psiuMulticomponentThermo Class Reference

Base-class for combustion fluid thermodynamic properties based on compressibility. More...

Inheritance diagram for psiuMulticomponentThermo:

Collaboration diagram for psiuMulticomponentThermo:

Classes
class	composite
class	implementation

Public Types
template<class MixtureType >
using	DerivedThermoType = PsiuMulticomponentThermo< BasicThermo< MixtureType, composite > >
	The derived type. More...
Public Types inherited from psiThermo
template<class MixtureType >
using	DerivedThermoType = PsiThermo< BasicThermo< MixtureType, composite > >
	The derived type. More...

Public Member Functions
	TypeName ("psiuMulticomponentThermo")
	Runtime type information. More...
	declareRunTimeSelectionTable (autoPtr, psiuMulticomponentThermo, fvMesh,(const fvMesh &mesh, const word &phaseName),(mesh, phaseName))
virtual	~psiuMulticomponentThermo ()
	Destructor. More...
virtual const speciesTable &	species () const =0
	The table of species. More...
bool	containsSpecie (const word &specieName) const
	Does the mixture include this specie? More...
virtual PtrList< volScalarField > &	Y ()=0
	Access the mass-fraction fields. More...
virtual const PtrList< volScalarField > &	Y () const =0
	Access the mass-fraction fields. More...
volScalarField &	Y (const word &specieName)
	Return the mass-fraction field for a specie given by name. More...
const volScalarField &	Y (const word &specieName) const
	Return the const mass-fraction field for a specie given by name. More...
virtual tmp< volScalarField >	fres () const =0
	Return the residual fraction of fuel in the burnt mixture. More...
virtual void	reset ()=0
	Reset the mixture to an unburnt state and update EGR. More...
virtual const volScalarField &	Tu () const =0
	Unburnt gas temperature [K]. More...
virtual const volScalarField &	heu () const =0
	Unburnt gas enthalpy [J/kg]. More...
virtual volScalarField &	heu ()=0
	Unburnt gas enthalpy [J/kg]. More...
virtual tmp< scalarField >	heu (const scalarField &T, const labelList &cells) const =0
	Unburnt gas enthalpy for cell-set [J/kg]. More...
virtual tmp< scalarField >	heu (const scalarField &T, const label patchi) const =0
	Unburnt gas enthalpy for patch [J/kg]. More...
virtual tmp< volScalarField >	hr () const =0
	Standard enthalpy of reaction [J/kg]. More...
virtual tmp< volScalarField >	Tb () const =0
	Burnt gas temperature [K]. More...
virtual tmp< volScalarField >	psiu () const =0
	Unburnt gas compressibility [s^2/m^2]. More...
virtual tmp< volScalarField >	psib () const =0
	Burnt gas compressibility [s^2/m^2]. More...
tmp< volScalarField >	rhou () const
	Unburnt gas density [kg/m^3]. More...
tmp< volScalarField >	rhob () const
	Burnt gas density [kg/m^3]. More...
virtual tmp< volScalarField >	muu () const =0
	Dynamic viscosity of unburnt gas [kg/m/s]. More...
virtual tmp< volScalarField >	mub () const =0
	Dynamic viscosity of burnt gas [kg/m/s]. More...
Public Member Functions inherited from psiThermo
	TypeName ("psiThermo")
	Runtime type information. More...
	declareRunTimeSelectionTable (autoPtr, psiThermo, fvMesh,(const fvMesh &mesh, const word &phaseName),(mesh, phaseName))
	Declare run-time constructor selection table. More...
virtual	~psiThermo ()
	Destructor. More...
virtual tmp< volScalarField >	rho () const =0
	Density [kg/m^3] - uses current value of pressure. More...
virtual tmp< scalarField >	rho (const label patchi) const =0
	Density for patch [kg/m^3]. More...
virtual tmp< volScalarField >	renameRho ()
	Return the thermodynamic density field [kg/m^3]. More...
virtual void	correctRho (const volScalarField &deltaRho)
	Add the given density correction to the density field. More...
Public Member Functions inherited from fluidThermo
	TypeName ("fluidThermo")
	Runtime type information. More...
	declareRunTimeSelectionTable (autoPtr, fluidThermo, fvMesh,(const fvMesh &mesh, const word &phaseName),(mesh, phaseName))
	Declare run-time constructor selection table. More...
virtual	~fluidThermo ()
	Destructor. More...
virtual const volScalarField &	p () const =0
	Pressure [Pa]. More...
virtual volScalarField &	p ()=0
	Pressure [Pa]. More...
virtual const volScalarField &	psi () const =0
	Compressibility [s^2/m^2]. More...
virtual const volScalarField &	mu () const =0
	Dynamic viscosity of mixture [kg/m/s]. More...
tmp< volScalarField >	nu () const
	Kinematic viscosity of mixture [m^2/s]. More...
tmp< scalarField >	nu (const label patchi) const
	Kinematic viscosity of mixture for patch [m^2/s]. More...
Public Member Functions inherited from basicThermo
	TypeName ("basicThermo")
	Runtime type information. More...
	declareRunTimeSelectionTable (autoPtr, basicThermo, fvMesh,(const fvMesh &mesh, const word &phaseName),(mesh, phaseName))
	Declare run-time constructor selection table. More...
virtual	~basicThermo ()
	Destructor. More...
virtual const IOdictionary &	properties () const =0
	Properties dictionary. More...
virtual IOdictionary &	properties ()=0
	Non-const access the properties dictionary. More...
virtual const fvMesh &	mesh () const =0
	Return const access to the mesh. More...
virtual const word &	phaseName () const =0
	Phase name. More...
word	phasePropertyName (const word &name) const
	Name of a property for a given phase. More...
void	validate (const string &app, const word &) const
	Check that the thermodynamics package is consistent. More...
void	validate (const string &app, const word &, const word &) const
	Check that the thermodynamics package is consistent. More...
virtual void	correct ()=0
	Update properties. More...
virtual word	thermoName () const =0
	Name of the thermo physics. More...
virtual bool	incompressible () const =0
	Return true if the equation of state is incompressible. More...
virtual bool	isochoric () const =0
	Return true if the equation of state is isochoric. More...
virtual Switch	dpdt () const =0
	Should the dpdt term be included in the enthalpy equation. More...
virtual tmp< volScalarField >	W () const =0
	Molecular weight [kg/kmol]. More...
virtual tmp< scalarField >	W (const label patchi) const =0
	Molecular weight for patch [kg/kmol]. More...
virtual const volScalarField &	T () const =0
	Temperature [K]. More...
virtual volScalarField &	T ()=0
	Temperature [K]. More...
virtual const volScalarField &	he () const =0
	Enthalpy/Internal energy [J/kg]. More...
virtual volScalarField &	he ()=0
	Enthalpy/Internal energy [J/kg]. More...
virtual const volScalarField &	Cp () const =0
	Heat capacity at constant pressure [J/kg/K]. More...
virtual const volScalarField &	Cv () const =0
	Heat capacity at constant volume [J/kg/K]. More...
virtual const volScalarField &	Cpv () const =0
	Heat capacity at constant pressure/volume [J/kg/K]. More...
virtual tmp< volScalarField >	he (const volScalarField &p, const volScalarField &T) const =0
	Enthalpy/Internal energy. More...
virtual tmp< volScalarField::Internal >	he (const volScalarField::Internal &p, const volScalarField::Internal &T) const =0
	Enthalpy/Internal energy. More...
virtual tmp< scalarField >	he (const scalarField &T, const labelList &cells) const =0
	Enthalpy/Internal energy for cell-set [J/kg]. More...
virtual tmp< scalarField >	he (const scalarField &T, const label patchi) const =0
	Enthalpy/Internal energy for patch [J/kg]. More...
virtual tmp< volScalarField::Internal >	he (const volScalarField::Internal &T, const fvSource &model, const volScalarField::Internal &source) const =0
	Enthalpy/Internal energy for source [J/kg]. More...
virtual tmp< scalarField >	he (const scalarField &T, const fvSource &model, const scalarField &source, const labelUList &cells) const =0
	Enthalpy/Internal energy for source [J/kg]. More...
virtual tmp< volScalarField >	hs () const =0
	Sensible enthalpy [J/kg]. More...
virtual tmp< volScalarField >	hs (const volScalarField &p, const volScalarField &T) const =0
	Sensible enthalpy. More...
virtual tmp< volScalarField::Internal >	hs (const volScalarField::Internal &p, const volScalarField::Internal &T) const =0
	Sensible enthalpy. More...
virtual tmp< scalarField >	hs (const scalarField &T, const labelList &cells) const =0
	Sensible enthalpy for cell-set [J/kg]. More...
virtual tmp< scalarField >	hs (const scalarField &T, const label patchi) const =0
	Sensible enthalpy for patch [J/kg]. More...
virtual tmp< volScalarField >	ha () const =0
	Absolute enthalpy [J/kg]. More...
virtual tmp< volScalarField >	ha (const volScalarField &p, const volScalarField &T) const =0
	Absolute enthalpy. More...
virtual tmp< volScalarField::Internal >	ha (const volScalarField::Internal &p, const volScalarField::Internal &T) const =0
	Absolute enthalpy. More...
virtual tmp< scalarField >	ha (const scalarField &T, const labelList &cells) const =0
	Absolute enthalpy for cell-set [J/kg]. More...
virtual tmp< scalarField >	ha (const scalarField &T, const label patchi) const =0
	Absolute enthalpy for patch [J/kg]. More...
virtual tmp< scalarField >	Cp (const scalarField &T, const label patchi) const =0
	Heat capacity at constant pressure for patch [J/kg/K]. More...
virtual tmp< scalarField >	Cv (const scalarField &T, const label patchi) const =0
	Heat capacity at constant volume for patch [J/kg/K]. More...
virtual tmp< scalarField >	Cpv (const scalarField &T, const label patchi) const =0
	Heat capacity at constant pressure/volume for patch [J/kg/K]. More...
tmp< volScalarField >	gamma () const
	Gamma = Cp/Cv []. More...
tmp< scalarField >	gamma (const scalarField &T, const label patchi) const
	Gamma = Cp/Cv for patch []. More...
virtual tmp< volScalarField >	The (const volScalarField &h, const volScalarField &p, const volScalarField &T0) const =0
	Temperature from enthalpy/internal energy. More...
virtual tmp< scalarField >	The (const scalarField &h, const scalarField &T0, const labelList &cells) const =0
	Temperature from enthalpy/internal energy for cell-set. More...
virtual tmp< scalarField >	The (const scalarField &h, const scalarField &T0, const label patchi) const =0
	Temperature from enthalpy/internal energy for patch. More...
virtual const volScalarField &	kappa () const =0
	Thermal conductivity of mixture [W/m/K]. More...
template<class FieldType >
const Foam::basicThermo &	lookupThermo (const FieldType &f)
template<class Thermo >
Foam::autoPtr< Thermo >	New (const fvMesh &mesh, const word &phaseName)
Public Member Functions inherited from viscosity
	TypeName ("viscosity")
	Runtime type information. More...
	viscosity ()
	Construct. More...
	viscosity (const viscosity &)=delete
	Disallow default bitwise copy construction. More...
virtual	~viscosity ()
	Destructor. More...
void	operator= (const viscosity &)=delete
	Disallow default bitwise assignment. More...

Static Public Member Functions
static autoPtr< psiuMulticomponentThermo >	New (const fvMesh &, const word &phaseName=word::null)
	Standard selection based on fvMesh. More...
Static Public Member Functions inherited from psiThermo
static autoPtr< psiThermo >	New (const fvMesh &mesh, const word &phaseName=word::null)
	Standard selection based on fvMesh. More...
Static Public Member Functions inherited from fluidThermo
static autoPtr< fluidThermo >	New (const fvMesh &, const word &phaseName=word::null)
	Standard selection based on fvMesh. More...
Static Public Member Functions inherited from basicThermo
static word	phasePropertyName (const word &name, const word &phaseName)
	Name of a property for a given phase. More...
template<class FieldType >
static const basicThermo &	lookupThermo (const FieldType &f)
	Lookup the thermo associated with the given field. More...
static wordList	splitThermoName (const word &thermoName, const int nCmpt)
	Split name of thermo package into a list of the components names. More...
static List< Pair< word > >	thermoNameComponents (const word &thermoName)
	Split name of thermo package into a list of named components names. More...
template<class Thermo >
static autoPtr< Thermo >	New (const fvMesh &, const word &phaseName=word::null)
	Generic New for each of the related thermodynamics packages. More...
static autoPtr< basicThermo >	New (const fvMesh &, const word &phaseName=word::null)
	Specialisation of the Generic New for basicThermo. More...

Static Public Attributes
static const word	derivedThermoName
	The derived name. More...
Static Public Attributes inherited from psiThermo
static const word	derivedThermoName
	The derived name. More...

Protected Member Functions
wordList	heuBoundaryTypes ()
	Return the unburnt enthalpy/internal energy field boundary types. More...
void	heuBoundaryCorrection (volScalarField &heu)
	... More...
Protected Member Functions inherited from basicThermo
wordList	heBoundaryTypes ()
	Enthalpy/internal energy field boundary types. More...
wordList	heBoundaryBaseTypes ()
	Enthalpy/internal energy field boundary base types. More...
HashTable< word >	heSourcesTypes ()
	Enthalpy/internal energy field sources types. More...

Additional Inherited Members
Static Protected Member Functions inherited from basicThermo
static volScalarField &	lookupOrConstruct (const fvMesh &mesh, const char *name)
	Lookup and the named field, or construct it as MUST-READ if it is. More...
template<class Thermo , class Table >
static Table::iterator	lookupCstrIter (const dictionary &thermoTypeDict, Table *tablePtr, const int nCmpt, const char *cmptNames[], const word &thermoTypeName)
	Get the constructor iterator for the given thermo dictionary and. More...
template<class Thermo , class Table >
static Table::iterator	lookupCstrIter (const dictionary &thermoDict, Table *tablePtr)
	Get the constructor iterator for the given thermo dictionary and. More...

Detailed Description

Base-class for combustion fluid thermodynamic properties based on compressibility.

See also

Foam::basicThermo

Source files

• psiuMulticomponentThermo.H
• psiuMulticomponentThermo.C

Definition at line 56 of file psiuMulticomponentThermo.H.

Member Typedef Documentation

DerivedThermoType

using DerivedThermoType = PsiuMulticomponentThermo<BasicThermo<MixtureType, composite> >

The derived type.

Definition at line 87 of file psiuMulticomponentThermo.H.

Constructor & Destructor Documentation

~psiuMulticomponentThermo()

~psiuMulticomponentThermo ( )

virtual

Destructor.

Definition at line 154 of file psiuMulticomponentThermo.C.

Member Function Documentation

heuBoundaryTypes()

Foam::wordList heuBoundaryTypes ( )

protected

Return the unburnt enthalpy/internal energy field boundary types.

by interrogating the temperature field boundary types

Definition at line 48 of file psiuMulticomponentThermo.C.

References GeometricField< Type, GeoMesh, PrimitiveField >::boundaryField(), forAll, patchi, psiuMulticomponentThermo::Tu(), and GeometricBoundaryField< Type, GeoMesh, PrimitiveField >::types().

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heuBoundaryCorrection()

void heuBoundaryCorrection ( volScalarField &  heu )

protected

...

Definition at line 78 of file psiuMulticomponentThermo.C.

References GeometricField< Type, GeoMesh, PrimitiveField >::boundaryFieldRef(), forAll, and patchi.

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TypeName()

TypeName

(

"psiuMulticomponentThermo"

)

Runtime type information.

declareRunTimeSelectionTable()

declareRunTimeSelectionTable	(	autoPtr	,
		psiuMulticomponentThermo	,
		fvMesh	,
		(const fvMesh &mesh, const word &phaseName)	,
		(mesh, phaseName)
	)

New()

Foam::autoPtr< Foam::psiuMulticomponentThermo > New ( const fvMesh &  mesh, const word &  phaseName = word::null  )

static

Standard selection based on fvMesh.

Definition at line 142 of file psiuMulticomponentThermo.C.

References basicThermo::mesh(), and basicThermo::phaseName().

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species()

virtual const speciesTable& species ( ) const

pure virtual

The table of species.

Implemented in psiuMulticomponentThermo::implementation.

Referenced by psiuMulticomponentThermo::containsSpecie().

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containsSpecie()

bool containsSpecie ( const word &  specieName ) const

inline

Does the mixture include this specie?

Definition at line 32 of file psiuMulticomponentThermoI.H.

References hashedWordList::found(), and psiuMulticomponentThermo::species().

Referenced by laminarFlameSpeed::laminarFlameSpeed(), and XiFluid::XiFluid().

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Y() [1/4]

virtual PtrList<volScalarField>& Y ( )

pure virtual

Access the mass-fraction fields.

Implemented in psiuMulticomponentThermo::implementation.

Referenced by XiEqModel::Db(), XiFluid::ftSolve(), and XiFluid::XiFluid().

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Y() [2/4]

virtual const PtrList<volScalarField>& Y ( ) const

pure virtual

Access the mass-fraction fields.

Implemented in psiuMulticomponentThermo::implementation.

Y() [3/4]

Foam::volScalarField & Y ( const word &  specieName )

inline

Return the mass-fraction field for a specie given by name.

Definition at line 41 of file psiuMulticomponentThermoI.H.

References Y.

Y() [4/4]

const Foam::volScalarField & Y ( const word &  specieName ) const

inline

Return the const mass-fraction field for a specie given by name.

Definition at line 50 of file psiuMulticomponentThermoI.H.

References Y.

fres()

virtual tmp<volScalarField> fres ( ) const

pure virtual

Return the residual fraction of fuel in the burnt mixture.

reset()

virtual void reset ( )

pure virtual

Reset the mixture to an unburnt state and update EGR.

Tu()

virtual const volScalarField& Tu ( ) const

pure virtual

Unburnt gas temperature [K].

Referenced by psiuMulticomponentThermo::heuBoundaryTypes().

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heu() [1/4]

virtual const volScalarField& heu ( ) const

pure virtual

Unburnt gas enthalpy [J/kg].

Referenced by XiFluid::XiFluid().

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heu() [2/4]

virtual volScalarField& heu ( )

pure virtual

Unburnt gas enthalpy [J/kg].

Non-const access allowed for transport equations

heu() [3/4]

virtual tmp<scalarField> heu ( const scalarField &  T, const labelList &  cells  ) const

pure virtual

Unburnt gas enthalpy for cell-set [J/kg].

heu() [4/4]

virtual tmp<scalarField> heu ( const scalarField &  T, const label  patchi  ) const

pure virtual

Unburnt gas enthalpy for patch [J/kg].

hr()

virtual tmp<volScalarField> hr ( ) const

pure virtual

Standard enthalpy of reaction [J/kg].

Tb()

virtual tmp<volScalarField> Tb ( ) const

pure virtual

Burnt gas temperature [K].

psiu()

virtual tmp<volScalarField> psiu ( ) const

pure virtual

Unburnt gas compressibility [s^2/m^2].

Referenced by psiuMulticomponentThermo::rhou().

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psib()

virtual tmp<volScalarField> psib ( ) const

pure virtual

Burnt gas compressibility [s^2/m^2].

Referenced by psiuMulticomponentThermo::rhob().

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rhou()

Foam::tmp< Foam::volScalarField > rhou

(

)

const

Unburnt gas density [kg/m^3].

Definition at line 164 of file psiuMulticomponentThermo.C.

References fluidThermo::p(), and psiuMulticomponentThermo::psiu().

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rhob()

Foam::tmp< Foam::volScalarField > rhob

(

)

const

Burnt gas density [kg/m^3].

Definition at line 170 of file psiuMulticomponentThermo.C.

References fluidThermo::p(), and psiuMulticomponentThermo::psib().

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muu()

virtual tmp<volScalarField> muu ( ) const

pure virtual

Dynamic viscosity of unburnt gas [kg/m/s].

mub()

virtual tmp<volScalarField> mub ( ) const

pure virtual

Dynamic viscosity of burnt gas [kg/m/s].

Member Data Documentation

derivedThermoName

const Foam::word derivedThermoName

static

The derived name.

Definition at line 91 of file psiuMulticomponentThermo.H.

---

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

• src/thermophysicalModels/multicomponentThermo/psiuMulticomponentThermo/psiuMulticomponentThermo.H
• src/thermophysicalModels/multicomponentThermo/psiuMulticomponentThermo/psiuMulticomponentThermo.C
• src/thermophysicalModels/multicomponentThermo/psiuMulticomponentThermo/psiuMulticomponentThermoI.H