def _createFields(runTime, mesh):
ref.ext_Info() << "Reading field p_rgh\n" << ref.nl
p_rgh = man.volScalarField(
man.IOobject(ref.word("p_rgh"), ref.fileName(runTime.timeName()), mesh,
ref.IOobject.MUST_READ, ref.IOobject.AUTO_WRITE), mesh)
ref.ext_Info() << "Reading field alpha1\n" << ref.nl
man.interfaceProperties # Load corresponding library to be able to use the following BC - "constantAlphaContactAngleFvPatchScalarField"
alpha1 = man.volScalarField(
man.IOobject(ref.word("alpha1"), ref.fileName(runTime.timeName()),
mesh, ref.IOobject.MUST_READ, ref.IOobject.AUTO_WRITE),
mesh)
ref.ext_Info() << "Reading field U\n" << ref.nl
U = man.volVectorField(
man.IOobject(ref.word("U"), ref.fileName(runTime.timeName()), mesh,
ref.IOobject.MUST_READ, ref.IOobject.AUTO_WRITE), mesh)
phi = man.createPhi(runTime, mesh, U)
ref.ext_Info() << "Reading transportProperties\n" << ref.nl
twoPhaseProperties = man.twoPhaseMixture(U, phi)
rho1 = twoPhaseProperties.rho1()
rho2 = twoPhaseProperties.rho2()
# Need to store rho for ddt(rho, U)
rho = man.volScalarField(
man.IOobject(ref.word("rho"), ref.fileName(runTime.timeName()), mesh,
ref.IOobject.READ_IF_PRESENT),
alpha1 * rho1 + (1.0 - alpha1) * rho2,
alpha1.ext_boundaryField().types())
rho.oldTime()
# Mass flux
# Initialisation does not matter because rhoPhi is reset after the
# alpha1 solution before it is used in the U equation.
rhoPhi = man.surfaceScalarField(
man.IOobject(ref.word("rho*phi"), ref.fileName(runTime.timeName()),
mesh, ref.IOobject.NO_READ, ref.IOobject.NO_WRITE),
rho1 * phi)
# Construct interface from alpha1 distribution
interface = man.interfaceProperties(alpha1, U, twoPhaseProperties)
# Construct incompressible turbulence model
turbulence = man.incompressible.turbulenceModel.New(
U, phi, twoPhaseProperties)
g = man.readGravitationalAcceleration(runTime, mesh)
#dimensionedVector g0(g);
#Read the data file and initialise the interpolation table
#interpolationTable<vector> timeSeriesAcceleration( runTime.path()/runTime.caseConstant()/"acceleration.dat" );
ref.ext_Info() << "Calculating field g.h\n" << ref.nl
gh = man.volScalarField(ref.word("gh"),
g & man.volVectorField(mesh.C(), man.Deps(mesh)))
ghf = man.surfaceScalarField(
ref.word("ghf"), g & man.surfaceVectorField(mesh.Cf(), man.Deps(mesh)))
p = man.volScalarField(
man.IOobject(ref.word("p"), ref.fileName(runTime.timeName()), mesh,
ref.IOobject.NO_READ, ref.IOobject.AUTO_WRITE),
p_rgh + rho * gh)
pRefCell = 0
pRefValue = 0.0
pRefCell, pRefValue = ref.setRefCell(
p, p_rgh,
mesh.solutionDict().subDict(ref.word("PIMPLE")), pRefCell, pRefValue)
if p_rgh.needReference():
p += ref.dimensionedScalar(
ref.word("p"), p.dimensions(),
pRefValue - ref.getRefCellValue(p, pRefCell))
p_rgh << p - rho * gh
pass
return p_rgh, p, alpha1, U, phi, rho1, rho2, rho, rhoPhi, twoPhaseProperties, pRefCell, pRefValue, interface, turbulence, g, gh, ghf
def _createFields(runTime, mesh, g):
ref.ext_Info() << "Reading field p_rgh\n" << ref.nl
p_rgh = man.volScalarField(
man.IOobject(ref.word("p_rgh"), ref.fileName(runTime.timeName()), mesh,
ref.IOobject.MUST_READ, ref.IOobject.AUTO_WRITE), mesh)
ref.ext_Info() << "Reading field alpha1\n" << ref.nl
alpha1 = man.volScalarField(
man.IOobject(ref.word("alpha1"), ref.fileName(runTime.timeName()),
mesh, ref.IOobject.MUST_READ, ref.IOobject.AUTO_WRITE),
mesh)
ref.ext_Info() << "Calculating field alpha1\n" << ref.nl
alpha2 = man.volScalarField(ref.word("alpha2"), 1.0 - alpha1)
ref.ext_Info() << "Reading field U\n" << ref.nl
U = man.volVectorField(
man.IOobject(ref.word("U"), ref.fileName(runTime.timeName()), mesh,
ref.IOobject.MUST_READ, ref.IOobject.AUTO_WRITE), mesh)
phi = man.createPhi(runTime, mesh, U)
ref.ext_Info() << "Reading transportProperties\n" << ref.nl
twoPhaseProperties = man.twoPhaseMixture(U, phi)
rho10 = ref.dimensionedScalar(
twoPhaseProperties.subDict(twoPhaseProperties.phase1Name()).lookup(
ref.word("rho0")))
rho20 = ref.dimensionedScalar(
twoPhaseProperties.subDict(twoPhaseProperties.phase2Name()).lookup(
ref.word("rho0")))
psi1 = ref.dimensionedScalar(
twoPhaseProperties.subDict(twoPhaseProperties.phase1Name()).lookup(
ref.word("psi")))
psi2 = ref.dimensionedScalar(
twoPhaseProperties.subDict(twoPhaseProperties.phase2Name()).lookup(
ref.word("psi")))
pMin = ref.dimensionedScalar(twoPhaseProperties.lookup(ref.word("pMin")))
ref.ext_Info() << "Calculating field g.h\n" << ref.nl
gh = man.volScalarField(ref.word("gh"),
g & man.volVectorField(mesh.C(), man.Deps(mesh)))
ghf = man.surfaceScalarField(
ref.word("ghf"), g & man.surfaceVectorField(mesh.Cf(), man.Deps(mesh)))
p = man.volScalarField(
man.IOobject(ref.word("p"), ref.fileName(runTime.timeName()), mesh,
ref.IOobject.NO_READ, ref.IOobject.AUTO_WRITE),
((p_rgh + gh * (alpha1 * rho10 + alpha2 * rho20)) /
(1.0 - gh * (alpha1 * psi1 + alpha2 * psi2))).ext_max(pMin)) #
rho1 = rho10 + psi1 * p
rho2 = rho20 + psi2 * p
rho = man.volScalarField(
man.IOobject(ref.word("rho"), ref.fileName(runTime.timeName()), mesh,
ref.IOobject.READ_IF_PRESENT, ref.IOobject.AUTO_WRITE),
alpha1 * rho1 + alpha2 * rho2)
