Pressure [Pa] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:
Temperature [K] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:
Specific volume [m3/kg] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:
Sound velocity [m/sec] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:
wspTHERMCONDHS(h, s)
Dynamic viscosity [Pa·sec] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:
wspDYNVISHS(h, s)
Prandtl number [-] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:
wspPRANDTLEHS(h, s)
wspKINVISHS(h, s)
Isoentropic exponent [-] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:
Vapor fraction [-] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:
Vapor fraction [-] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Vapor fraction [-] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Rough value of density of steam at saturation line [kg/m3] as function of temperature t [K]:
Rough value of density of water at saturation line [kg/m3] as function of temperature t [K]:
Specific enthalpy of steam at saturation line [J/kg] as function of specific entropy s [J/(kg·K)]:
Specific enthalpy of water at saturation line [J/kg] as function of specific entropy s [J/(kg·K)]:
Pressure at sublimation line [Pa] as function of temperature t [K]:
Pressure at melting line of ice I [Pa] as function of temperature t [K]:
Temperature in IF-97 region 3 [K] as function of density r [kg/m3], specific enthalpy h [J/kg]:
Area of phase state as function of pressure p [Pa], temperature t [K]:
IF-97 region as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:
Specific isobaric heat capacity [J/(kg·K)] as function of gas identificator id, temperature t [K]:
Specific enthalpy [J/kg] as function of gas identificator id, temperature t [K]:
Specific enthalpy [J/kg] as function of gas specification gas_specification, temperature t [K]:
Specific entropy [J/(kg·K)] as function of gas identificator id, temperature t [K]:
Specific entropy [J/(kg·K)] as function of gas specification gas_specification, temperature t [K]:
Specific entropy [J/(kg·K)] as function of gas identificator id, pressure p [Pa], temperature t [K]:
Specific isochoric heat capacity [J/(kg·K)] as function of gas identificator id, temperature t [K]:
Specific internal energy [J/kg] as function of gas identificator id, temperature t [K]:
Molar mass [kg/mole] as function of gas specification gas_specification:
Specific gas constant [J/(kg·K)] as function of gas identificator id:
Specific gas constant [J/(kg·K)] as function of gas specification gas_specification:
Specific volume [m3/kg] as function of gas identificator id, temperature t [K]:
Specific volume [m3/kg] as function of gas specification gas_specification, temperature t [K]:
Specific volume [m3/kg] as function of gas identificator id, pressure p [Pa], temperature t [K]:
Temperature [K] as function of gas identificator id, specific enthalpy h [J/kg]:
Temperature [K] as function of gas specification gas_specification, specific enthalpy h [J/kg]:
Temperature [K] as function of gas identificator id, specific entropy s [J/(kg·K)]:
Temperature [K] as function of gas specification gas_specification, specific entropy s [J/(kg·K)]:
Temperature [K] as function of gas identificator id, pressure p [Pa], specific entropy s [J/(kg·K)]:
Pressure [Pa] as function of gas identificator id, temperature t [K], specific entropy s [J/(kg·K)]:
New gas identificator as function of gas specification gas_specification:
Deleting of early created gas as function of gas identificator id:
Mode of calculating dissociation while calculate gases mixtures:
Properties calculation result as function of pressure p [Pa], temperature t [K]:
wspVUSHCVWDERPTPT(p, t, *v, *u, *s, *h, *Cv, *w, *DVDPt, *DUDPt, *DSDPt, *DHDPt, *DVDTp, *DUDTp, *DSDTp, *DHDTp)
Derivative of saturation pressure on saturation temperature [Pa/K] as function of temperature t [K]:
Properties calculation result for water at saturation line as function of temperature t [K]:
wspVUSHCVWDERPTSWT(t, *v, *u, *s, *h, *Cv, *w, *DVDPt, *DUDPt, *DSDPt, *DHDPt, *DVDTp, *DUDTp, *DSDTp, *DHDTp)
Properties calculation result for steam at saturation line as function of temperature t [K]:
wspVUSHCVWDERPTSST(t, *v, *u, *s, *h, *Cv, *w, *DVDPt, *DUDPt, *DSDPt, *DHDPt, *DVDTp, *DUDTp, *DSDTp, *DHDTp)
Properties calculation result in IF-97 region 1 as function of pressure p [Pa], temperature t [K]:
wspVUSHCVWDERPT1PT(p, t, *v, *u, *s, *h, *Cv, *w, *DVDPt, *DUDPt, *DSDPt, *DHDPt, *DVDTp, *DUDTp, *DSDTp, *DHDTp)
Properties calculation result in IF-97 region 2 as function of pressure p [Pa], temperature t [K]:
wspVUSHCVWDERPT2PT(p, t, *v, *u, *s, *h, *Cv, *w, *DVDPt, *DUDPt, *DSDPt, *DHDPt, *DVDTp, *DUDTp, *DSDTp, *DHDTp)
Properties calculation result in IF-97 region 3 as function of density r [kg/m3], temperature t [K]:
wspVUSHCVWDERPT3RT(r, t, *v, *u, *s, *h, *Cv, *w, *DVDPt, *DUDPt, *DSDPt, *DHDPt, *DVDTp, *DUDTp, *DSDTp, *DHDTp)
Properties calculation result in IF-97 region 3 as function of pressure p [Pa], temperature t [K]:
wspVUSHCVWDERPT3PT(p, t, *v, *u, *s, *h, *Cv, *w, *DVDPt, *DUDPt, *DSDPt, *DHDPt, *DVDTp, *DUDTp, *DSDTp, *DHDTp)
Properties calculation result in IF-97 region 5 as function of pressure p [Pa], temperature t [K]:
wspVUSHCVWDERPT5PT(p, t, *v, *u, *s, *h, *Cv, *w, *DVDPt, *DUDPt, *DSDPt, *DHDPt, *DVDTp, *DUDTp, *DSDTp, *DHDTp)
wspDYNVISMSPT(p, t)
wspKINVISMSPT(p, t)
wspXEXPANSIONPTPEFF(p0, t0, p1, eff)
wspTEXPANSIONPTPEFF(p0, t0, p1, eff)
wspVEXPANSIONPTPEFF(p0, t0, p1, eff)
wspUEXPANSIONPTPEFF(p0, t0, p1, eff)
wspHEXPANSIONPTPEFF(p0, t0, p1, eff)
wspSEXPANSIONPTPEFF(p0, t0, p1, eff)
wspCPEXPANSIONPTPEFF(p0, t0, p1, eff)
wspCVEXPANSIONPTPEFF(p0, t0, p1, eff)
wspWEXPANSIONPTPEFF(p0, t0, p1, eff)
wspKEXPANSIONPTPEFF(p0, t0, p1, eff)
Joule-Thomson coefficient [K/Pa] as function of pressure p [Pa], temperature t [K]:
wspJOULETHOMPSONPTX(p, t, x)
Temperature [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Temperature [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Specific internal energy [J/kg] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Specific volume [m3/kg] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Specific entropy [J/(kg·K)] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Sound velocity [m/sec] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Joule-Thomson coefficient [K/Pa] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Dynamic viscosity [Pa·sec] as function of pressure p [Pa], specific enthalpy h [J/kg]:
wspDYNVISPH(p, h)
Kinematic viscosity [m2/sec] as function of pressure p [Pa], specific enthalpy h [J/kg]:
wspKINVISPH(p, h)
Prandtl number [-] as function of pressure p [Pa], specific enthalpy h [J/kg]:
wspPRANDTLEPH(p, h)
Isoentropic exponent [-] as function of pressure p [Pa], specific enthalpy h [J/kg]:
wspTHERMCONDPH(p, h)
Specific internal energy [J/kg] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Specific volume [m3/kg] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Specific enthalpy [J/kg] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Sound velocity [m/sec] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Joule-Thomson coefficient [K/Pa] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Dynamic viscosity [Pa·sec] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
wspDYNVISPS(p, s)
Kinematic viscosity [m2/sec] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
wspKINVISPS(p, s)
Prandtl number [-] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
wspPRANDTLEPS(p, s)
Isoentropic exponent [-] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
wspTHERMCONDPS(p, s)
Joule-Thomson coefficient of steam at saturation line [K/Pa] as function of temperature t [K]:
Joule-Thomson coefficient of water at saturation line [K/Pa] as function of temperature t [K]:
Vapor fraction [-] as function of temperature t [K], Joule-Thomson coefficient jt [K/Pa]:
Temperature in IF-97 region 1 [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Temperature in IF-97 region 1 [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Temperature in IF-97 region 2a [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Temperature in IF-97 region 2a [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Temperature in IF-97 region 2b [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Temperature in IF-97 region 2b [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Temperature in IF-97 region 2c [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Temperature in IF-97 region 2c [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Temperature in IF-97 region 2 [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Temperature in IF-97 region 2 [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Temperature in IF-97 region 3 [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Temperature in IF-97 region 3 [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Temperature in IF-97 region 5 [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Temperature in IF-97 region 5 [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Pressure at line between areas 2b and 2c [Pa] as function of specific enthalpy h [J/kg]:
