WaterSteamPro functions history list

• Version 6.0
• Version 5.6
• Version 5.5
• Version 5.4
• Version 5.3
• Version 5.2
• Version 5.1
• Version 5.0

Version 6.0

1. Pressure [Pa] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

   wspPHS(h, s)

2. Temperature [K] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

   wspTHS(h, s)

3. Properties calculation result as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

   wspPTHS(h, s, *p, *t)

4. Specific volume [m3/kg] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

   wspVHS(h, s)

5. Specific internal energy [J/kg] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

   wspUHS(h, s)

6. Specific isobaric heat capacity [J/(kg·K)] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

   wspCPHS(h, s)

7. Specific isochoric heat capacity [J/(kg·K)] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

   wspCVHS(h, s)

8. Sound velocity [m/sec] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

   wspWHS(h, s)

9. Joule-Thomson coefficient [K/Pa] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

   wspJOULETHOMPSONHS(h, s)

10. Thermal conductivity coefficient [W/(m·K)] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspTHERMCONDHS(h, s)

11. Dynamic viscosity [Pa·sec] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspDYNVISHS(h, s)

12. Prandtl number [-] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspPRANDTLEHS(h, s)

13. Kinematic viscosity [m2/sec] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspKINVISHS(h, s)

14. Isoentropic exponent [-] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspKHS(h, s)

15. Vapor fraction [-] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspXHS(h, s)

16. Vapor fraction [-] as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspXPH(p, h)

17. Vapor fraction [-] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspXPS(p, s)

18. Rough value of density of steam at saturation line [kg/m3] as function of temperature t [K]:

    wspROUGHRSST(t)

19. Rough value of density of water at saturation line [kg/m3] as function of temperature t [K]:

    wspROUGHRSWT(t)

20. Specific enthalpy of steam at saturation line [J/kg] as function of specific entropy s [J/(kg·K)]:

    wspROUGHHSSS(s)

21. Specific enthalpy of water at saturation line [J/kg] as function of specific entropy s [J/(kg·K)]:

    wspROUGHHSWS(s)

22. Temperature at saturation line [K] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspTSHS(h, s)

23. Properties calculation result in double-phase area as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspTXSHS(h, s, *t, *x)

24. Pressure at sublimation line [Pa] as function of temperature t [K]:

    wspPSUBT(t)

25. Pressure at melting line of ice I [Pa] as function of temperature t [K]:

    wspPMELTIT(t)

26. Pressure in IF-97 region 1 [Pa] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspP1HS(h, s)

27. Temperature in IF-97 region 1 [K] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspT1HS(h, s)

28. Properties calculation result in IF-97 region 1 as function of density r [kg/m3], specific enthalpy h [J/kg]:

    wspPT1RH(r, h, *p, *t)

29. Pressure in IF-97 region 2 [Pa] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspP2HS(h, s)

30. Temperature in IF-97 region 2 [K] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspT2HS(h, s)

31. Properties calculation result in IF-97 region 2 as function of density r [kg/m3], specific enthalpy h [J/kg]:

    wspPT2RH(r, h, *p, *t)

32. Pressure in IF-97 region 3 [Pa] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspP3HS(h, s)

33. Temperature in IF-97 region 3 [K] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspT3HS(h, s)

34. Specific volume in IF-97 region 3 [m3/kg] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspV3HS(h, s)

35. Specific volume in IF-97 region 3 [m3/kg] as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspV3PH(p, h)

36. Specific volume in IF-97 region 3 [m3/kg] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspV3PS(p, s)

37. Temperature in IF-97 region 3 [K] as function of density r [kg/m3], specific enthalpy h [J/kg]:

    wspT3RH(r, h)

38. Properties calculation result in IF-97 region 5 as function of density r [kg/m3], specific enthalpy h [J/kg]:

    wspPT5RH(r, h, *p, *t)

39. Area of phase state as function of pressure p [Pa], temperature t [K]:

    wspPHASESTATEPT(p, t)

40. IF-97 region as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspWATERSTATEAREAHS(h, s)

41. Temperature at boundary line between areas 2 and 3 [K] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspTB23HS(h, s)

42. Pressure at boundary line between areas 2 and 3 [Pa] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspPB23HS(h, s)

43. Specific enthalpy at boundary line between areas 1 and 3 [J/kg] as function of specific entropy s [J/(kg·K)]:

    wspHB13S(s)

44. Pressure in IF-97 region 5 [Pa] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspP5HS(h, s)

45. Temperature in IF-97 region 5 [K] as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspT5HS(h, s)

46. Properties calculation result in IF-97 region 1 as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspPT1HS(h, s, *p, *t)

47. Properties calculation result in IF-97 region 2 as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspPT2HS(h, s, *p, *t)

48. Properties calculation result in IF-97 region 3 as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspRT3HS(h, s, *r, *t)

49. Properties calculation result in IF-97 region 3 as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspPT3HS(h, s, *p, *t)

50. Properties calculation result in IF-97 region 5 as function of specific enthalpy h [J/kg], specific entropy s [J/(kg·K)]:

    wspPT5HS(h, s, *p, *t)

51. Specific isobaric heat capacity [J/(kg·K)] as function of gas identificator id, temperature t [K]:

    wspgCPIDT(id, t)

52. Specific isobaric heat capacity [J/(kg·K)] as function of gas specification gas_specification, temperature t [K]:

    wspgCPGST(gas_specification, t)

53. Specific enthalpy [J/kg] as function of gas identificator id, temperature t [K]:

    wspgHIDT(id, t)

54. Specific enthalpy [J/kg] as function of gas specification gas_specification, temperature t [K]:

    wspgHGST(gas_specification, t)

55. Specific entropy [J/(kg·K)] as function of gas identificator id, temperature t [K]:

    wspgSIDT(id, t)

56. Specific entropy [J/(kg·K)] as function of gas specification gas_specification, temperature t [K]:

    wspgSGST(gas_specification, t)

57. Specific entropy [J/(kg·K)] as function of gas identificator id, pressure p [Pa], temperature t [K]:

    wspgSIDPT(id, p, t)

58. Specific entropy [J/(kg·K)] as function of gas specification gas_specification, pressure p [Pa], temperature t [K]:

    wspgSGSPT(gas_specification, p, t)

59. Specific isochoric heat capacity [J/(kg·K)] as function of gas identificator id, temperature t [K]:

    wspgCVIDT(id, t)

60. Specific isochoric heat capacity [J/(kg·K)] as function of gas specification gas_specification, temperature t [K]:

    wspgCVGST(gas_specification, t)

61. Specific internal energy [J/kg] as function of gas identificator id, temperature t [K]:

    wspgUIDT(id, t)

62. Specific internal energy [J/kg] as function of gas specification gas_specification, temperature t [K]:

    wspgUGST(gas_specification, t)

63. Molar mass [kg/mole] as function of gas identificator id:

    wspgMMID(id)

64. Molar mass [kg/mole] as function of gas specification gas_specification:

    wspgMMGS(gas_specification)

65. Specific gas constant [J/(kg·K)] as function of gas identificator id:

    wspgGCID(id)

66. Specific gas constant [J/(kg·K)] as function of gas specification gas_specification:

    wspgGCGS(gas_specification)

67. Specific volume [m3/kg] as function of gas identificator id, temperature t [K]:

    wspgVIDT(id, t)

68. Specific volume [m3/kg] as function of gas specification gas_specification, temperature t [K]:

    wspgVGST(gas_specification, t)

69. Specific volume [m3/kg] as function of gas identificator id, pressure p [Pa], temperature t [K]:

    wspgVIDPT(id, p, t)

70. Specific volume [m3/kg] as function of gas specification gas_specification, pressure p [Pa], temperature t [K]:

    wspgVGSPT(gas_specification, p, t)

71. Temperature [K] as function of gas identificator id, specific enthalpy h [J/kg]:

    wspgTIDH(id, h)

72. Temperature [K] as function of gas specification gas_specification, specific enthalpy h [J/kg]:

    wspgTGSH(gas_specification, h)

73. Temperature [K] as function of gas identificator id, specific entropy s [J/(kg·K)]:

    wspgTIDS(id, s)

74. Temperature [K] as function of gas specification gas_specification, specific entropy s [J/(kg·K)]:

    wspgTGSS(gas_specification, s)

75. Temperature [K] as function of gas identificator id, pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspgTIDPS(id, p, s)

76. Temperature [K] as function of gas specification gas_specification, pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspgTGSPS(gas_specification, p, s)

77. Pressure [Pa] as function of gas identificator id, temperature t [K], specific entropy s [J/(kg·K)]:

    wspgPIDTS(id, t, s)

78. Pressure [Pa] as function of gas specification gas_specification, temperature t [K], specific entropy s [J/(kg·K)]:

    wspgPGSTS(gas_specification, t, s)

79. Volume fraction of gas as function of primary gas specification gas_spec_looked, gas specification looked for gas_spec_looked_for:

    wspgVFGSGS(gas_spec_looked, gas_spec_looked_for)

80. Mass fraction of gas as function of primary gas specification gas_spec_looked, gas specification looked for gas_spec_looked_for:

    wspgMFGSGS(gas_spec_looked, gas_spec_looked_for)

81. Volume fraction of gas as function of primary gas identificator id_looked, gas identificator looked for id_looked_for:

    wspgVFIDID(id_looked, id_looked_for)

82. Mass fraction of gas as function of primary gas identificator id_looked, gas identificator looked for id_looked_for:

    wspgMFIDID(id_looked, id_looked_for)

83. Gas identificator as function of existing gas name name:

    wspgIDNAME(name)

84. New gas identificator:

    wspgNEWID()

85. Gas identificator as function of new gas name name:

    wspgNEWIDNAME(name)

86. New gas identificator as function of gas specification gas_specification:

    wspgNEWIDGS(gas_specification)

87. Deleting of early created gas as function of gas identificator id:

    wspgDELETEGASID(id)

88. Deleting of all user-defined gases:

    wspgDELETEGASES()

89. Available gases count:

    wspgGASESCOUNT()

90. Addition of one gas to another as function of identificator of target gas id_target, identificator of added gas id_source, added gas mass mass:

    wspgADDGASM(id_target, id_source, mass)

91. Addition of one gas to another as function of identificator of target gas id_target, identificator of added gas id_source, added gas volume volume:

    wspgADDGASV(id_target, id_source, volume)

92. Set and return a mode of calculating dissociation while calculate gases mixtures as function of mode mode:

    wspgSETCALCDISSMODE(mode)

93. Mode of calculating dissociation while calculate gases mixtures:

    wspgGETCALCDISSMODE()

94. Last error description:

    wspGETLASTERRORDESCRIPTIONW()

95. Process registration of the WaterSteamPro as function of registration name name, registration data data:

    wspLOCALREGISTRATIONEXA(name, data)

96. Process registration of the WaterSteamPro as function of registration name name, registration data data:

    wspLOCALREGISTRATIONEXW(name, data)

97. Absolute gas constant [J/(mole·K)]:

    wspGETABSOLUTEGASCONSTANT()

Version 5.6

1. 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)

2. Derivative of saturation pressure on saturation temperature [Pa/K] as function of temperature t [K]:

   wspDPDTST(t)

3. Specific isochoric heat capacity of steam at saturation line from the double-phase region [J/(kg·K)] as function of temperature t [K]:

   wspCVDPSST(t)

4. Specific isochoric heat capacity of water at saturation line from the double-phase region [J/(kg·K)] as function of temperature t [K]:

   wspCVDPSWT(t)

5. 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)

6. 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)

7. 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)

8. 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)

9. 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)

10. 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)

11. 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)

Version 5.5

1. Specific volume of meta-stable supercooled steam [m3/kg] as function of pressure p [Pa], temperature t [K]:

   wspVMSPT(p, t)

2. Specific internal energy of meta-stable supercooled steam [J/kg] as function of pressure p [Pa], temperature t [K]:

   wspUMSPT(p, t)

3. Specific entropy of meta-stable supercooled steam [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

   wspSMSPT(p, t)

4. Specific enthalpy of meta-stable supercooled steam [J/kg] as function of pressure p [Pa], temperature t [K]:

   wspHMSPT(p, t)

5. Specific isobaric heat capacity of meta-stable supercooled steam [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

   wspCPMSPT(p, t)

6. Specific isochoric heat capacity of meta-stable supercooled steam [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

   wspCVMSPT(p, t)

7. Sound velocity of meta-stable supercooled steam [m/sec] as function of pressure p [Pa], temperature t [K]:

   wspWMSPT(p, t)

8. Thermal conductivity coefficient of meta-stable supercooled steam [W/(m·K)] as function of pressure p [Pa], temperature t [K]:

   wspTHERMCONDMSPT(p, t)

9. Dynamic viscosity of meta-stable supercooled steam [Pa·sec] as function of pressure p [Pa], temperature t [K]:

   wspDYNVISMSPT(p, t)

10. Prandtl number of meta-stable supercooled steam [-] as function of pressure p [Pa], temperature t [K]:

    wspPRANDTLEMSPT(p, t)

11. Kinematic viscosity of meta-stable supercooled steam [m2/sec] as function of pressure p [Pa], temperature t [K]:

    wspKINVISMSPT(p, t)

12. Isoentropic exponent of meta-stable supercooled steam [-] as function of pressure p [Pa], temperature t [K]:

    wspKMSPT(p, t)

13. Joule-Thomson coefficient of meta-stable supercooled steam [K/Pa] as function of pressure p [Pa], temperature t [K]:

    wspJOULETHOMPSONMSPT(p, t)

Version 5.4

1. Temperature at the end of expansion/compression process [K] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], vapor fraction at initial point x0 [-], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspTEXPANSIONPTXPEFF(p0, t0, x0, p1, eff)

2. Specific volume at the end of expansion/compression process [m3/kg] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], vapor fraction at initial point x0 [-], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspVEXPANSIONPTXPEFF(p0, t0, x0, p1, eff)

3. Specific internal energy at the end of expansion/compression process [J/kg] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], vapor fraction at initial point x0 [-], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspUEXPANSIONPTXPEFF(p0, t0, x0, p1, eff)

4. Specific enthalpy at the end of expansion/compression process [J/kg] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], vapor fraction at initial point x0 [-], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspHEXPANSIONPTXPEFF(p0, t0, x0, p1, eff)

5. Specific entropy at the end of expansion/compression process [J/(kg·K)] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], vapor fraction at initial point x0 [-], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspSEXPANSIONPTXPEFF(p0, t0, x0, p1, eff)

6. Specific isobaric heat capacity at the end of expansion/compression process [J/(kg·K)] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], vapor fraction at initial point x0 [-], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspCPEXPANSIONPTXPEFF(p0, t0, x0, p1, eff)

7. Specific isochoric heat capacity at the end of expansion/compression process [J/(kg·K)] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], vapor fraction at initial point x0 [-], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspCVEXPANSIONPTXPEFF(p0, t0, x0, p1, eff)

8. Sound velocity at the end of expansion/compression process [m/sec] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], vapor fraction at initial point x0 [-], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspWEXPANSIONPTXPEFF(p0, t0, x0, p1, eff)

9. Thermal conductivity coefficient at the end of expansion/compression process [W/(m·K)] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], vapor fraction at initial point x0 [-], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspTHERMCONDEXPANSIONPTXPEFF(p0, t0, x0, p1, eff)

10. Kinematic viscosity at the end of expansion/compression process [m2/sec] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], vapor fraction at initial point x0 [-], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

    wspKINVISEXPANSIONPTXPEFF(p0, t0, x0, p1, eff)

11. Dynamic viscosity at the end of expansion/compression process [Pa·sec] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], vapor fraction at initial point x0 [-], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

    wspDYNVISEXPANSIONPTXPEFF(p0, t0, x0, p1, eff)

12. Prandtl number at the end of expansion/compression process [-] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], vapor fraction at initial point x0 [-], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

    wspPRANDTLEEXPANSIONPTXPEFF(p0, t0, x0, p1, eff)

13. Isoentropic exponent [-] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], vapor fraction at initial point x0 [-], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

    wspKEXPANSIONPTXPEFF(p0, t0, x0, p1, eff)

14. Joule-Thomson coefficient at the end of expansion/compression process [K/Pa] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], vapor fraction at initial point x0 [-], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

    wspJOULETHOMPSONEXPANSIONPTXPEFF(p0, t0, x0, p1, eff)

15. Vapor fraction at the end of expansion/compression process [-] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], vapor fraction at initial point x0 [-], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

    wspXEXPANSIONPTXPEFF(p0, t0, x0, p1, eff)

16. Vapor fraction at the end of expansion/compression process [-] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

    wspXEXPANSIONPTPEFF(p0, t0, p1, eff)

Version 5.3

1. Temperature at the end of expansion/compression process [K] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspTEXPANSIONPTPEFF(p0, t0, p1, eff)

2. Specific volume at the end of expansion/compression process [m3/kg] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspVEXPANSIONPTPEFF(p0, t0, p1, eff)

3. Specific internal energy at the end of expansion/compression process [J/kg] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspUEXPANSIONPTPEFF(p0, t0, p1, eff)

4. Specific enthalpy at the end of expansion/compression process [J/kg] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspHEXPANSIONPTPEFF(p0, t0, p1, eff)

5. Specific entropy at the end of expansion/compression process [J/(kg·K)] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspSEXPANSIONPTPEFF(p0, t0, p1, eff)

6. Specific isobaric heat capacity at the end of expansion/compression process [J/(kg·K)] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspCPEXPANSIONPTPEFF(p0, t0, p1, eff)

7. Specific isochoric heat capacity at the end of expansion/compression process [J/(kg·K)] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspCVEXPANSIONPTPEFF(p0, t0, p1, eff)

8. Sound velocity at the end of expansion/compression process [m/sec] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspWEXPANSIONPTPEFF(p0, t0, p1, eff)

9. Thermal conductivity coefficient at the end of expansion/compression process [W/(m·K)] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

   wspTHERMCONDEXPANSIONPTPEFF(p0, t0, p1, eff)

10. Kinematic viscosity at the end of expansion/compression process [m2/sec] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

    wspKINVISEXPANSIONPTPEFF(p0, t0, p1, eff)

11. Dynamic viscosity at the end of expansion/compression process [Pa·sec] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

    wspDYNVISEXPANSIONPTPEFF(p0, t0, p1, eff)

12. Prandtl number at the end of expansion/compression process [-] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

    wspPRANDTLEEXPANSIONPTPEFF(p0, t0, p1, eff)

13. Isoentropic exponent at the end of expansion/compression process [-] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

    wspKEXPANSIONPTPEFF(p0, t0, p1, eff)

14. Joule-Thomson coefficient at the end of expansion/compression process [K/Pa] as function of pressure at initial point p0 [Pa], temperature at initial point t0 [K], pressure at final point p1 [Pa], internal efficiency of process eff [-]:

    wspJOULETHOMPSONEXPANSIONPTPEFF(p0, t0, p1, eff)

Version 5.2

1. Joule-Thomson coefficient [K/Pa] as function of pressure p [Pa], temperature t [K]:

   wspJOULETHOMPSONPT(p, t)

2. Joule-Thomson coefficient [K/Pa] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:

   wspJOULETHOMPSONPTX(p, t, x)

3. Temperature [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:

   wspTPH(p, h)

4. Temperature [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

   wspTPS(p, s)

5. Specific internal energy [J/kg] as function of pressure p [Pa], specific enthalpy h [J/kg]:

   wspUPH(p, h)

6. Specific volume [m3/kg] as function of pressure p [Pa], specific enthalpy h [J/kg]:

   wspVPH(p, h)

7. Specific entropy [J/(kg·K)] as function of pressure p [Pa], specific enthalpy h [J/kg]:

   wspSPH(p, h)

8. Specific isobaric heat capacity [J/(kg·K)] as function of pressure p [Pa], specific enthalpy h [J/kg]:

   wspCPPH(p, h)

9. Specific isochoric heat capacity [J/(kg·K)] as function of pressure p [Pa], specific enthalpy h [J/kg]:

   wspCVPH(p, h)

10. Sound velocity [m/sec] as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspWPH(p, h)

11. Joule-Thomson coefficient [K/Pa] as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspJOULETHOMPSONPH(p, h)

12. Dynamic viscosity [Pa·sec] as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspDYNVISPH(p, h)

13. Kinematic viscosity [m2/sec] as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspKINVISPH(p, h)

14. Prandtl number [-] as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspPRANDTLEPH(p, h)

15. Isoentropic exponent [-] as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspKPH(p, h)

16. Thermal conductivity coefficient [W/(m·K)] as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspTHERMCONDPH(p, h)

17. Specific internal energy [J/kg] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspUPS(p, s)

18. Specific volume [m3/kg] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspVPS(p, s)

19. Specific enthalpy [J/kg] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspHPS(p, s)

20. Specific isobaric heat capacity [J/(kg·K)] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspCPPS(p, s)

21. Specific isochoric heat capacity [J/(kg·K)] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspCVPS(p, s)

22. Sound velocity [m/sec] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspWPS(p, s)

23. Joule-Thomson coefficient [K/Pa] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspJOULETHOMPSONPS(p, s)

24. Dynamic viscosity [Pa·sec] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspDYNVISPS(p, s)

25. Kinematic viscosity [m2/sec] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspKINVISPS(p, s)

26. Prandtl number [-] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspPRANDTLEPS(p, s)

27. Isoentropic exponent [-] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspKPS(p, s)

28. Thermal conductivity coefficient [W/(m·K)] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspTHERMCONDPS(p, s)

29. Joule-Thomson coefficient of steam at saturation line [K/Pa] as function of temperature t [K]:

    wspJOULETHOMPSONSST(t)

30. Joule-Thomson coefficient of water at saturation line [K/Pa] as function of temperature t [K]:

    wspJOULETHOMPSONSWT(t)

31. Joule-Thomson coefficient in double-phase area [K/Pa] as function of temperature t [K], vapor fraction x [-]:

    wspJOULETHOMPSONSTX(t, x)

32. Vapor fraction [-] as function of temperature t [K], Joule-Thomson coefficient jt [K/Pa]:

    wspXSTJOULETHOMPSON(t, jt)

33. Joule-Thomson coefficient in IF-97 region 1 [K/Pa] as function of pressure p [Pa], temperature t [K]:

    wspJOULETHOMPSON1PT(p, t)

34. Joule-Thomson coefficient in IF-97 region 2 [K/Pa] as function of pressure p [Pa], temperature t [K]:

    wspJOULETHOMPSON2PT(p, t)

35. Joule-Thomson coefficient in IF-97 region 3 [K/Pa] as function of density r [kg/m3], temperature t [K]:

    wspJOULETHOMPSON3RT(r, t)

36. Joule-Thomson coefficient in IF-97 region 3 [K/Pa] as function of pressure p [Pa], temperature t [K]:

    wspJOULETHOMPSON3PT(p, t)

37. Joule-Thomson coefficient in IF-97 region 5 [K/Pa] as function of pressure p [Pa], temperature t [K]:

    wspJOULETHOMPSON5PT(p, t)

38. Temperature in IF-97 region 1 [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspT1PH(p, h)

39. Temperature in IF-97 region 1 [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspT1PS(p, s)

40. Temperature in IF-97 region 2a [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspT2APH(p, h)

41. Temperature in IF-97 region 2a [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspT2APS(p, s)

42. Temperature in IF-97 region 2b [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspT2BPH(p, h)

43. Temperature in IF-97 region 2b [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspT2BPS(p, s)

44. Temperature in IF-97 region 2c [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspT2CPH(p, h)

45. Temperature in IF-97 region 2c [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspT2CPS(p, s)

46. Temperature in IF-97 region 2 [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspT2PH(p, h)

47. Temperature in IF-97 region 2 [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspT2PS(p, s)

48. Temperature in IF-97 region 3 [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspT3PH(p, h)

49. Temperature in IF-97 region 3 [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspT3PS(p, s)

50. Temperature in IF-97 region 5 [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspT5PH(p, h)

51. Temperature in IF-97 region 5 [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspT5PS(p, s)

52. Pressure at line between areas 2b and 2c [Pa] as function of specific enthalpy h [J/kg]:

    wspP2B2CH(h)

53. Specific enthalpy at line between areas 2b and 2c [J/kg] as function of pressure p [Pa]:

    wspH2B2CP(p)

54. IF-97 region as function of pressure p [Pa], specific enthalpy h [J/kg]:

    wspWATERSTATEAREAPH(p, h)

55. IF-97 region as function of pressure p [Pa], specific entropy s [J/(kg·K)]:

    wspWATERSTATEAREAPS(p, s)

56. Set and return relative precision in the WaterSteamPro functions [-] as function of tolerance tolerance [-]:

    wspSETTOLERANCE(tolerance)

57. Relative precision in the WaterSteamPro functions [-]:

    wspGETTOLERANCE()

58. Set and return a mode of management of make function results more precise as function of mode mode:

    wspSETTOLERANCEMODE(mode)

59. Mode of management of make function results more precise:

    wspGETTOLERANCEMODE()

60. Internal version of the WaterSteamPro:

    wspGETWSPVERSION()

Version 5.1

1. Last error description:

   wspGETLASTERRORDESCRIPTION()

2. Process registration of the WaterSteamPro as function of registration name name, registration key key:

   wspLOCALREGISTRATION(name, key)

Version 5.0

1. Surface tension [N/m] as function of temperature t [K]:

   wspSURFTENT(t)

2. Specific volume [m3/kg] as function of pressure p [Pa], temperature t [K]:

   wspVPT(p, t)

3. Specific internal energy [J/kg] as function of pressure p [Pa], temperature t [K]:

   wspUPT(p, t)

4. Specific entropy [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

   wspSPT(p, t)

5. Specific enthalpy [J/kg] as function of pressure p [Pa], temperature t [K]:

   wspHPT(p, t)

6. Specific isobaric heat capacity [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

   wspCPPT(p, t)

7. Specific isochoric heat capacity [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

   wspCVPT(p, t)

8. Sound velocity [m/sec] as function of pressure p [Pa], temperature t [K]:

   wspWPT(p, t)

9. Thermal conductivity coefficient [W/(m·K)] as function of pressure p [Pa], temperature t [K]:

   wspTHERMCONDPT(p, t)

10. Dynamic viscosity [Pa·sec] as function of pressure p [Pa], temperature t [K]:

    wspDYNVISPT(p, t)

11. Prandtl number [-] as function of pressure p [Pa], temperature t [K]:

    wspPRANDTLEPT(p, t)

12. Kinematic viscosity [m2/sec] as function of pressure p [Pa], temperature t [K]:

    wspKINVISPT(p, t)

13. Isoentropic exponent [-] as function of pressure p [Pa], temperature t [K]:

    wspKPT(p, t)

14. Specific volume [m3/kg] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:

    wspVPTX(p, t, x)

15. Specific internal energy [J/kg] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:

    wspUPTX(p, t, x)

16. Specific entropy [J/(kg·K)] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:

    wspSPTX(p, t, x)

17. Specific enthalpy [J/kg] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:

    wspHPTX(p, t, x)

18. Specific isobaric heat capacity [J/(kg·K)] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:

    wspCPPTX(p, t, x)

19. Specific isochoric heat capacity [J/(kg·K)] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:

    wspCVPTX(p, t, x)

20. Sound velocity [m/sec] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:

    wspWPTX(p, t, x)

21. Thermal conductivity coefficient [W/(m·K)] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:

    wspTHERMCONDPTX(p, t, x)

22. Dynamic viscosity [Pa·sec] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:

    wspDYNVISPTX(p, t, x)

23. Prandtl number [-] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:

    wspPRANDTLEPTX(p, t, x)

24. Kinematic viscosity [m2/sec] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:

    wspKINVISPTX(p, t, x)

25. Isoentropic exponent [-] as function of pressure p [Pa], temperature t [K], vapor fraction x [-]:

    wspKPTX(p, t, x)

26. Pressure at saturation line [Pa] as function of temperature t [K]:

    wspPST(t)

27. Temperature at saturation line [K] as function of pressure p [Pa]:

    wspTSP(p)

28. Specific volume of steam at saturation line [m3/kg] as function of temperature t [K]:

    wspVSST(t)

29. Specific volume of water at saturation line [m3/kg] as function of temperature t [K]:

    wspVSWT(t)

30. Specific internal energy of steam at saturation line [J/kg] as function of temperature t [K]:

    wspUSST(t)

31. Specific internal energy of water at saturation line [J/kg] as function of temperature t [K]:

    wspUSWT(t)

32. Specific entropy of steam at saturation line [J/(kg·K)] as function of temperature t [K]:

    wspSSST(t)

33. Specific entropy of water at saturation line [J/(kg·K)] as function of temperature t [K]:

    wspSSWT(t)

34. Specific enthalpy of steam at saturation line [J/kg] as function of temperature t [K]:

    wspHSST(t)

35. Specific enthalpy of water at saturation line [J/kg] as function of temperature t [K]:

    wspHSWT(t)

36. Specific isobaric heat capacity of steam at saturation line [J/(kg·K)] as function of temperature t [K]:

    wspCPSST(t)

37. Specific isobaric heat capacity of water at saturation line [J/(kg·K)] as function of temperature t [K]:

    wspCPSWT(t)

38. Specific isochoric heat capacity of steam at saturation line from the one-phase region [J/(kg·K)] as function of temperature t [K]:

    wspCVSST(t)

39. Specific isochoric heat capacity of water at saturation line from the one-phase region [J/(kg·K)] as function of temperature t [K]:

    wspCVSWT(t)

40. Sound velocity in steam at saturation line [m/sec] as function of temperature t [K]:

    wspWSST(t)

41. Sound velocity in water at saturation line [m/sec] as function of temperature t [K]:

    wspWSWT(t)

