Hagen–Poiseuille-type flux law to describe the advective flux for pore-network models.  
#include <dumux/flux/porenetwork/advection.hh>
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| template<class Problem, class Element, class FVElementGeometry, class ElementVolumeVariables, class SubControlVolumeFace, class ElemFluxVarsCache> | 
| static Scalar | flux (const Problem &problem, const Element &element, const FVElementGeometry &fvGeometry, const ElementVolumeVariables &elemVolVars, const SubControlVolumeFace &scvf, const int phaseIdx, const ElemFluxVarsCache &elemFluxVarsCache) | 
|  | Returns the advective flux of a fluid phase across the given sub-control volume face (corresponding to a pore throat). 
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|  | 
| template<class Problem, class Element, class FVElementGeometry, class ElementVolumeVariables, class FluxVariablesCache> | 
| static Scalar | calculateTransmissibility (const Problem &problem, const Element &element, const FVElementGeometry &fvGeometry, const typename FVElementGeometry::SubControlVolumeFace &scvf, const ElementVolumeVariables &elemVolVars, const FluxVariablesCache &fluxVarsCache, const int phaseIdx) | 
|  | Returns the throat conductivity. 
 | 
|  | 
| template<class Problem, class Element, class FVElementGeometry, class ElementVolumeVariables, class FluxVariablesCache> | 
| static std::array< Scalar, 2 > | calculateTransmissibilities (const Problem &problem, const Element &element, const FVElementGeometry &fvGeometry, const ElementVolumeVariables &elemVolVars, const typename FVElementGeometry::SubControlVolumeFace &scvf, const FluxVariablesCache &fluxVarsCache) | 
|  | 
◆ Scalar
template<class ScalarT, class... TransmissibilityLawTypes> 
      
 
 
◆ Transmissibility
template<class ScalarT, class... TransmissibilityLawTypes> 
      
 
 
◆ calculateTransmissibilities()
template<class ScalarT, class... TransmissibilityLawTypes> 
template<class Problem, class Element, class FVElementGeometry, class ElementVolumeVariables, class FluxVariablesCache> 
  
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          | static std::array< Scalar, 2 > Dumux::PoreNetwork::CreepingFlow< ScalarT, TransmissibilityLawTypes >::calculateTransmissibilities | ( | const Problem & | problem, |  
          |  |  | const Element & | element, |  
          |  |  | const FVElementGeometry & | fvGeometry, |  
          |  |  | const ElementVolumeVariables & | elemVolVars, |  
          |  |  | const typename FVElementGeometry::SubControlVolumeFace & | scvf, |  
          |  |  | const FluxVariablesCache & | fluxVarsCache ) |  | inlinestatic | 
 
 
◆ calculateTransmissibility()
template<class ScalarT, class... TransmissibilityLawTypes> 
template<class Problem, class Element, class FVElementGeometry, class ElementVolumeVariables, class FluxVariablesCache> 
  
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          | static Scalar Dumux::PoreNetwork::CreepingFlow< ScalarT, TransmissibilityLawTypes >::calculateTransmissibility | ( | const Problem & | problem, |  
          |  |  | const Element & | element, |  
          |  |  | const FVElementGeometry & | fvGeometry, |  
          |  |  | const typename FVElementGeometry::SubControlVolumeFace & | scvf, |  
          |  |  | const ElementVolumeVariables & | elemVolVars, |  
          |  |  | const FluxVariablesCache & | fluxVarsCache, |  
          |  |  | const int | phaseIdx ) |  | inlinestatic | 
 
 
◆ flux()
template<class ScalarT, class... TransmissibilityLawTypes> 
template<class Problem, class Element, class FVElementGeometry, class ElementVolumeVariables, class SubControlVolumeFace, class ElemFluxVarsCache> 
  
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          | static Scalar Dumux::PoreNetwork::CreepingFlow< ScalarT, TransmissibilityLawTypes >::flux | ( | const Problem & | problem, |  
          |  |  | const Element & | element, |  
          |  |  | const FVElementGeometry & | fvGeometry, |  
          |  |  | const ElementVolumeVariables & | elemVolVars, |  
          |  |  | const SubControlVolumeFace & | scvf, |  
          |  |  | const int | phaseIdx, |  
          |  |  | const ElemFluxVarsCache & | elemFluxVarsCache ) |  | inlinestatic | 
 
- Note
- The flux is given in N*m, and can be converted into a volume flux (m^3/s) or mass flux (kg/s) by applying an upwind scheme for the mobility (1/viscosity) or the product of density and mobility, respectively. 
 
 
The documentation for this class was generated from the following file: