, ADJOINT, HOMOGENEOUS_FORWARD, ADJOINT_TIMESTEP_BEGIN, ADJOINT_TIMESTEP_END, NONE, INITIAL, LINEAR, NONLINEAR, TIMESTEP_END, TIMESTEP_BEGIN, MULTIAPP_FIXED_POINT_END, MULTIAPP_FIXED_POINT_BEGIN, FINAL, CUSTOM.
Default:ALWAYS
C++ Type:ExecFlagEnum
Options:FORWARD, ADJOINT, HOMOGENEOUS_FORWARD, ADJOINT_TIMESTEP_BEGIN, ADJOINT_TIMESTEP_END, NONE, INITIAL, LINEAR, NONLINEAR, TIMESTEP_END, TIMESTEP_BEGIN, MULTIAPP_FIXED_POINT_END, MULTIAPP_FIXED_POINT_BEGIN, FINAL, CUSTOM, ALWAYS
Controllable:No
Description:The list of flag(s) indicating when this object should be executed, the available options include FORWARD, ADJOINT, HOMOGENEOUS_FORWARD, ADJOINT_TIMESTEP_BEGIN, ADJOINT_TIMESTEP_END, NONE, INITIAL, LINEAR, NONLINEAR, TIMESTEP_END, TIMESTEP_BEGIN, MULTIAPP_FIXED_POINT_END, MULTIAPP_FIXED_POINT_BEGIN, FINAL, CUSTOM.
prop_getter_suffixAn optional suffix parameter that can be appended to any attempt to retrieve/get material properties. The suffix will be prepended with a '_' character.
C++ Type:MaterialPropertyName
Controllable:No
Description:An optional suffix parameter that can be appended to any attempt to retrieve/get material properties. The suffix will be prepended with a '_' character.
use_interpolated_stateFalseFor the old and older state use projected material properties interpolated at the quadrature points. To set up projection use the ProjectedStatefulMaterialStorageAction.
Default:False
C++ Type:bool
Controllable:No
Description:For the old and older state use projected material properties interpolated at the quadrature points. To set up projection use the ProjectedStatefulMaterialStorageAction.

Optional Parameters

control_tagsAdds user-defined labels for accessing object parameters via control logic.
C++ Type:std::vector<std::string>
Controllable:No
Description:Adds user-defined labels for accessing object parameters via control logic.
enableTrueSet the enabled status of the MooseObject.
Default:True
C++ Type:bool
Controllable:Yes
Description:Set the enabled status of the MooseObject.
implicitTrueDetermines whether this object is calculated using an implicit or explicit form
Default:True
C++ Type:bool
Controllable:No
Description:Determines whether this object is calculated using an implicit or explicit form
seed0The seed for the master random number generator
Default:0
C++ Type:unsigned int
Controllable:No
Description:The seed for the master random number generator

Advanced Parameters

output_propertiesList of material properties, from this material, to output (outputs must also be defined to an output type)
C++ Type:std::vector<std::string>
Controllable:No
Description:List of material properties, from this material, to output (outputs must also be defined to an output type)
outputsnone Vector of output names where you would like to restrict the output of variables(s) associated with this object
Default:none
C++ Type:std::vector<OutputName>
Controllable:No
Description:Vector of output names where you would like to restrict the output of variables(s) associated with this object

Outputs Parameters

Input Files

(modules/navier_stokes/test/tests/finite_volume/ins/solidification/pipe_solidification.i)

(modules/navier_stokes/test/tests/finite_volume/ins/solidification/pipe_solidification.i)

mu = 8.8871e-4
rho_solid = 997.561
rho_liquid = 997.561
k_solid = 0.6203
k_liquid = 0.6203
cp_solid = 4181.72
cp_liquid = 4181.72
L = 3e5
T_liquidus = 285
T_solidus = 280

advected_interp_method = 'average'
velocity_interp_method = 'rc'

U_inlet = '${fparse 0.5 * mu / rho_liquid / 0.5}'
T_inlet = 300.0
T_cold = 200.0
Nx = 30
Ny = 5

[GlobalParams]
  rhie_chow_user_object = 'rc'
[]

[UserObjects]
  [rc]
    type = INSFVRhieChowInterpolator
    u = vel_x
    v = vel_y
    pressure = pressure
  []
[]

