Dumux::ClosedSystemTestProblem< TypeTag > Class Template Reference

Test problem for the one-phase (Navier-) Stokes model. More...

#include <test/freeflow/navierstokes/closedsystem/problem.hh>

Inheritance diagram for Dumux::ClosedSystemTestProblem< TypeTag >:

Description

template<class TypeTag>
class Dumux::ClosedSystemTestProblem< TypeTag >

Test problem for the one-phase (Navier-) Stokes model.

Here, a quadratic two-dimensional domain with closed walls at all sides is considered. If all walls are immobile and gravity is switched on, a hydrostatic pressure gradient will develop. When assigning a fixed velocity to the top wall (without gravity), this test corresponds to a lid-driven cavity problem.

Public Member Functions
	ClosedSystemTestProblem (std::shared_ptr< const GridGeometry > gridGeometry)
Scalar	temperatureAtPos (const GlobalPosition &globalPos) const
	Returns the temperature \(\mathrm{[K]}\) at a given global position. More...
const GravityVector &	gravity () const
	Returns the acceleration due to gravity. More...
bool	enableInertiaTerms () const
	Returns whether interia terms should be considered. More...
template<class SolutionVector , class G = GridGeometry>
std::enable_if< G::discMethod==DiscretizationMethod::staggered, void >::type	applyInitialFaceSolution (SolutionVector &sol, const SubControlVolumeFace &scvf, const PrimaryVariables &initSol) const
	Applys the initial face solution (velocities on the faces). Specialization for staggered grid discretization. More...
Scalar	pseudo3DWallFriction (const Scalar velocity, const Scalar viscosity, const Scalar height, const Scalar factor=8.0) const
	An additional drag term can be included as source term for the momentum balance to mimic 3D flow behavior in 2D: More...
template<class ElementVolumeVariables , class ElementFaceVariables , class G = GridGeometry>
std::enable_if< G::discMethod==DiscretizationMethod::staggered, Scalar >::type	pseudo3DWallFriction (const SubControlVolumeFace &scvf, const ElementVolumeVariables &elemVolVars, const ElementFaceVariables &elemFaceVars, const Scalar height, const Scalar factor=8.0) const
	Convenience function for staggered grid implementation. More...
Scalar	permeability (const Element &element, const SubControlVolumeFace &scvf) const
	Returns the intrinsic permeability of required as input parameter for the Beavers-Joseph-Saffman boundary condition. More...
Scalar	alphaBJ (const SubControlVolumeFace &scvf) const
	Returns the alpha value required as input parameter for the Beavers-Joseph-Saffman boundary condition. More...
Scalar	betaBJ (const Element &element, const SubControlVolumeFace &scvf) const
	Returns the alpha value required as input parameter for the Beavers-Joseph-Saffman boundary condition. More...
Scalar	velocityPorousMedium (const Element &element, const SubControlVolumeFace &scvf) const
	Returns the velocity in the porous medium (which is 0 by default according to Saffmann). More...
const Scalar	bjsVelocity (const Element &element, const SubControlVolume &scv, const SubControlVolumeFace &faceOnPorousBoundary, const Scalar velocitySelf) const
	helper function to evaluate the slip velocity on the boundary when the Beavers-Joseph-Saffman condition is used More...
const Scalar	beaversJosephVelocity (const Element &element, const SubControlVolume &scv, const SubControlVolumeFace &faceOnPorousBoundary, const Scalar velocitySelf, const Scalar tangentialVelocityGradient) const
	helper function to evaluate the slip velocity on the boundary when the Beavers-Joseph condition is used More...
Problem parameters
bool	shouldWriteRestartFile () const
Scalar	temperature () const
	Returns the temperature within the domain in [K]. More...
NumEqVector	sourceAtPos (const GlobalPosition &globalPos) const
	Returns the sources within the domain. More...

Boundary conditions
BoundaryTypes	boundaryTypesAtPos (const GlobalPosition &globalPos) const
	Specifies which kind of boundary condition should be used for which equation on a given boundary control volume. More...
bool	isDirichletCell (const Element &element, const FVElementGeometry &fvGeometry, const SubControlVolume &scv, int pvIdx) const
	Returns whether a fixed Dirichlet value shall be used at a given cell. More...
PrimaryVariables	dirichletAtPos (const GlobalPosition &globalPos) const
	Returns Dirichlet boundary values at a given position. More...
PrimaryVariables	initialAtPos (const GlobalPosition &globalPos) const
	Evaluates the initial value for a control volume. More...

Constructor & Destructor Documentation

ClosedSystemTestProblem()

template<class TypeTag >

Dumux::ClosedSystemTestProblem< TypeTag >::ClosedSystemTestProblem ( std::shared_ptr< const GridGeometry >  gridGeometry )

inline

Member Function Documentation

alphaBJ()

template<class TypeTag >

Scalar Dumux::NavierStokesProblem< TypeTag >::alphaBJ ( const SubControlVolumeFace &  scvf ) const

inlineinherited

Returns the alpha value required as input parameter for the Beavers-Joseph-Saffman boundary condition.

This member function must be overloaded in the problem implementation, if the BJS boundary condition is used.

applyInitialFaceSolution()

template<class TypeTag >

template<class SolutionVector , class G = GridGeometry>

std::enable_if< G::discMethod==DiscretizationMethod::staggered, void >::type Dumux::NavierStokesProblem< TypeTag >::applyInitialFaceSolution ( SolutionVector &  sol, const SubControlVolumeFace &  scvf, const PrimaryVariables &  initSol  ) const

inlineinherited

Applys the initial face solution (velocities on the faces). Specialization for staggered grid discretization.

beaversJosephVelocity()

template<class TypeTag >

const Scalar Dumux::NavierStokesProblem< TypeTag >::beaversJosephVelocity ( const Element &  element, const SubControlVolume &  scv, const SubControlVolumeFace &  faceOnPorousBoundary, const Scalar  velocitySelf, const Scalar  tangentialVelocityGradient  ) const

inlineinherited

helper function to evaluate the slip velocity on the boundary when the Beavers-Joseph condition is used

betaBJ()

template<class TypeTag >

Scalar Dumux::NavierStokesProblem< TypeTag >::betaBJ ( const Element &  element, const SubControlVolumeFace &  scvf  ) const

inlineinherited

Returns the alpha value required as input parameter for the Beavers-Joseph-Saffman boundary condition.

This member function must be overloaded in the problem implementation, if the BJS boundary condition is used.

bjsVelocity()

template<class TypeTag >

const Scalar Dumux::NavierStokesProblem< TypeTag >::bjsVelocity ( const Element &  element, const SubControlVolume &  scv, const SubControlVolumeFace &  faceOnPorousBoundary, const Scalar  velocitySelf  ) const

inlineinherited

helper function to evaluate the slip velocity on the boundary when the Beavers-Joseph-Saffman condition is used

Deprecated:

"Use beaversJosephVelocity(element, scv, faceOnPorousBoundary, velocitySelf, tangentialVelocityGradient) instead"

boundaryTypesAtPos()

template<class TypeTag >

BoundaryTypes Dumux::ClosedSystemTestProblem< TypeTag >::boundaryTypesAtPos ( const GlobalPosition &  globalPos ) const

inline

Specifies which kind of boundary condition should be used for which equation on a given boundary control volume.

Parameters

globalPos

The position of the center of the finite volume

dirichletAtPos()

template<class TypeTag >

PrimaryVariables Dumux::ClosedSystemTestProblem< TypeTag >::dirichletAtPos ( const GlobalPosition &  globalPos ) const

inline

Returns Dirichlet boundary values at a given position.

Parameters

globalPos

The global position

enableInertiaTerms()

template<class TypeTag >

bool Dumux::NavierStokesProblem< TypeTag >::enableInertiaTerms ( ) const

inlineinherited

Returns whether interia terms should be considered.

gravity()

template<class TypeTag >

const GravityVector & Dumux::NavierStokesProblem< TypeTag >::gravity ( ) const

inlineinherited

Returns the acceleration due to gravity.

If the Problem.EnableGravity parameter is true, this means \(\boldsymbol{g} = ( 0,\dots,\ -9.81)^T \), else \(\boldsymbol{g} = ( 0,\dots, 0)^T \)

initialAtPos()

template<class TypeTag >

PrimaryVariables Dumux::ClosedSystemTestProblem< TypeTag >::initialAtPos ( const GlobalPosition &  globalPos ) const

inline

Evaluates the initial value for a control volume.

Parameters

globalPos

The global position

isDirichletCell()

template<class TypeTag >

bool Dumux::ClosedSystemTestProblem< TypeTag >::isDirichletCell ( const Element &  element, const FVElementGeometry &  fvGeometry, const SubControlVolume &  scv, int  pvIdx  ) const

inline

Returns whether a fixed Dirichlet value shall be used at a given cell.

Parameters

element	The finite element
fvGeometry	The finite-volume geometry
scv	The sub control volume
pvIdx	The primary variable index in the solution vector

permeability()

template<class TypeTag >

Scalar Dumux::NavierStokesProblem< TypeTag >::permeability ( const Element &  element, const SubControlVolumeFace &  scvf  ) const

inlineinherited

Returns the intrinsic permeability of required as input parameter for the Beavers-Joseph-Saffman boundary condition.

This member function must be overloaded in the problem implementation, if the BJS boundary condition is used.

pseudo3DWallFriction() [1/2]

template<class TypeTag >

Scalar Dumux::NavierStokesProblem< TypeTag >::pseudo3DWallFriction ( const Scalar  velocity, const Scalar  viscosity, const Scalar  height, const Scalar  factor = 8.0  ) const

inlineinherited

An additional drag term can be included as source term for the momentum balance to mimic 3D flow behavior in 2D:

\[ f_{drag} = -(8 \mu / h^2)v \]

Here, \(h\) corresponds to the extruded height that is bounded by the imaginary walls. See Flekkoy et al. (1995) [25]
A value of 8.0 is used as a default factor, corresponding to the velocity profile at the center plane of the virtual height (maximum velocity). Setting this value to 12.0 corresponds to an depth-averaged velocity (Venturoli and Boek, 2006) [74].

pseudo3DWallFriction() [2/2]

template<class TypeTag >

template<class ElementVolumeVariables , class ElementFaceVariables , class G = GridGeometry>

std::enable_if< G::discMethod==DiscretizationMethod::staggered, Scalar >::type Dumux::NavierStokesProblem< TypeTag >::pseudo3DWallFriction ( const SubControlVolumeFace &  scvf, const ElementVolumeVariables &  elemVolVars, const ElementFaceVariables &  elemFaceVars, const Scalar  height, const Scalar  factor = 8.0  ) const

inlineinherited

Convenience function for staggered grid implementation.

shouldWriteRestartFile()

template<class TypeTag >

bool Dumux::ClosedSystemTestProblem< TypeTag >::shouldWriteRestartFile ( ) const

inline

sourceAtPos()

template<class TypeTag >

NumEqVector Dumux::ClosedSystemTestProblem< TypeTag >::sourceAtPos ( const GlobalPosition &  globalPos ) const

inline

Returns the sources within the domain.

Parameters

globalPos

The global position

temperature()

template<class TypeTag >

Scalar Dumux::ClosedSystemTestProblem< TypeTag >::temperature ( ) const

inline

Returns the temperature within the domain in [K].

This problem assumes a temperature of 10 degrees Celsius.

temperatureAtPos()

template<class TypeTag >

Scalar Dumux::NavierStokesProblem< TypeTag >::temperatureAtPos ( const GlobalPosition &  globalPos ) const

inlineinherited

Returns the temperature \(\mathrm{[K]}\) at a given global position.

This is not specific to the discretization. By default it just calls temperature().

Parameters

globalPos

The position in global coordinates where the temperature should be specified.

velocityPorousMedium()

template<class TypeTag >

Scalar Dumux::NavierStokesProblem< TypeTag >::velocityPorousMedium ( const Element &  element, const SubControlVolumeFace &  scvf  ) const

inlineinherited

Returns the velocity in the porous medium (which is 0 by default according to Saffmann).

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

• test/freeflow/navierstokes/closedsystem/problem.hh