Cantera
2.2.1
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Class DustyGasTransport implements the Dusty Gas model for transport in porous media. More...
#include <DustyGasTransport.h>
Public Member Functions | |
DustyGasTransport (thermo_t *thermo=0) | |
default constructor More... | |
DustyGasTransport (const DustyGasTransport &right) | |
DustyGasTransport & | operator= (const DustyGasTransport &right) |
Assignment operator. More... | |
virtual Transport * | duplMyselfAsTransport () const |
Duplication routine for objects which inherit from Transport. More... | |
virtual void | setThermo (thermo_t &thermo) |
Specifies the ThermoPhase object. More... | |
virtual int | model () const |
Transport model. More... | |
virtual void | setParameters (const int type, const int k, const doublereal *const p) |
Set the Parameters in the model. More... | |
virtual void | getMultiDiffCoeffs (const size_t ld, doublereal *const d) |
Return the Multicomponent diffusion coefficients. Units: [m^2/s]. More... | |
virtual void | getMolarFluxes (const doublereal *const state1, const doublereal *const state2, const doublereal delta, doublereal *const fluxes) |
Get the molar fluxes [kmol/m^2/s], given the thermodynamic state at two nearby points. More... | |
void | setPorosity (doublereal porosity) |
Set the porosity (dimensionless) More... | |
void | setTortuosity (doublereal tort) |
Set the tortuosity (dimensionless) More... | |
void | setMeanPoreRadius (doublereal rbar) |
Set the mean pore radius (m) More... | |
void | setMeanParticleDiameter (doublereal dbar) |
Set the mean particle diameter. More... | |
void | setPermeability (doublereal B) |
Set the permeability of the media. More... | |
Transport & | gasTransport () |
Return a reference to the transport manager used to compute the gas binary diffusion coefficients and the viscosity. More... | |
Public Member Functions inherited from Transport | |
Transport (thermo_t *thermo=0, size_t ndim=1) | |
Constructor. More... | |
Transport (const Transport &right) | |
Transport & | operator= (const Transport &right) |
thermo_t & | thermo () |
bool | ready () |
void | setNDim (const int ndim) |
Set the number of dimensions to be expected in flux expressions. More... | |
size_t | nDim () const |
Return the number of dimensions in flux expressions. More... | |
void | checkSpeciesIndex (size_t k) const |
Check that the specified species index is in range Throws an exception if k is greater than nSpecies() More... | |
void | checkSpeciesArraySize (size_t kk) const |
Check that an array size is at least nSpecies() Throws an exception if kk is less than nSpecies(). More... | |
virtual doublereal | getElectricConduct () |
Compute the mixture electrical conductivity (S m-1) at the current conditions of the phase (Siemens m-1) More... | |
virtual void | getElectricCurrent (int ndim, const doublereal *grad_T, int ldx, const doublereal *grad_X, int ldf, const doublereal *grad_V, doublereal *current) |
Compute the electric current density in A/m^2. More... | |
virtual void | getSpeciesFluxes (size_t ndim, const doublereal *const grad_T, size_t ldx, const doublereal *const grad_X, size_t ldf, doublereal *const fluxes) |
Get the species diffusive mass fluxes wrt to the specified solution averaged velocity, given the gradients in mole fraction and temperature. More... | |
virtual void | getSpeciesFluxesES (size_t ndim, const doublereal *grad_T, size_t ldx, const doublereal *grad_X, size_t ldf, const doublereal *grad_Phi, doublereal *fluxes) |
Get the species diffusive mass fluxes wrt to the mass averaged velocity, given the gradients in mole fraction, temperature and electrostatic potential. More... | |
virtual void | getSpeciesVdiff (size_t ndim, const doublereal *grad_T, int ldx, const doublereal *grad_X, int ldf, doublereal *Vdiff) |
Get the species diffusive velocities wrt to the mass averaged velocity, given the gradients in mole fraction and temperature. More... | |
virtual void | getSpeciesVdiffES (size_t ndim, const doublereal *grad_T, int ldx, const doublereal *grad_X, int ldf, const doublereal *grad_Phi, doublereal *Vdiff) |
Get the species diffusive velocities wrt to the mass averaged velocity, given the gradients in mole fraction, temperature, and electrostatic potential. More... | |
virtual void | getMassFluxes (const doublereal *state1, const doublereal *state2, doublereal delta, doublereal *mfluxes) |
Get the mass fluxes [kg/m^2/s], given the thermodynamic state at two nearby points. More... | |
virtual void | getThermalDiffCoeffs (doublereal *const dt) |
Return a vector of Thermal diffusion coefficients [kg/m/sec]. More... | |
virtual void | getBinaryDiffCoeffs (const size_t ld, doublereal *const d) |
Returns the matrix of binary diffusion coefficients [m^2/s]. More... | |
virtual void | getMixDiffCoeffs (doublereal *const d) |
Returns a vector of mixture averaged diffusion coefficients. More... | |
virtual void | getMixDiffCoeffsMole (doublereal *const d) |
Returns a vector of mixture averaged diffusion coefficients. More... | |
virtual void | getMixDiffCoeffsMass (doublereal *const d) |
Returns a vector of mixture averaged diffusion coefficients. More... | |
void | setVelocityBasis (VelocityBasis ivb) |
Sets the velocity basis. More... | |
VelocityBasis | getVelocityBasis () const |
Gets the velocity basis. More... | |
virtual doublereal | viscosity () |
virtual void | getSpeciesViscosities (doublereal *const visc) |
Returns the pure species viscosities. More... | |
virtual doublereal | bulkViscosity () |
The bulk viscosity in Pa-s. More... | |
virtual doublereal | ionConductivity () |
The ionic conductivity in 1/ohm/m. More... | |
virtual void | getSpeciesIonConductivity (doublereal *const ionCond) |
Returns the pure species ionic conductivity. More... | |
virtual void | mobilityRatio (double *mobRat) |
Returns the pointer to the mobility ratios of the species in the phase. More... | |
virtual void | getSpeciesMobilityRatio (double **mobRat) |
Returns the pure species limit of the mobility ratios. More... | |
virtual void | selfDiffusion (doublereal *const selfDiff) |
Returns the self diffusion coefficients of the species in the phase. More... | |
virtual void | getSpeciesSelfDiffusion (double **selfDiff) |
Returns the pure species self diffusion in solution of each species. More... | |
virtual doublereal | thermalConductivity () |
Returns the mixture thermal conductivity in W/m/K. More... | |
virtual doublereal | electricalConductivity () |
virtual void | getMobilities (doublereal *const mobil_e) |
Get the Electrical mobilities (m^2/V/s). More... | |
virtual void | getFluidMobilities (doublereal *const mobil_f) |
Get the fluid mobilities (s kmol/kg). More... | |
virtual void | init (thermo_t *thermo, int mode=0, int log_level=0) |
Initialize a transport manager. More... | |
virtual bool | initLiquid (LiquidTransportParams &tr) |
Called by TransportFactory to set parameters. More... | |
virtual bool | initSolid (SolidTransportData &tr) |
Called by TransportFactory to set parameters. More... | |
Protected Member Functions | |
void | initialize (ThermoPhase *phase, Transport *gastr) |
Initialization routine called by TransportFactory. More... | |
Protected Member Functions inherited from Transport | |
void | finalize () |
Enable the transport object for use. More... | |
Private Member Functions | |
void | updateTransport_T () |
Update temperature-dependent quantities within the object. More... | |
void | updateTransport_C () |
Update concentration-dependent quantities within the object. More... | |
void | updateBinaryDiffCoeffs () |
Private routine to update the dusty gas binary diffusion coefficients. More... | |
void | updateMultiDiffCoeffs () |
Update the Multicomponent diffusion coefficients that are used in the approximation. More... | |
void | updateKnudsenDiffCoeffs () |
Update the Knudsen diffusion coefficients. More... | |
void | eval_H_matrix () |
Calculate the H matrix. More... | |
Private Attributes | |
vector_fp | m_mw |
Local copy of the species molecular weights. More... | |
DenseMatrix | m_d |
binary diffusion coefficients More... | |
vector_fp | m_x |
mole fractions More... | |
vector_fp | m_dk |
Knudsen diffusion coefficients. More... | |
doublereal | m_temp |
temperature More... | |
DenseMatrix | m_multidiff |
Multicomponent diffusion coefficients. More... | |
vector_fp | m_spwork |
work space of size m_nsp; More... | |
vector_fp | m_spwork2 |
work space of size m_nsp; More... | |
doublereal | m_gradP |
Pressure Gradient. More... | |
bool | m_knudsen_ok |
Update-to-date variable for Knudsen diffusion coefficients. More... | |
bool | m_bulk_ok |
Update-to-date variable for Binary diffusion coefficients. More... | |
doublereal | m_porosity |
Porosity. More... | |
doublereal | m_tortuosity |
Tortuosity. More... | |
doublereal | m_pore_radius |
Pore radius (meter) More... | |
doublereal | m_diam |
Particle diameter. More... | |
doublereal | m_perm |
Permeability of the media. More... | |
Transport * | m_gastran |
Pointer to the transport object for the gas phase. More... | |
Friends | |
class | TransportFactory |
Make the TransportFactory object a friend, because this object has restricted its instantiation to classes which are friends. More... | |
Additional Inherited Members | |
Protected Attributes inherited from Transport | |
thermo_t * | m_thermo |
pointer to the object representing the phase More... | |
bool | m_ready |
true if finalize has been called More... | |
size_t | m_nsp |
Number of species. More... | |
size_t | m_nDim |
Number of dimensions used in flux expressions. More... | |
int | m_velocityBasis |
Velocity basis from which diffusion velocities are computed. More... | |
Class DustyGasTransport implements the Dusty Gas model for transport in porous media.
As implemented here, only species transport is handled. The viscosity, thermal conductivity, and thermal diffusion coefficients are not implemented.
The dusty gas model includes the effects of Darcy's law. There is a net flux of species due to a pressure gradient that is part of Darcy's law.
The dusty gas model expresses the value of the molar flux of species \( k \), \( J_k \) by the following formula.
\[ \sum_{j \ne k}{\frac{X_j J_k - X_k J_j}{D^e_{kj}}} + \frac{J_k}{\mathcal{D}^{e}_{k,knud}} = - \nabla C_k - \frac{C_k}{\mathcal{D}^{e}_{k,knud}} \frac{\kappa}{\mu} \nabla p \]
\( j \) is a sum over all species in the gas.
The effective Knudsen diffusion coefficients are given by the following form
\[ \mathcal{D}^e_{k,knud} = \frac{2}{3} \frac{r_{pore} \phi}{\tau} \left( \frac{8 R T}{\pi W_k} \right)^{1/2} \]
The effective knudsen diffusion coefficients take into account the effects of collisions of gas-phase molecules with the wall.
References for the Dusty Gas Model
(1) H. Zhu, R. J. Kee, "Modeling Electrochemical Impedance Spectra in SOFC Button Cells with Internal Methane Reforming," J. Electrochem. Soc., 153(9) A1765-1772 (2006).
(2) H. Zhu, R. J. Kee, V. M. Janardhanan, O. Deutschmann, D. G. Goodwin, J. Electrochem. Soc., 152, A2427 (2005).
(3) E. A. Mason, A. P. Malinauskas," Gas Transport in Porous Media: the Dusty-Gas Model", American Elsevier, New York (1983).
(4) J. W. Veldsink, R. M. J. van Damme, G. F. Versteeg, W. P. M. van Swaaij, "The use of the dusty gas model for the description of mass transport with chemical reaction in porous media," Chemical Engineering Journal, 57, 115 - 125 (1995).
Definition at line 62 of file DustyGasTransport.h.
DustyGasTransport | ( | thermo_t * | thermo = 0 | ) |
default constructor
thermo | Pointer to the ThermoPhase object for this phase. Defaults to zero. |
Definition at line 18 of file DustyGasTransport.cpp.
Referenced by DustyGasTransport::duplMyselfAsTransport().
DustyGasTransport & operator= | ( | const DustyGasTransport & | right | ) |
Assignment operator.
Warning -> Shallow pointer copies are made of m_thermo and m_gastran.. gastran may not point to the correct object after this copy. The routine initialize() must be called after this routine to complete the copy.
right | Reference to DustyGasTransport object to be copied into the current one. |
Definition at line 48 of file DustyGasTransport.cpp.
References DustyGasTransport::duplMyselfAsTransport(), DustyGasTransport::m_bulk_ok, DustyGasTransport::m_d, DustyGasTransport::m_diam, DustyGasTransport::m_dk, DustyGasTransport::m_gastran, DustyGasTransport::m_gradP, DustyGasTransport::m_knudsen_ok, DustyGasTransport::m_multidiff, DustyGasTransport::m_mw, DustyGasTransport::m_perm, DustyGasTransport::m_pore_radius, DustyGasTransport::m_porosity, DustyGasTransport::m_spwork, DustyGasTransport::m_spwork2, DustyGasTransport::m_temp, DustyGasTransport::m_tortuosity, and DustyGasTransport::m_x.
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Duplication routine for objects which inherit from Transport.
This virtual routine can be used to duplicate objects derived from Transport even if the application only has a pointer to Transport to work with.
These routines are basically wrappers around the derived copy constructor.
Reimplemented from Transport.
Definition at line 86 of file DustyGasTransport.cpp.
References DustyGasTransport::DustyGasTransport().
Referenced by DustyGasTransport::operator=().
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Specifies the ThermoPhase object.
We have relaxed this operation so that it will succeed when the underlying old and new ThermoPhase objects have the same number of species and the same names of the species in the same order. The idea here is to allow copy constructors and duplicators to work. In order for them to work, we need a method to switch the internal pointer within the Transport object after the duplication takes place. Also, different thermodynamic instantiations of the same species should also work.
thermo | Reference to the ThermoPhase object that the transport object will use |
Reimplemented from Transport.
Definition at line 92 of file DustyGasTransport.cpp.
References DustyGasTransport::m_gastran, and Transport::setThermo().
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Transport model.
The transport model is the set of equations used to compute the transport properties. This method returns an integer flag that identifies the transport model implemented. The base class returns 0.
Reimplemented from Transport.
Definition at line 92 of file DustyGasTransport.h.
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Set the Parameters in the model.
type | Type of the parameter to set 0 - porosity 1 - tortuosity 2 - mean pore radius 3 - mean particle radius 4 - permeability |
k | Unused int |
p | pointer to double for the input list of parameters |
Reimplemented from Transport.
Definition at line 99 of file DustyGasTransport.cpp.
References DustyGasTransport::setMeanParticleDiameter(), DustyGasTransport::setMeanPoreRadius(), DustyGasTransport::setPermeability(), DustyGasTransport::setPorosity(), DustyGasTransport::setTortuosity(), and Cantera::warn_deprecated().
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Return the Multicomponent diffusion coefficients. Units: [m^2/s].
Returns the array of multicomponent diffusion coefficients.
ld | The dimension of the inner loop of d (usually equal to m_nsp) |
d | flat vector of diffusion coefficients, fortran ordering. d[ld*j+i] is the D_ij diffusion coefficient (the diffusion coefficient for species i due to species j). |
Reimplemented from Transport.
Definition at line 288 of file DustyGasTransport.cpp.
References DustyGasTransport::m_multidiff, Transport::m_nsp, and DustyGasTransport::updateMultiDiffCoeffs().
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Get the molar fluxes [kmol/m^2/s], given the thermodynamic state at two nearby points.
\[ J_k = - \sum_{j = 1, N} \left[D^{multi}_{kj}\right]^{-1} \left( \nabla C_j + \frac{C_j}{\mathcal{D}^{knud}_j} \frac{\kappa}{\mu} \nabla p \right) \]
state1 | Array of temperature, density, and mass fractions for state 1. |
state2 | Array of temperature, density, and mass fractions for state 2. |
delta | Distance from state 1 to state 2 (m). |
fluxes | Vector of species molar fluxes due to diffusional driving force |
Reimplemented from Transport.
Definition at line 207 of file DustyGasTransport.cpp.
References DATA_PTR, Cantera::divide_each(), Cantera::GasConstant, Cantera::increment(), DustyGasTransport::m_diam, DustyGasTransport::m_dk, DustyGasTransport::m_gastran, DustyGasTransport::m_multidiff, DustyGasTransport::m_mw, Transport::m_nsp, DustyGasTransport::m_perm, DustyGasTransport::m_porosity, DustyGasTransport::m_spwork, DustyGasTransport::m_spwork2, Transport::m_thermo, DustyGasTransport::m_tortuosity, Cantera::multiply(), Cantera::scale(), ThermoPhase::setState_TPX(), DustyGasTransport::updateMultiDiffCoeffs(), and Transport::viscosity().
void setPorosity | ( | doublereal | porosity | ) |
Set the porosity (dimensionless)
porosity | Set the value of the porosity |
Definition at line 321 of file DustyGasTransport.cpp.
References DustyGasTransport::m_bulk_ok, DustyGasTransport::m_knudsen_ok, and DustyGasTransport::m_porosity.
Referenced by DustyGasTransport::setParameters().
void setTortuosity | ( | doublereal | tort | ) |
Set the tortuosity (dimensionless)
Tortuosity is considered to be constant within the object
tort | Value of the tortuosity |
Definition at line 328 of file DustyGasTransport.cpp.
References DustyGasTransport::m_bulk_ok, DustyGasTransport::m_knudsen_ok, and DustyGasTransport::m_tortuosity.
Referenced by DustyGasTransport::setParameters().
void setMeanPoreRadius | ( | doublereal | rbar | ) |
Set the mean pore radius (m)
rbar | Value of the pore radius ( m) |
Definition at line 335 of file DustyGasTransport.cpp.
References DustyGasTransport::m_knudsen_ok, and DustyGasTransport::m_pore_radius.
Referenced by DustyGasTransport::setParameters().
void setMeanParticleDiameter | ( | doublereal | dbar | ) |
Set the mean particle diameter.
dbar | Set the mean particle diameter (m) |
Definition at line 341 of file DustyGasTransport.cpp.
References DustyGasTransport::m_diam.
Referenced by DustyGasTransport::setParameters().
void setPermeability | ( | doublereal | B | ) |
Set the permeability of the media.
If not set, the value for close-packed spheres will be used by default.
The value for close-packed spheres is given below, where p is the porosity, t is the tortuosity, and d is the diameter of the sphere
\[ \kappa = \frac{p^3 d^2}{72 t (1 - p)^2} \]
B | set the permeability of the media (units = m^2) |
Definition at line 346 of file DustyGasTransport.cpp.
References DustyGasTransport::m_perm.
Referenced by DustyGasTransport::setParameters().
Transport & gasTransport | ( | ) |
Return a reference to the transport manager used to compute the gas binary diffusion coefficients and the viscosity.
Definition at line 351 of file DustyGasTransport.cpp.
References DustyGasTransport::m_gastran.
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Initialization routine called by TransportFactory.
The DustyGas model is a subordinate model to the gas phase transport model. Here we set the gas phase models.
This is a protected routine, so that initialization of the Model must occur within Cantera's setup
phase | Pointer to the underlying ThermoPhase model for the gas phase |
gastr | Pointer to the underlying Transport model for transport in the gas phase. |
Definition at line 123 of file DustyGasTransport.cpp.
References DATA_PTR, Phase::getMoleFractions(), DustyGasTransport::m_bulk_ok, DustyGasTransport::m_d, DustyGasTransport::m_dk, DustyGasTransport::m_gastran, DustyGasTransport::m_knudsen_ok, DustyGasTransport::m_multidiff, DustyGasTransport::m_mw, Transport::m_nsp, DustyGasTransport::m_spwork, DustyGasTransport::m_spwork2, Transport::m_thermo, DustyGasTransport::m_x, Phase::molecularWeights(), Phase::nSpecies(), and DenseMatrix::resize().
Referenced by TransportFactory::newTransport().
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Update temperature-dependent quantities within the object.
The object keeps a value m_temp, which is the temperature at which quantities were last evaluated at. If the temperature is changed, update Booleans are set false, triggering recomputation.
Definition at line 298 of file DustyGasTransport.cpp.
References DustyGasTransport::m_bulk_ok, DustyGasTransport::m_knudsen_ok, DustyGasTransport::m_temp, Transport::m_thermo, and Phase::temperature().
Referenced by DustyGasTransport::updateMultiDiffCoeffs().
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Update concentration-dependent quantities within the object.
The object keeps a value m_temp, which is the temperature at which quantities were last evaluated at. If the temperature is changed, update Booleans are set false, triggering recomputation.
Definition at line 308 of file DustyGasTransport.cpp.
References DATA_PTR, Phase::getMoleFractions(), DustyGasTransport::m_bulk_ok, Transport::m_nsp, Transport::m_thermo, DustyGasTransport::m_x, and Cantera::Tiny.
Referenced by DustyGasTransport::updateMultiDiffCoeffs().
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Private routine to update the dusty gas binary diffusion coefficients.
The dusty gas binary diffusion coefficients \( D^{dg}_{i,j} \) are evaluated from the binary gas-phase diffusion coefficients \( D^{bin}_{i,j} \) using the following formula
\[ D^{dg}_{i,j} = \frac{\phi}{\tau} D^{bin}_{i,j} \]
where \( \phi \) is the porosity of the media and \( \tau \) is the tortuosity of the media.
Definition at line 153 of file DustyGasTransport.cpp.
References Transport::getBinaryDiffCoeffs(), DustyGasTransport::m_bulk_ok, DustyGasTransport::m_d, DustyGasTransport::m_gastran, Transport::m_nsp, DustyGasTransport::m_porosity, DustyGasTransport::m_tortuosity, and Array2D::ptrColumn().
Referenced by DustyGasTransport::eval_H_matrix().
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Update the Multicomponent diffusion coefficients that are used in the approximation.
This routine updates the H matrix and then inverts it.
Definition at line 269 of file DustyGasTransport.cpp.
References DustyGasTransport::eval_H_matrix(), Cantera::int2str(), Cantera::invert(), DustyGasTransport::m_multidiff, DustyGasTransport::updateTransport_C(), and DustyGasTransport::updateTransport_T().
Referenced by DustyGasTransport::getMolarFluxes(), and DustyGasTransport::getMultiDiffCoeffs().
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Update the Knudsen diffusion coefficients.
The Knudsen diffusion coefficients are given by the following form
\[ \mathcal{D}^{knud}_k = \frac{2}{3} \frac{r_{pore} \phi}{\tau} \left( \frac{8 R T}{\pi W_k} \right)^{1/2} \]
Definition at line 170 of file DustyGasTransport.cpp.
References Cantera::GasConstant, DustyGasTransport::m_dk, DustyGasTransport::m_knudsen_ok, DustyGasTransport::m_mw, Transport::m_nsp, DustyGasTransport::m_pore_radius, DustyGasTransport::m_porosity, DustyGasTransport::m_temp, DustyGasTransport::m_tortuosity, and Cantera::Pi.
Referenced by DustyGasTransport::eval_H_matrix().
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Calculate the H matrix.
The multicomponent diffusion H matrix \( H_{k,l} \) is given by the following form
\[ H_{k,l} = - \frac{X_k}{D_{k,l}} \]
\[ H_{k,k} = \frac{1}{\mathcal(D)^{knud}_{k}} + \sum_{j \ne k}^N{ \frac{X_j}{D_{k,j}} } \]
Definition at line 184 of file DustyGasTransport.cpp.
References DustyGasTransport::m_d, DustyGasTransport::m_dk, DustyGasTransport::m_multidiff, Transport::m_nsp, DustyGasTransport::m_x, DustyGasTransport::updateBinaryDiffCoeffs(), and DustyGasTransport::updateKnudsenDiffCoeffs().
Referenced by DustyGasTransport::updateMultiDiffCoeffs().
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Make the TransportFactory object a friend, because this object has restricted its instantiation to classes which are friends.
Definition at line 192 of file DustyGasTransport.h.
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Local copy of the species molecular weights.
units kg /kmol length = m_nsp;
Definition at line 276 of file DustyGasTransport.h.
Referenced by DustyGasTransport::getMolarFluxes(), DustyGasTransport::initialize(), DustyGasTransport::operator=(), and DustyGasTransport::updateKnudsenDiffCoeffs().
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binary diffusion coefficients
Definition at line 279 of file DustyGasTransport.h.
Referenced by DustyGasTransport::eval_H_matrix(), DustyGasTransport::initialize(), DustyGasTransport::operator=(), and DustyGasTransport::updateBinaryDiffCoeffs().
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mole fractions
Definition at line 282 of file DustyGasTransport.h.
Referenced by DustyGasTransport::eval_H_matrix(), DustyGasTransport::initialize(), DustyGasTransport::operator=(), and DustyGasTransport::updateTransport_C().
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Knudsen diffusion coefficients.
The Knudsen diffusion coefficients are given by the following form
\[ \mathcal{D}^{knud}_k = \frac{2}{3} \frac{r_{pore} \phi}{\tau} \left( \frac{8 R T}{\pi W_k} \right)^{1/2} \]
Definition at line 292 of file DustyGasTransport.h.
Referenced by DustyGasTransport::eval_H_matrix(), DustyGasTransport::getMolarFluxes(), DustyGasTransport::initialize(), DustyGasTransport::operator=(), and DustyGasTransport::updateKnudsenDiffCoeffs().
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temperature
Definition at line 295 of file DustyGasTransport.h.
Referenced by DustyGasTransport::operator=(), DustyGasTransport::updateKnudsenDiffCoeffs(), and DustyGasTransport::updateTransport_T().
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Multicomponent diffusion coefficients.
The multicomponent diffusion matrix \( H_{k,l} \) is given by the following form
\[ H_{k,l} = - \frac{X_k}{D_{k,l}} \]
\[ H_{k,k} = \frac{1}{\mathcal(D)^{knud}_{k}} + \sum_{j \ne k}^N{ \frac{X_j}{D_{k,j}} } \]
Definition at line 308 of file DustyGasTransport.h.
Referenced by DustyGasTransport::eval_H_matrix(), DustyGasTransport::getMolarFluxes(), DustyGasTransport::getMultiDiffCoeffs(), DustyGasTransport::initialize(), DustyGasTransport::operator=(), and DustyGasTransport::updateMultiDiffCoeffs().
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work space of size m_nsp;
Definition at line 311 of file DustyGasTransport.h.
Referenced by DustyGasTransport::getMolarFluxes(), DustyGasTransport::initialize(), and DustyGasTransport::operator=().
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work space of size m_nsp;
Definition at line 314 of file DustyGasTransport.h.
Referenced by DustyGasTransport::getMolarFluxes(), DustyGasTransport::initialize(), and DustyGasTransport::operator=().
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Pressure Gradient.
Definition at line 317 of file DustyGasTransport.h.
Referenced by DustyGasTransport::operator=().
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Update-to-date variable for Knudsen diffusion coefficients.
Definition at line 320 of file DustyGasTransport.h.
Referenced by DustyGasTransport::initialize(), DustyGasTransport::operator=(), DustyGasTransport::setMeanPoreRadius(), DustyGasTransport::setPorosity(), DustyGasTransport::setTortuosity(), DustyGasTransport::updateKnudsenDiffCoeffs(), and DustyGasTransport::updateTransport_T().
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Update-to-date variable for Binary diffusion coefficients.
Definition at line 323 of file DustyGasTransport.h.
Referenced by DustyGasTransport::initialize(), DustyGasTransport::operator=(), DustyGasTransport::setPorosity(), DustyGasTransport::setTortuosity(), DustyGasTransport::updateBinaryDiffCoeffs(), DustyGasTransport::updateTransport_C(), and DustyGasTransport::updateTransport_T().
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Porosity.
Definition at line 326 of file DustyGasTransport.h.
Referenced by DustyGasTransport::getMolarFluxes(), DustyGasTransport::operator=(), DustyGasTransport::setPorosity(), DustyGasTransport::updateBinaryDiffCoeffs(), and DustyGasTransport::updateKnudsenDiffCoeffs().
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Definition at line 329 of file DustyGasTransport.h.
Referenced by DustyGasTransport::getMolarFluxes(), DustyGasTransport::operator=(), DustyGasTransport::setTortuosity(), DustyGasTransport::updateBinaryDiffCoeffs(), and DustyGasTransport::updateKnudsenDiffCoeffs().
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Pore radius (meter)
Definition at line 332 of file DustyGasTransport.h.
Referenced by DustyGasTransport::operator=(), DustyGasTransport::setMeanPoreRadius(), and DustyGasTransport::updateKnudsenDiffCoeffs().
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Particle diameter.
The medium is assumed to consist of particles of size m_diam units = m
Definition at line 339 of file DustyGasTransport.h.
Referenced by DustyGasTransport::getMolarFluxes(), DustyGasTransport::operator=(), and DustyGasTransport::setMeanParticleDiameter().
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Permeability of the media.
The permeability is the proportionality constant for Darcy's law which relates discharge rate and viscosity to the applied pressure gradient.
Below is Darcy's law, where \( \kappa \) is the permeability
\[ v = \frac{\kappa}{\mu} \frac{\delta P}{\delta x} \]
units are m2
Definition at line 355 of file DustyGasTransport.h.
Referenced by DustyGasTransport::getMolarFluxes(), DustyGasTransport::operator=(), and DustyGasTransport::setPermeability().
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Pointer to the transport object for the gas phase.
Note, this object owns the gastran object
Definition at line 361 of file DustyGasTransport.h.
Referenced by DustyGasTransport::gasTransport(), DustyGasTransport::getMolarFluxes(), DustyGasTransport::initialize(), DustyGasTransport::operator=(), DustyGasTransport::setThermo(), and DustyGasTransport::updateBinaryDiffCoeffs().