Specific enthalpy at line between areas 2b and 2c [J/kg] as function of pressure p [Pa]:
IF-97 region as function of pressure p [Pa], specific enthalpy h [J/kg]:
IF-97 region as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Set and return a mode of management of make function results more precise as function of mode mode:
Specific volume [m3/kg] as function of pressure p [Pa], temperature t [K]:
Specific internal energy [J/kg] as function of pressure p [Pa], temperature t [K]:
Specific entropy [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:
Specific enthalpy [J/kg] as function of pressure p [Pa], temperature t [K]:
Specific isobaric heat capacity [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:
Specific isochoric heat capacity [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:
Sound velocity [m/sec] as function of pressure p [Pa], temperature t [K]:
Thermal conductivity coefficient [W/(m·K)] as function of pressure p [Pa], temperature t [K]:
wspTHERMCONDPT(p, t)
Dynamic viscosity [Pa·sec] as function of pressure p [Pa], temperature t [K]:
wspDYNVISPT(p, t)
Prandtl number [-] as function of pressure p [Pa], temperature t [K]:
wspPRANDTLEPT(p, t)
Kinematic viscosity [m2/sec] as function of pressure p [Pa], temperature t [K]:
wspKINVISPT(p, t)
Isoentropic exponent [-] as function of pressure p [Pa], temperature t [K]:
Specific volume [m3/kg] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:
Specific entropy [J/(kg·K)] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:
Specific enthalpy [J/kg] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:
Sound velocity [m/sec] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:
wspTHERMCONDPTX(p, t, x)
Dynamic viscosity [Pa·sec] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:
wspDYNVISPTX(p, t, x)
Prandtl number [-] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:
wspPRANDTLEPTX(p, t, x)
wspKINVISPTX(p, t, x)
Isoentropic exponent [-] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:
Pressure at saturation line [Pa] as function of temperature t [K]:
Temperature at saturation line [K] as function of pressure p [Pa]:
Specific volume of steam at saturation line [m3/kg] as function of temperature t [K]:
Specific volume of water at saturation line [m3/kg] as function of temperature t [K]:
Specific internal energy of steam at saturation line [J/kg] as function of temperature t [K]:
Specific internal energy of water at saturation line [J/kg] as function of temperature t [K]:
Specific entropy of steam at saturation line [J/(kg·K)] as function of temperature t [K]:
Specific entropy of water at saturation line [J/(kg·K)] as function of temperature t [K]:
Specific enthalpy of steam at saturation line [J/kg] as function of temperature t [K]:
Specific enthalpy of water at saturation line [J/kg] as function of temperature t [K]:
Sound velocity in steam at saturation line [m/sec] as function of temperature t [K]:
Sound velocity in water at saturation line [m/sec] as function of temperature t [K]:
Dynamic viscosity of steam at saturation line [Pa·sec] as function of temperature t [K]:
Dynamic viscosity of water at saturation line [Pa·sec] as function of temperature t [K]:
Prandtl number of steam at saturation line [-] as function of temperature t [K]:
Prandtl number of water at saturation line [-] as function of temperature t [K]:
Kinematic viscosity of steam at saturation line [m2/sec] as function of temperature t [K]:
Kinematic viscosity of water at saturation line [m2/sec] as function of temperature t [K]:
Isoentropic exponent of steam at saturation line [-] as function of temperature t [K]:
Isoentropic exponent of water at saturation line [-] as function of temperature t [K]:
Specific evaporation heat [J/kg] as function of temperature t [K]:
Specific volume in double-phase area [m3/kg] as function of temperature t [K], vapor fraction x [-]:
Sound velocity in double-phase area [m/sec] as function of temperature t [K], vapor fraction x [-]:
wspDYNVISSTX(t, x)
Prandtl number in double-phase area [-] as function of temperature t [K], vapor fraction x [-]:
wspPRANDTLESTX(t, x)
wspKINVISSTX(t, x)
Vapor fraction [-] as function of temperature t [K], specific volume v [m3/kg]:
Vapor fraction [-] as function of temperature t [K], specific internal energy u [J/kg]:
Vapor fraction [-] as function of temperature t [K], specific entropy s [J/(kg·K)]:
Vapor fraction [-] as function of temperature t [K], specific enthalpy h [J/kg]:
Vapor fraction [-] as function of temperature t [K], specific isobaric heat capacity Cp [J/(kg·K)]:
Vapor fraction [-] as function of temperature t [K], specific isochoric heat capacity Cv [J/(kg·K)]:
Vapor fraction [-] as function of temperature t [K], sound velocity w [m/sec]:
Vapor fraction [-] as function of temperature t [K], thermal conductivity coefficient tc [W/(m·K)]:
Vapor fraction [-] as function of temperature t [K], dynamic viscosity dv [Pa·sec]:
wspXSTDYNVIS(t, dv)
Vapor fraction [-] as function of temperature t [K], kinematic viscosity kv [m2/sec]:
wspXSTKINVIS(t, kv)
Vapor fraction [-] as function of temperature t [K], Prandtl number pr [-]:
Vapor fraction [-] as function of temperature t [K], isoentropic exponent k [-]:
Pressure at line between areas 2 and 3 [Pa] as function of temperature t [K]:
Temperature at line between areas 2 and 3 [K] as function of pressure p [Pa]:
IF-97 region as function of pressure p [Pa], temperature t [K]:
IF-97 region (version 2) as function of pressure p [Pa], temperature t [K]:
Thermal conductivity coefficient [W/(m·K)] as function of density r [kg/m3], temperature t [K]:
wspTHERMCONDRT(r, t)
Dynamic viscosity [Pa·sec] as function of density r [kg/m3], temperature t [K]:
wspDYNVISRT(r, t)
Specific volume in IF-97 region 1 [m3/kg] as function of pressure p [Pa], temperature t [K]:
Specific internal energy in IF-97 region 1 [J/kg] as function of pressure p [Pa], temperature t [K]:
Specific entropy in IF-97 region 1 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:
Specific enthalpy in IF-97 region 1 [J/kg] as function of pressure p [Pa], temperature t [K]:
Sound velocity in IF-97 region 1 [m/sec] as function of pressure p [Pa], temperature t [K]:
Specific volume in IF-97 region 2 [m3/kg] as function of pressure p [Pa], temperature t [K]:
Specific internal energy in IF-97 region 2 [J/kg] as function of pressure p [Pa], temperature t [K]:
Specific entropy in IF-97 region 2 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:
Specific enthalpy in IF-97 region 2 [J/kg] as function of pressure p [Pa], temperature t [K]:
Sound velocity in IF-97 region 2 [m/sec] as function of pressure p [Pa], temperature t [K]:
Pressure in IF-97 region 3 [Pa] as function of density r [kg/m3], temperature t [K]:
Density in IF-97 region 3 [kg/m3] as function of pressure p [Pa], temperature t [K]:
Specific entropy in IF-97 region 3 [J/(kg·K)] as function of density r [kg/m3], temperature t [K]:
Specific enthalpy in IF-97 region 3 [J/kg] as function of density r [kg/m3], temperature t [K]:
Sound velocity in IF-97 region 3 [m/sec] as function of density r [kg/m3], temperature t [K]:
Specific volume in IF-97 region 3 [m3/kg] as function of pressure p [Pa], temperature t [K]:
Specific internal energy in IF-97 region 3 [J/kg] as function of pressure p [Pa], temperature t [K]:
Specific entropy in IF-97 region 3 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:
Specific enthalpy in IF-97 region 3 [J/kg] as function of pressure p [Pa], temperature t [K]:
Sound velocity in IF-97 region 3 [m/sec] as function of pressure p [Pa], temperature t [K]:
Specific volume in IF-97 region 5 [m3/kg] as function of pressure p [Pa], temperature t [K]:
Specific internal energy in IF-97 region 5 [J/kg] as function of pressure p [Pa], temperature t [K]:
Specific entropy in IF-97 region 5 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:
Specific enthalpy in IF-97 region 5 [J/kg] as function of pressure p [Pa], temperature t [K]:
Sound velocity in IF-97 region 5 [m/sec] as function of pressure p [Pa], temperature t [K]:
Set and return a mode of checking the range of functions arguments as function of mode mode:
Set and return a last error code as function of error code ErrCode:
Maximum difference between pressure values at estimation of the area 3 parameters [Pa]:
Initial value for density of water in IF-97 region 3 [kg/m3]:
Initial value for density of steam in IF-97 region 3 [kg/m3]: