52 return ha(
p,
T) - hf();
94 return kappa_.value(
T);
100 return kappag_.value(
T);
106 return sigma_.value(
T);
112 return D_.value(
p,
T);
118 return D_.value(
p,
T, Wb);
scalar ha(const scalar p, const scalar T) const
scalar B(scalar p, scalar T) const
Second Virial Coefficient [m^3/kg].
scalar D(scalar p, scalar T) const
Vapour diffusivity [m^2/s].
scalar mu(scalar p, scalar T) const
Liquid viscosity [Pa s].
scalar Cpg(scalar p, scalar T) const
Ideal gas heat capacity [J/kg/K].
scalar rho(scalar p, scalar T) const
Liquid density [kg/m^3].
scalar sigma(scalar p, scalar T) const
Surface tension [N/m].
scalar kappa(scalar p, scalar T) const
Liquid thermal conductivity [W/m/K].
scalar Cp(scalar p, scalar T) const
Liquid heat capacity [J/kg/K].
scalar hf() const
Liquid heat of formation [J/kg].
scalar hs(scalar p, scalar T) const
Liquid sensible enthalpy [J/kg].
scalar mug(scalar p, scalar T) const
Vapour viscosity [Pa s].
scalar pv(scalar p, scalar T) const
Vapour pressure [Pa];.
scalar ha(scalar p, scalar T) const
Liquid absolute enthalpy [J/kg].
scalar hl(scalar p, scalar T) const
Heat of vapourisation [J/kg].
scalar kappag(scalar p, scalar T) const
Vapour thermal conductivity [W/m/K].
virtual scalar value(scalar T) const
Evaluate the function and return the result.
void T(FieldField< Field, Type > &f1, const FieldField< Field, Type > &f2)