Enthalpy/Internal energy for a mixture. More...

Inheritance diagram for heThermo< BasicThermo, MixtureType >:

Collaboration diagram for heThermo< BasicThermo, MixtureType >:

Public Member Functions
	heThermo (const fvMesh &, const word &phaseName)
	Construct from mesh. More...

	heThermo (const fvMesh &, const dictionary &, const word &phaseName)
	Construct from mesh and dictionary. More...

virtual	~heThermo ()
	Destructor. More...

virtual MixtureType::basicMixtureType &	composition ()
	Return the compostion of the mixture. More...

virtual const MixtureType::basicMixtureType &	composition () const
	Return the compostion of the mixture. More...

virtual word	thermoName () const
	Return the name of the thermo physics. More...

virtual bool	incompressible () const
	Return true if the equation of state is incompressible. More...

virtual bool	isochoric () const
	Return true if the equation of state is isochoric. More...

virtual volScalarField &	he ()
	Enthalpy/Internal energy [J/kg]. More...

virtual const volScalarField &	he () const
	Enthalpy/Internal energy [J/kg]. More...

virtual tmp< volScalarField >	he (const volScalarField &p, const volScalarField &T) const
	Enthalpy/Internal energy. More...

virtual tmp< scalarField >	he (const scalarField &p, const scalarField &T, const labelList &cells) const
	Enthalpy/Internal energy for cell-set [J/kg]. More...

virtual tmp< scalarField >	he (const scalarField &p, const scalarField &T, const label patchi) const
	Enthalpy/Internal energy for patch [J/kg]. More...

virtual tmp< volScalarField >	hc () const
	Chemical enthalpy [J/kg]. More...

virtual tmp< scalarField >	THE (const scalarField &he, const scalarField &p, const scalarField &T0, const labelList &cells) const
	Temperature from enthalpy/internal energy for cell-set. More...

virtual tmp< scalarField >	THE (const scalarField &he, const scalarField &p, const scalarField &T0, const label patchi) const
	Temperature from enthalpy/internal energy for patch. More...

virtual tmp< scalarField >	Cp (const scalarField &p, const scalarField &T, const label patchi) const
	Heat capacity at constant pressure for patch [J/kg/K]. More...

virtual tmp< volScalarField >	Cp () const
	Heat capacity at constant pressure [J/kg/K]. More...

virtual tmp< scalarField >	Cv (const scalarField &p, const scalarField &T, const label patchi) const
	Heat capacity at constant volume for patch [J/kg/K]. More...

virtual tmp< volScalarField >	Cv () const
	Heat capacity at constant volume [J/kg/K]. More...

virtual tmp< volScalarField >	gamma () const
	Gamma = Cp/Cv []. More...

virtual tmp< scalarField >	gamma (const scalarField &p, const scalarField &T, const label patchi) const
	Gamma = Cp/Cv for patch []. More...

virtual tmp< scalarField >	Cpv (const scalarField &p, const scalarField &T, const label patchi) const
	Heat capacity at constant pressure/volume for patch [J/kg/K]. More...

virtual tmp< volScalarField >	Cpv () const
	Heat capacity at constant pressure/volume [J/kg/K]. More...

virtual tmp< volScalarField >	CpByCpv () const
	Heat capacity ratio []. More...

virtual tmp< scalarField >	CpByCpv (const scalarField &p, const scalarField &T, const label patchi) const
	Heat capacity ratio for patch []. More...

virtual tmp< volScalarField >	W () const
	Molecular weight [kg/kmol]. More...

virtual tmp< scalarField >	W (const label patchi) const
	Molecular weight for patch [kg/kmol]. More...

virtual tmp< volScalarField >	kappa () const
	Thermal diffusivity for temperature of mixture [W/m/K]. More...

virtual tmp< scalarField >	kappa (const label patchi) const
	Thermal diffusivity for temperature of mixture. More...

virtual tmp< volScalarField >	alphahe () const
	Thermal diffusivity for energy of mixture [kg/m/s]. More...

virtual tmp< scalarField >	alphahe (const label patchi) const
	Thermal diffusivity for energy of mixture for patch [kg/m/s]. More...

virtual tmp< volScalarField >	kappaEff (const volScalarField &) const
	Effective thermal turbulent diffusivity for temperature. More...

virtual tmp< scalarField >	kappaEff (const scalarField &alphat, const label patchi) const
	Effective thermal turbulent diffusivity for temperature. More...

virtual tmp< volScalarField >	alphaEff (const volScalarField &alphat) const
	Effective thermal turbulent diffusivity of mixture [kg/m/s]. More...

virtual tmp< scalarField >	alphaEff (const scalarField &alphat, const label patchi) const
	Effective thermal turbulent diffusivity of mixture. More...

virtual bool	read ()
	Read thermophysical properties dictionary. More...

Protected Member Functions
void	heBoundaryCorrection (volScalarField &he)
	Correct the enthalpy/internal energy field boundaries. More...

Protected Attributes
volScalarField	he_
	Energy field. More...

Detailed Description

template<class BasicThermo, class MixtureType>
class Foam::heThermo< BasicThermo, MixtureType >

Enthalpy/Internal energy for a mixture.

Source files

Definition at line 49 of file heThermo.H.

Constructor & Destructor Documentation

◆ heThermo() [1/2]

heThermo	(	const fvMesh &	mesh,
		const word &	phaseName
	)

Construct from mesh.

Definition at line 88 of file heThermo.C.

◆ heThermo() [2/2]

heThermo	(	const fvMesh &	mesh,
		const dictionary &	dict,
		const word &	phaseName
	)

Construct from mesh and dictionary.

Definition at line 121 of file heThermo.C.

◆ ~heThermo()

~heThermo ( )

virtual

Destructor.

Definition at line 156 of file heThermo.C.

Member Function Documentation

◆ heBoundaryCorrection()

void heBoundaryCorrection ( volScalarField & he )

protected

Correct the enthalpy/internal energy field boundaries.

Definition at line 34 of file heThermo.C.

◆ composition() [1/2]

virtual MixtureType::basicMixtureType& composition ( )

inlinevirtual

Return the compostion of the mixture.

Definition at line 110 of file heThermo.H.

◆ composition() [2/2]

virtual const MixtureType::basicMixtureType& composition ( ) const

inlinevirtual

Return the compostion of the mixture.

Definition at line 117 of file heThermo.H.

◆ thermoName()

virtual word thermoName ( ) const

inlinevirtual

Return the name of the thermo physics.

Definition at line 123 of file heThermo.H.

◆ incompressible()

virtual bool incompressible ( ) const

inlinevirtual

Return true if the equation of state is incompressible.

i.e. rho != f(p)

Definition at line 130 of file heThermo.H.

Referenced by heThermo< BasicSolidThermo, MixtureType >::thermoName().

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◆ isochoric()

virtual bool isochoric ( ) const

inlinevirtual

Return true if the equation of state is isochoric.

i.e. rho = const

Definition at line 137 of file heThermo.H.

Referenced by heThermo< BasicSolidThermo, MixtureType >::thermoName().

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◆ he() [1/5]

virtual volScalarField& he ( )

inlinevirtual

Enthalpy/Internal energy [J/kg].

Non-const access allowed for transport equations

Definition at line 147 of file heThermo.H.

Referenced by heThermo< BasicSolidThermo, MixtureType >::he(), heThermo< BasicSolidThermo, MixtureType >::thermoName(), and heThermo< BasicSolidThermo, MixtureType >::~heThermo().

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◆ he() [2/5]

virtual const volScalarField& he ( ) const

inlinevirtual

Enthalpy/Internal energy [J/kg].

Definition at line 153 of file heThermo.H.

◆ he() [3/5]

Foam::tmp< Foam::volScalarField > he	(	const volScalarField &	p,
		const volScalarField &	T
	)		const

virtual

Enthalpy/Internal energy.

for given pressure and temperature [J/kg]

Definition at line 164 of file heThermo.C.

◆ he() [4/5]

Foam::tmp< Foam::scalarField > he	(	const scalarField &	p,
		const scalarField &	T,
		const labelList &	cells
	)		const

virtual

Enthalpy/Internal energy for cell-set [J/kg].

Definition at line 213 of file heThermo.C.

◆ he() [5/5]

Foam::tmp< Foam::scalarField > he	(	const scalarField &	p,
		const scalarField &	T,
		const label	patchi
	)		const

virtual

Enthalpy/Internal energy for patch [J/kg].

Definition at line 233 of file heThermo.C.

◆ hc()

Foam::tmp< Foam::volScalarField > hc ( ) const

virtual

Chemical enthalpy [J/kg].

Definition at line 254 of file heThermo.C.

Referenced by heThermo< BasicSolidThermo, MixtureType >::he().

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◆ THE() [1/2]

Foam::tmp< Foam::scalarField > THE	(	const scalarField &	he,
		const scalarField &	p,
		const scalarField &	T0,
		const labelList &	cells
	)		const

virtual

Temperature from enthalpy/internal energy for cell-set.

Definition at line 622 of file heThermo.C.

Referenced by heThermo< BasicSolidThermo, MixtureType >::CpByCpv(), heThermo< BasicSolidThermo, MixtureType >::he(), and heThermo< BasicSolidThermo, MixtureType >::THE().

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◆ THE() [2/2]

Foam::tmp< Foam::scalarField > THE	(	const scalarField &	he,
		const scalarField &	p,
		const scalarField &	T0,
		const label	patchi
	)		const

virtual

Temperature from enthalpy/internal energy for patch.

Definition at line 644 of file heThermo.C.

◆ Cp() [1/2]

Foam::tmp< Foam::scalarField > Cp	(	const scalarField &	p,
		const scalarField &	T,
		const label	patchi
	)		const

virtual

Heat capacity at constant pressure for patch [J/kg/K].

Definition at line 294 of file heThermo.C.

◆ Cp() [2/2]

Foam::tmp< Foam::volScalarField > Cp ( ) const

virtual

Heat capacity at constant pressure [J/kg/K].

Definition at line 315 of file heThermo.C.

Referenced by heThermo< BasicSolidThermo, MixtureType >::hc(), and heThermo< BasicSolidThermo, MixtureType >::he().

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◆ Cv() [1/2]

Foam::tmp< Foam::scalarField > Cv	(	const scalarField &	p,
		const scalarField &	T,
		const label	patchi
	)		const

virtual

Heat capacity at constant volume for patch [J/kg/K].

Definition at line 359 of file heThermo.C.

◆ Cv() [2/2]

Foam::tmp< Foam::volScalarField > Cv ( ) const

virtual

Heat capacity at constant volume [J/kg/K].

Definition at line 380 of file heThermo.C.

Referenced by heThermo< BasicSolidThermo, MixtureType >::Cp(), and heThermo< BasicSolidThermo, MixtureType >::he().

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◆ gamma() [1/2]

Foam::tmp< Foam::volScalarField > gamma ( ) const

virtual

Gamma = Cp/Cv [].

Definition at line 441 of file heThermo.C.

Referenced by heThermo< BasicSolidThermo, MixtureType >::Cv(), and heThermo< BasicSolidThermo, MixtureType >::he().

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◆ gamma() [2/2]

Foam::tmp< Foam::scalarField > gamma	(	const scalarField &	p,
		const scalarField &	T,
		const label	patchi
	)		const

virtual

Gamma = Cp/Cv for patch [].

Definition at line 420 of file heThermo.C.

◆ Cpv() [1/2]

Foam::tmp< Foam::scalarField > Cpv	(	const scalarField &	p,
		const scalarField &	T,
		const label	patchi
	)		const

virtual

Heat capacity at constant pressure/volume for patch [J/kg/K].

Definition at line 487 of file heThermo.C.

◆ Cpv() [2/2]

Foam::tmp< Foam::volScalarField > Cpv ( ) const

virtual

Heat capacity at constant pressure/volume [J/kg/K].

Definition at line 508 of file heThermo.C.

Referenced by heThermo< BasicSolidThermo, MixtureType >::gamma(), and heThermo< BasicSolidThermo, MixtureType >::he().

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◆ CpByCpv() [1/2]

Foam::tmp< Foam::volScalarField > CpByCpv ( ) const

virtual

Heat capacity ratio [].

Definition at line 572 of file heThermo.C.

Referenced by heThermo< BasicSolidThermo, MixtureType >::Cpv(), and heThermo< BasicSolidThermo, MixtureType >::he().

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◆ CpByCpv() [2/2]

Foam::tmp< Foam::scalarField > CpByCpv	(	const scalarField &	p,
		const scalarField &	T,
		const label	patchi
	)		const

virtual

Heat capacity ratio for patch [].

Definition at line 551 of file heThermo.C.

◆ W() [1/2]

Foam::tmp< Foam::volScalarField > W ( ) const

virtual

Molecular weight [kg/kmol].

Definition at line 669 of file heThermo.C.

Referenced by heThermo< BasicSolidThermo, MixtureType >::he(), heThermo< BasicSolidThermo, MixtureType >::THE(), and heThermo< BasicSolidThermo, MixtureType >::W().

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◆ W() [2/2]

Foam::tmp< Foam::scalarField > W ( const label patchi ) const

virtual

Molecular weight for patch [kg/kmol].

Definition at line 709 of file heThermo.C.

◆ kappa() [1/2]

Foam::tmp< Foam::volScalarField > kappa ( ) const

virtual

Thermal diffusivity for temperature of mixture [W/m/K].

Definition at line 728 of file heThermo.C.

Referenced by heThermo< BasicSolidThermo, MixtureType >::he(), and heThermo< BasicSolidThermo, MixtureType >::kappa().

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◆ kappa() [2/2]

Foam::tmp< Foam::scalarField > kappa ( const label patchi ) const

virtual

Thermal diffusivity for temperature of mixture.

for patch [W/m/K]

Definition at line 738 of file heThermo.C.

◆ alphahe() [1/2]

Foam::tmp< Foam::volScalarField > alphahe ( ) const

virtual

Thermal diffusivity for energy of mixture [kg/m/s].

Definition at line 754 of file heThermo.C.

Referenced by heThermo< BasicSolidThermo, MixtureType >::he().

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◆ alphahe() [2/2]

Foam::tmp< Foam::scalarField > alphahe ( const label patchi ) const

virtual

Thermal diffusivity for energy of mixture for patch [kg/m/s].

Definition at line 764 of file heThermo.C.

◆ kappaEff() [1/2]

Foam::tmp< Foam::volScalarField > kappaEff ( const volScalarField & alphat ) const

virtual

Effective thermal turbulent diffusivity for temperature.

of mixture [W/m/K]

Definition at line 780 of file heThermo.C.

Referenced by heThermo< BasicSolidThermo, MixtureType >::alphahe(), heThermo< BasicSolidThermo, MixtureType >::he(), and heThermo< BasicSolidThermo, MixtureType >::kappaEff().

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◆ kappaEff() [2/2]

Foam::tmp< Foam::scalarField > kappaEff	(	const scalarField &	alphat,
		const label	patchi
	)		const

virtual

Effective thermal turbulent diffusivity for temperature.

of mixture for patch [W/m/K]

Definition at line 793 of file heThermo.C.

◆ alphaEff() [1/2]

Foam::tmp< Foam::volScalarField > alphaEff ( const volScalarField & alphat ) const

virtual

Effective thermal turbulent diffusivity of mixture [kg/m/s].

Definition at line 815 of file heThermo.C.

Referenced by heThermo< BasicSolidThermo, MixtureType >::alphaEff(), heThermo< BasicSolidThermo, MixtureType >::he(), and heThermo< BasicSolidThermo, MixtureType >::kappaEff().

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◆ alphaEff() [2/2]

Foam::tmp< Foam::scalarField > alphaEff	(	const scalarField &	alphat,
		const label	patchi
	)		const

virtual

Effective thermal turbulent diffusivity of mixture.

for patch [kg/m/s]

Definition at line 828 of file heThermo.C.

◆ read()

bool read ( )

virtual

Read thermophysical properties dictionary.

Definition at line 848 of file heThermo.C.

Referenced by heThermo< BasicSolidThermo, MixtureType >::he().

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Member Data Documentation

◆ he_

volScalarField he_

protected

Energy field.

Definition at line 59 of file heThermo.H.

Referenced by heThermo< BasicSolidThermo, MixtureType >::he(), and heThermo< BasicSolidThermo, MixtureType >::thermoName().

The documentation for this class was generated from the following files:

src/thermophysicalModels/basic/heThermo/heThermo.H
src/thermophysicalModels/basic/heThermo/heThermo.C

Public Member Functions

Protected Member Functions

Protected Attributes

Detailed Description

template<class BasicThermo, class MixtureType> class Foam::heThermo< BasicThermo, MixtureType >

Constructor & Destructor Documentation

◆ heThermo() [1/2]

◆ heThermo() [2/2]

◆ ~heThermo()

Member Function Documentation

◆ heBoundaryCorrection()

◆ composition() [1/2]

◆ composition() [2/2]

◆ thermoName()

◆ incompressible()

◆ isochoric()

◆ he() [1/5]

◆ he() [2/5]

◆ he() [3/5]

◆ he() [4/5]

◆ he() [5/5]

◆ hc()

◆ THE() [1/2]

◆ THE() [2/2]

◆ Cp() [1/2]

◆ Cp() [2/2]

◆ Cv() [1/2]

◆ Cv() [2/2]

◆ gamma() [1/2]

◆ gamma() [2/2]

◆ Cpv() [1/2]

◆ Cpv() [2/2]

◆ CpByCpv() [1/2]

◆ CpByCpv() [2/2]

◆ W() [1/2]

◆ W() [2/2]

◆ kappa() [1/2]

◆ kappa() [2/2]

◆ alphahe() [1/2]

◆ alphahe() [2/2]

◆ kappaEff() [1/2]

◆ kappaEff() [2/2]

◆ alphaEff() [1/2]

◆ alphaEff() [2/2]

◆ read()

Member Data Documentation

◆ he_

template<class BasicThermo, class MixtureType>
class Foam::heThermo< BasicThermo, MixtureType >