76 #ifndef VoFCavitation_H
77 #define VoFCavitation_H
80 #include "cavitationModel.H"
87 class compressibleTwoPhaseVoFMixture;
91 namespace compressible
114 TypeName(
"compressible::VoFCavitation");
122 const word& sourceName,
123 const word& modelType,
Generic GeometricField class.
Class to represent a mixture of two rhoFluidThermo-based phases.
A list of keyword definitions, which are a keyword followed by any number of values (e....
A special matrix type and solver, designed for finite volume solutions of scalar equations....
Mesh data needed to do the Finite Volume discretisation.
Finite volume model abstract base class.
const fvMesh & mesh() const
Return const access to the mesh database.
virtual bool movePoints()
Update for mesh motion.
virtual wordList addSupFields() const
Return the list of fields for which the option adds source term.
virtual void correct()
Correct the cavitation model.
virtual void topoChange(const polyTopoChangeMap &)
Update topology using the given map.
virtual void distribute(const polyDistributionMap &)
Redistribute or update using the given distribution map.
virtual void mapMesh(const polyMeshMap &)
Update from another mesh using the given map.
TypeName("compressible::VoFCavitation")
Runtime type information.
virtual void addSup(const volScalarField &alpha, const volScalarField &rho, fvMatrix< scalar > &eqn) const
Add a source to the phase continuity equation.
void operator=(const VoFCavitation &)=delete
Disallow default bitwise assignment.
VoFCavitation(const word &sourceName, const word &modelType, const fvMesh &mesh, const dictionary &dict)
Construct from explicit source name and mesh.
Class containing mesh-to-mesh mapping information after a mesh distribution where we send parts of me...
Class containing mesh-to-mesh mapping information.
Class containing mesh-to-mesh mapping information after a change in polyMesh topology.
A class for handling words, derived from string.
volScalarField alpha(IOobject("alpha", runTime.name(), mesh, IOobject::READ_IF_PRESENT, IOobject::AUTO_WRITE), lambda *max(Ua &U, zeroSensitivity))