# Mass flux
# Initialisation does not matter because rhoPhi is reset after the
# alpha1 solution before it is used in the U equation.
rhoPhi = man.surfaceScalarField(
man.IOobject(ref.word("rho*phi"), ref.fileName(runTime.timeName()),
mesh, ref.IOobject.NO_READ, ref.IOobject.NO_WRITE),
man.fvc.interpolate(rho) * phi)
dgdt = alpha2.pos() * man.fvc.div(phi) / alpha2.ext_max(0.0001)
# Construct interface from alpha1 distribution
interface = man.interfaceProperties(alpha1, U, twoPhaseProperties)
# Construct incompressible turbulence model
turbulence = man.incompressible.turbulenceModel.New(
U, phi, twoPhaseProperties)
return p_rgh, alpha1, alpha2, U, phi, twoPhaseProperties, rho10, rho20, psi1, psi2, pMin, \
gh, ghf, p, rho1, rho2, rho, rhoPhi, dgdt, interface, turbulence
def _createFields(runTime, mesh):
ref.ext_Info() << "Reading field p_rgh\n" << ref.nl
p_rgh = man.volScalarField(
man.IOobject(
ref.word("p_rgh"), ref.fileName(runTime.timeName()), mesh, ref.IOobject.MUST_READ, ref.IOobject.AUTO_WRITE
),
mesh,
)
ref.ext_Info() << "Reading field alpha1\n" << ref.nl
alpha1 = man.volScalarField(
man.IOobject(
ref.word("alpha1"), ref.fileName(runTime.timeName()), mesh, ref.IOobject.MUST_READ, ref.IOobject.AUTO_WRITE
),
mesh,
)
ref.ext_Info() << "Reading field U\n" << ref.nl
U = man.volVectorField(
man.IOobject(
ref.word("U"), ref.fileName(runTime.timeName()), mesh, ref.IOobject.MUST_READ, ref.IOobject.AUTO_WRITE
),
mesh,
)
phi = man.createPhi(runTime, mesh, U)
ref.ext_Info() << "Reading transportProperties\n" << ref.nl
twoPhaseProperties = man.twoPhaseMixture(U, phi)
rho1 = twoPhaseProperties.rho1()
rho2 = twoPhaseProperties.rho2()
# Need to store rho for ddt(rho, U)
rho = man.volScalarField(
man.IOobject(ref.word("rho"), ref.fileName(runTime.timeName()), mesh, ref.IOobject.READ_IF_PRESENT),
alpha1 * rho1 + (1.0 - alpha1) * rho2,
alpha1.ext_boundaryField().types(),
)
rho.oldTime()
# Mass flux
# Initialisation does not matter because rhoPhi is reset after the
# alpha1 solution before it is used in the U equation.
rhoPhi = man.surfaceScalarField(
man.IOobject(
ref.word("rho*phi"), ref.fileName(runTime.timeName()), mesh, ref.IOobject.NO_READ, ref.IOobject.NO_WRITE
),
rho1 * phi,
)
# Construct interface from alpha1 distribution
interface = man.interfaceProperties(alpha1, U, twoPhaseProperties)
# Construct incompressible turbulence model
turbulence = man.incompressible.turbulenceModel.New(U, phi, twoPhaseProperties)
g = man.readGravitationalAcceleration(runTime, mesh)
# dimensionedVector g0(g);
# Read the data file and initialise the interpolation table
# interpolationTable<vector> timeSeriesAcceleration( runTime.path()/runTime.caseConstant()/"acceleration.dat" );
ref.ext_Info() << "Calculating field g.h\n" << ref.nl
gh = man.volScalarField(ref.word("gh"), g & man.volVectorField(mesh.C(), man.Deps(mesh)))
ghf = man.surfaceScalarField(ref.word("ghf"), g & man.surfaceVectorField(mesh.Cf(), man.Deps(mesh)))
p = man.volScalarField(
man.IOobject(
ref.word("p"), ref.fileName(runTime.timeName()), mesh, ref.IOobject.NO_READ, ref.IOobject.AUTO_WRITE
),
p_rgh + rho * gh,
)
pRefCell = 0
pRefValue = 0.0
pRefCell, pRefValue = ref.setRefCell(p, p_rgh, mesh.solutionDict().subDict(ref.word("PIMPLE")), pRefCell, pRefValue)
if p_rgh.needReference():
p += ref.dimensionedScalar(ref.word("p"), p.dimensions(), pRefValue - ref.getRefCellValue(p, pRefCell))
p_rgh << p - rho * gh
pass
return (
p_rgh,
p,
alpha1,
U,
phi,
rho1,
rho2,
rho,
rhoPhi,
twoPhaseProperties,
pRefCell,
pRefValue,
interface,
turbulence,
g,
gh,
ghf,
)
def _createFields( runTime, mesh, g ):
ref.ext_Info() << "Reading field p_rgh\n" << ref.nl
p_rgh = man.volScalarField( man.IOobject( ref.word( "p_rgh" ),
ref.fileName( runTime.timeName() ),
mesh,
ref.IOobject.MUST_READ,
ref.IOobject.AUTO_WRITE ),
mesh )
ref.ext_Info() << "Reading field alpha1\n" << ref.nl
alpha1 = man.volScalarField( man.IOobject( ref.word( "alpha1" ),
ref.fileName( runTime.timeName() ),
mesh,
ref.IOobject.MUST_READ,
ref.IOobject.AUTO_WRITE ),
mesh )
ref.ext_Info() << "Calculating field alpha1\n" << ref.nl
alpha2 = man.volScalarField( ref.word( "alpha2" ), 1.0 - alpha1 )
ref.ext_Info() << "Reading field U\n" << ref.nl
U = man.volVectorField( man.IOobject( ref.word( "U" ),
ref.fileName( runTime.timeName() ),
mesh,
ref.IOobject.MUST_READ,
ref.IOobject.AUTO_WRITE ),
mesh )
phi = man.createPhi( runTime, mesh, U )
ref.ext_Info() << "Reading transportProperties\n" << ref.nl
twoPhaseProperties = man.twoPhaseMixture (U, phi)
rho10 = ref.dimensionedScalar( twoPhaseProperties.subDict( twoPhaseProperties.phase1Name() ).lookup( ref.word( "rho0" ) ) )
rho20 = ref.dimensionedScalar( twoPhaseProperties.subDict( twoPhaseProperties.phase2Name() ).lookup( ref.word( "rho0" ) ) )
psi1 = ref.dimensionedScalar( twoPhaseProperties.subDict( twoPhaseProperties.phase1Name() ).lookup( ref.word( "psi" ) ) )
psi2 = ref.dimensionedScalar( twoPhaseProperties.subDict( twoPhaseProperties.phase2Name() ).lookup( ref.word( "psi" ) ) )
pMin = ref.dimensionedScalar( twoPhaseProperties.lookup( ref.word( "pMin" ) ) )
ref.ext_Info() << "Calculating field g.h\n" << ref.nl
gh = man.volScalarField( ref.word( "gh" ), g & man.volVectorField( mesh.C(), man.Deps( mesh ) ) )
ghf = man.surfaceScalarField( ref.word( "ghf" ), g & man.surfaceVectorField( mesh.Cf(), man.Deps( mesh ) ) )
p = man.volScalarField( man.IOobject( ref.word( "p" ),
ref.fileName( runTime.timeName() ),
mesh,
ref.IOobject.NO_READ,
ref.IOobject.AUTO_WRITE ),
( ( p_rgh + gh * ( alpha1 * rho10 + alpha2 * rho20 ) ) / ( 1.0 - gh * ( alpha1 * psi1 + alpha2 * psi2 ) ) ).ext_max( pMin ) ) #
rho1 = rho10 + psi1 * p
rho2 = rho20 + psi2 * p
rho = man.volScalarField( man.IOobject( ref.word( "rho" ),
ref.fileName( runTime.timeName() ),
mesh,
ref.IOobject.READ_IF_PRESENT,
ref.IOobject.AUTO_WRITE ),
alpha1 * rho1 + alpha2 * rho2 )
# Mass flux
# Initialisation does not matter because rhoPhi is reset after the
# alpha1 solution before it is used in the U equation.
rhoPhi = man.surfaceScalarField( man.IOobject( ref.word( "rho*phi" ),
ref.fileName( runTime.timeName() ),
mesh,
ref.IOobject.NO_READ,
ref.IOobject.NO_WRITE ),
man.fvc.interpolate( rho ) * phi )
dgdt = alpha2.pos() * man.fvc.div( phi ) / alpha2.ext_max( 0.0001 )
# Construct interface from alpha1 distribution
interface = man.interfaceProperties( alpha1, U, twoPhaseProperties )
# Construct incompressible turbulence model
turbulence = man.incompressible.turbulenceModel.New( U, phi, twoPhaseProperties )
return p_rgh, alpha1, alpha2, U, phi, twoPhaseProperties, rho10, rho20, psi1, psi2, pMin, \
gh, ghf, p, rho1, rho2, rho, rhoPhi, dgdt, interface, turbulence
