Basic thermodynamics type based on the use of fitting functions for cp, h, s obtained from the template argument type thermo. All other properties are derived from these primitive functions. More...
#include <specie/specieThermo.H>
Basic thermodynamics type based on the use of fitting functions for cp, h, s obtained from the template argument type thermo. All other properties are derived from these primitive functions.
Definition at line 91 of file specieThermo.H.
Public Member Functions | |
specieThermo (const thermo &sp) | |
construct from components | |
specieThermo (Istream &) | |
Construct from Istream. | |
specieThermo (const word &name, const specieThermo &) | |
Construct as named copy. | |
scalar | cv (const scalar T) const |
Heat capacity at constant volume [J/(kmol K)]. | |
scalar | gamma (const scalar T) const |
gamma = cp/cv [] | |
scalar | e (const scalar T) const |
Internal energy [J/kmol]. | |
scalar | es (const scalar T) const |
Sensible internal energy [J/kmol]. | |
scalar | g (const scalar T) const |
Gibbs free energy [J/kmol]. | |
scalar | a (const scalar T) const |
Helmholtz free energy [J/kmol]. | |
scalar | Cp (const scalar T) const |
Heat capacity at constant pressure [J/(kg K)]. | |
scalar | Cv (const scalar T) const |
Heat capacity at constant volume [J/(kg K)]. | |
scalar | H (const scalar T) const |
Enthalpy [J/kg]. | |
scalar | Hs (const scalar T) const |
Sensible enthalpy [J/kg]. | |
scalar | Hc () const |
Chemical enthalpy [J/kg]. | |
scalar | S (const scalar T) const |
Entropy [J/(kg K)]. | |
scalar | E (const scalar T) const |
Internal energy [J/kg]. | |
scalar | G (const scalar T) const |
Gibbs free energy [J/kg]. | |
scalar | A (const scalar T) const |
Helmholtz free energy [J/kg]. | |
scalar | K (const scalar T) const |
Equilibrium constant [] i.t.o fugacities. | |
scalar | Kp (const scalar T) const |
Equilibrium constant [] i.t.o. partial pressures. | |
scalar | Kc (const scalar T) const |
Equilibrium constant i.t.o. molar concentration. | |
scalar | Kx (const scalar T, const scalar p) const |
Equilibrium constant [] i.t.o. mole-fractions. | |
scalar | Kn (const scalar T, const scalar p, const scalar n) const |
Equilibrium constant [] i.t.o. number of moles. | |
scalar | TH (const scalar H, const scalar T0) const |
Temperature from Enthalpy given an initial temperature T0. | |
scalar | THs (const scalar Hs, const scalar T0) const |
Temperature from sensible Enthalpy given an initial T0. | |
scalar | TE (const scalar E, const scalar T0) const |
Temperature from internal energy given an initial temperature T0. | |
void | operator+= (const specieThermo &) |
void | operator-= (const specieThermo &) |
void | operator*= (const scalar) |
Friends | |
specieThermo | operator+ (const specieThermo &, const specieThermo &) |
specieThermo | operator- (const specieThermo &, const specieThermo &) |
specieThermo | operator* (const scalar s, const specieThermo &) |
specieThermo | operator== (const specieThermo &, const specieThermo &) |
Ostream & | operator (Ostream &, const specieThermo &) |
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construct from components
Definition at line 32 of file specieThermoI.H.
specieThermo | ( | Istream & | is | ) |
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Construct as named copy.
Definition at line 81 of file specieThermoI.H.
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Heat capacity at constant volume [J/(kmol K)].
Definition at line 93 of file specieThermoI.H.
References cp.
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Heat capacity at constant pressure [J/(kg K)].
Definition at line 136 of file specieThermoI.H.
References cp.
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Heat capacity at constant volume [J/(kg K)].
Definition at line 143 of file specieThermoI.H.
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Chemical enthalpy [J/kg].
Definition at line 164 of file specieThermoI.H.
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Entropy [J/(kg K)].
Definition at line 171 of file specieThermoI.H.
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Gibbs free energy [J/kg].
Definition at line 185 of file specieThermoI.H.
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Helmholtz free energy [J/kg].
Definition at line 192 of file specieThermoI.H.
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Equilibrium constant [] i.t.o fugacities.
= PIi(fi/Pstd)^nui
Definition at line 199 of file specieThermoI.H.
References Foam::exp(), and T.
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Equilibrium constant [] i.t.o. partial pressures.
= PIi(pi/Pstd)^nui For low pressures (where the gas mixture is near perfect) Kp = K
Definition at line 215 of file specieThermoI.H.
References K.
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Equilibrium constant i.t.o. molar concentration.
= PIi(ci/cstd)^nui For low pressures (where the gas mixture is near perfect) Kc = Kp(pstd/(RR*T))^nu
Definition at line 222 of file specieThermoI.H.
References equal(), and Foam::pow().
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Equilibrium constant [] i.t.o. mole-fractions.
For low pressures (where the gas mixture is near perfect) Kx = Kp(pstd/p)^nui
Definition at line 237 of file specieThermoI.H.
References equal(), and Foam::pow().
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Equilibrium constant [] i.t.o. number of moles.
For low pressures (where the gas mixture is near perfect) Kn = Kp(n*pstd/p)^nui where n = number of moles in mixture
Definition at line 255 of file specieThermoI.H.
References equal(), and Foam::pow().
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Temperature from Enthalpy given an initial temperature T0.
Definition at line 274 of file specieThermoI.H.
References T.
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Temperature from sensible Enthalpy given an initial T0.
Definition at line 285 of file specieThermoI.H.
References T.
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Temperature from internal energy given an initial temperature T0.
Definition at line 296 of file specieThermoI.H.
References T.
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Definition at line 309 of file specieThermoI.H.
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Definition at line 318 of file specieThermoI.H.
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Definition at line 326 of file specieThermoI.H.
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