[Mesh]
  coord_type = 'RZ'
  rz_coord_axis = 'X'
  [gen]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0
    xmax = 10
    ymin = 0
    ymax = '${fparse 0.5 * 1.0}'
    nx = ${Nx}
    ny = ${Ny}
    bias_y = '${fparse 1 / 1.2}'
  []
  [rename1]
    type = RenameBoundaryGenerator
    input = gen
    old_boundary = 'left'
    new_boundary = 'inlet'
  []
  [rename2]
    type = RenameBoundaryGenerator
    input = rename1
    old_boundary = 'right'
    new_boundary = 'outlet'
  []
  [rename3]
    type = RenameBoundaryGenerator
    input = rename2
    old_boundary = 'bottom'
    new_boundary = 'symmetry'
  []
  [rename4]
    type = RenameBoundaryGenerator
    input = rename3
    old_boundary = 'top'
    new_boundary = 'wall'
  []
  [rename5]
    type = ParsedGenerateSideset
    input = rename4
    normal = '0 1 0'
    combinatorial_geometry = 'x>2.0 & x<8.0 & y>0.49999'
    new_sideset_name = 'cooled_wall'
  []
[]

[AuxVariables]
  [U]
    type = MooseVariableFVReal
  []
  [fl]
    type = MooseVariableFVReal
    initial_condition = 1.0
  []
  [density]
    type = MooseVariableFVReal
  []
  [th_cond]
    type = MooseVariableFVReal
  []
  [cp_var]
    type = MooseVariableFVReal
  []
  [darcy_coef]
    type = MooseVariableFVReal
  []
  [fch_coef]
    type = MooseVariableFVReal
  []
[]

[AuxKernels]
  [mag]
    type = VectorMagnitudeAux
    variable = U
    x = vel_x
    y = vel_y
  []
  [compute_fl]
    type = NSLiquidFractionAux
    variable = fl
    temperature = T
    T_liquidus = '${T_liquidus}'
    T_solidus = '${T_solidus}'
    execute_on = 'TIMESTEP_END'
  []
  [rho_out]
    type = FunctorAux
    functor = 'rho_mixture'
    variable = 'density'
  []
  [th_cond_out]
    type = FunctorAux
    functor = 'k_mixture'
    variable = 'th_cond'
  []
  [cp_out]
    type = FunctorAux
    functor = 'cp_mixture'
    variable = 'cp_var'
  []
  [darcy_out]
    type = FunctorAux
    functor = 'Darcy_coefficient'
    variable = 'darcy_coef'
  []
  [fch_out]
    type = FunctorAux
    functor = 'Forchheimer_coefficient'
    variable = 'fch_coef'
  []
[]

[Variables]
  [vel_x]
    type = INSFVVelocityVariable
    initial_condition = 0.0
  []
  [vel_y]
    type = INSFVVelocityVariable
    initial_condition = 0.0
  []
  [pressure]
    type = INSFVPressureVariable
  []
  [T]
    type = INSFVEnergyVariable
    initial_condition = '${T_inlet}'
    scaling = 1.0
  []
[]

[FVKernels]
  [mass]
    type = INSFVMassAdvection
    variable = pressure
    advected_interp_method = ${advected_interp_method}
    velocity_interp_method = ${velocity_interp_method}
    rho = rho_mixture
  []

  [u_time]
    type = INSFVMomentumTimeDerivative
    variable = vel_x
    rho = rho_mixture
    momentum_component = 'x'
  []
  [u_advection]
    type = INSFVMomentumAdvection
    variable = vel_x
    advected_interp_method = ${advected_interp_method}
    velocity_interp_method = ${velocity_interp_method}
    rho = rho_mixture
    momentum_component = 'x'
  []
  [u_viscosity]
    type = INSFVMomentumDiffusion
    variable = vel_x
    mu = ${mu}
    momentum_component = 'x'
  []
  [u_pressure]
    type = INSFVMomentumPressure
    variable = vel_x
    momentum_component = 'x'
    pressure = pressure
  []
  [u_friction]
    type = INSFVMomentumFriction
    variable = vel_x
    momentum_component = 'x'
    linear_coef_name = 'Darcy_coefficient'
    quadratic_coef_name = 'Forchheimer_coefficient'
  []

  [v_time]
    type = INSFVMomentumTimeDerivative
    variable = vel_y
    rho = rho_mixture
    momentum_component = 'y'
  []
  [v_advection]
    type = INSFVMomentumAdvection
    variable = vel_y
    advected_interp_method = ${advected_interp_method}
    velocity_interp_method = ${velocity_interp_method}
    rho = rho_mixture
    momentum_component = 'y'
  []
  [v_viscosity]
    type = INSFVMomentumDiffusion
    variable = vel_y
    mu = ${mu}
    momentum_component = 'y'
  []
  [v_pressure]
    type = INSFVMomentumPressure
    variable = vel_y
    momentum_component = 'y'
    pressure = pressure
  []
  [v_friction]
    type = INSFVMomentumFriction
    variable = vel_y
    momentum_component = 'y'
    linear_coef_name = 'Darcy_coefficient'
    quadratic_coef_name = 'Forchheimer_coefficient'
  []

  [T_time]
    type = INSFVEnergyTimeDerivative
    variable = T
    rho = rho_mixture
    dh_dt = dh_dt
  []
  [energy_advection]
    type = INSFVEnergyAdvection
    variable = T
    velocity_interp_method = ${velocity_interp_method}
    advected_interp_method = ${advected_interp_method}
  []
  [energy_diffusion]
    type = FVDiffusion
    coeff = k_mixture
    variable = T
  []
  [energy_source]
    type = NSFVPhaseChangeSource
    variable = T
    L = ${L}
    liquid_fraction = fl
    T_liquidus = ${T_liquidus}
    T_solidus = ${T_solidus}
    rho = 'rho_mixture'
  []
[]

[FVBCs]
  [inlet-u]
    type = INSFVInletVelocityBC
    boundary = 'inlet'
    variable = vel_x
    function = '${U_inlet}'
  []
  [sym_u]
    type = INSFVSymmetryVelocityBC
    boundary = 'symmetry'
    variable = vel_x
    u = vel_x
    v = vel_y
    mu = ${mu}
    momentum_component = 'x'
  []
  [inlet-v]
    type = INSFVInletVelocityBC
    boundary = 'inlet'
    variable = vel_y
    function = 0
  []
  [walls-u]
    type = INSFVNoSlipWallBC
    boundary = 'wall'
    variable = vel_x
    function = 0
  []
  [walls-v]
    type = INSFVNoSlipWallBC
    boundary = 'wall'
    variable = vel_y
    function = 0
  []
  [sym_v]
    type = INSFVSymmetryVelocityBC
    boundary = 'symmetry'
    variable = vel_y
    u = vel_x
    v = vel_y
    mu = ${mu}
    momentum_component = y
  []
  [outlet_p]
    type = INSFVOutletPressureBC
    boundary = 'outlet'
    variable = pressure
    function = 0
  []
  [sym_p]
    type = INSFVSymmetryPressureBC
    boundary = 'symmetry'
    variable = pressure
  []
  [sym_T]
    type = INSFVSymmetryScalarBC
    variable = T
    boundary = 'symmetry'
  []
  [cooled_wall]
    type = FVFunctorDirichletBC
    variable = T
    functor = '${T_cold}'
    boundary = 'cooled_wall'
  []
[]

[FunctorMaterials]
  [ins_fv]
    type = INSFVEnthalpyFunctorMaterial
    rho = rho_mixture
    cp = cp_mixture
    temperature = 'T'
  []
  [eff_cp]
    type = NSFVMixtureFunctorMaterial
    phase_2_names = '${cp_solid} ${k_solid} ${rho_solid}'
    phase_1_names = '${cp_liquid} ${k_liquid} ${rho_liquid}'
    prop_names = 'cp_mixture k_mixture rho_mixture'
    phase_1_fraction = fl
  []
  [mushy_zone_resistance]
    type = INSFVMushyPorousFrictionFunctorMaterial
    liquid_fraction = 'fl'
    mu = '${mu}'
    rho_l = '${rho_liquid}'
  []
[]

[Executioner]
  type = Transient
  dt = 5e3
  end_time = 1e4
  solve_type = 'NEWTON'
  petsc_options_iname = '-pc_type -pc_factor_shift_type'
  petsc_options_value = 'lu NONZERO'
  nl_abs_tol = 1e-8
  nl_max_its = 12
[]

[Postprocessors]
  [average_T]
    type = ElementAverageValue
    variable = T
    outputs = csv
    execute_on = FINAL
  []
[]

[VectorPostprocessors]
  [sat]
    type = LineValueSampler
    warn_discontinuous_face_values = false
    start_point = '0.0 0 0'
    end_point = '10.0 0 0'
    num_points = '${Nx}'
    sort_by = x
    variable = 'T'
    execute_on = FINAL
  []
[]

[Outputs]
  exodus = true
  [csv]
    type = CSV
    execute_on = 'FINAL'
  []
[]

Input Parameters
Input Files