42. Thermal conductivity coefficient of steam at saturation line [W/(m·K)] as function of temperature t [K]:

    wspTHERMCONDSST(t)

43. Thermal conductivity coefficient of water at saturation line [W/(m·K)] as function of temperature t [K]:

    wspTHERMCONDSWT(t)

44. Dynamic viscosity of steam at saturation line [Pa·sec] as function of temperature t [K]:

    wspDYNVISSST(t)

45. Dynamic viscosity of water at saturation line [Pa·sec] as function of temperature t [K]:

    wspDYNVISSWT(t)

46. Prandtl number of steam at saturation line [-] as function of temperature t [K]:

    wspPRANDTLESST(t)

47. Prandtl number of water at saturation line [-] as function of temperature t [K]:

    wspPRANDTLESWT(t)

48. Kinematic viscosity of steam at saturation line [m2/sec] as function of temperature t [K]:

    wspKINVISSST(t)

49. Kinematic viscosity of water at saturation line [m2/sec] as function of temperature t [K]:

    wspKINVISSWT(t)

50. Isoentropic exponent of steam at saturation line [-] as function of temperature t [K]:

    wspKSST(t)

51. Isoentropic exponent of water at saturation line [-] as function of temperature t [K]:

    wspKSWT(t)

52. Specific evaporation heat [J/kg] as function of temperature t [K]:

    wspRST(t)

53. Specific volume in double-phase area [m3/kg] as function of temperature t [K], vapor fraction x [-]:

    wspVSTX(t, x)

54. Specific internal energy in double-phase area [J/kg] as function of temperature t [K], vapor fraction x [-]:

    wspUSTX(t, x)

55. Specific entropy in double-phase area [J/(kg·K)] as function of temperature t [K], vapor fraction x [-]:

    wspSSTX(t, x)

56. Specific enthalpy in double-phase area [J/kg] as function of temperature t [K], vapor fraction x [-]:

    wspHSTX(t, x)

57. Specific isobaric heat capacity in double-phase area [J/(kg·K)] as function of temperature t [K], vapor fraction x [-]:

    wspCPSTX(t, x)

58. Specific isochoric heat capacity in double-phase area [J/(kg·K)] as function of temperature t [K], vapor fraction x [-]:

    wspCVSTX(t, x)

59. Sound velocity in double-phase area [m/sec] as function of temperature t [K], vapor fraction x [-]:

    wspWSTX(t, x)

60. Thermal conductivity coefficient in double-phase area [W/(m·K)] as function of temperature t [K], vapor fraction x [-]:

    wspTHERMCONDSTX(t, x)

61. Dynamic viscosity in double-phase area [Pa·sec] as function of temperature t [K], vapor fraction x [-]:

    wspDYNVISSTX(t, x)

62. Prandtl number in double-phase area [-] as function of temperature t [K], vapor fraction x [-]:

    wspPRANDTLESTX(t, x)

63. Kinematic viscosity in double-phase area [m2/sec] as function of temperature t [K], vapor fraction x [-]:

    wspKINVISSTX(t, x)

64. Isoentropic exponent in double-phase area [-] as function of temperature t [K], vapor fraction x [-]:

    wspKSTX(t, x)

65. Vapor fraction [-] as function of temperature t [K], specific volume v [m3/kg]:

    wspXSTV(t, v)

66. Vapor fraction [-] as function of temperature t [K], specific internal energy u [J/kg]:

    wspXSTU(t, u)

67. Vapor fraction [-] as function of temperature t [K], specific entropy s [J/(kg·K)]:

    wspXSTS(t, s)

68. Vapor fraction [-] as function of temperature t [K], specific enthalpy h [J/kg]:

    wspXSTH(t, h)

69. Vapor fraction [-] as function of temperature t [K], specific isobaric heat capacity Cp [J/(kg·K)]:

    wspXSTCP(t, Cp)

70. Vapor fraction [-] as function of temperature t [K], specific isochoric heat capacity Cv [J/(kg·K)]:

    wspXSTCV(t, Cv)

71. Vapor fraction [-] as function of temperature t [K], sound velocity w [m/sec]:

    wspXSTW(t, w)

72. Vapor fraction [-] as function of temperature t [K], thermal conductivity coefficient tc [W/(m·K)]:

    wspXSTTHERMCOND(t, tc)

73. Vapor fraction [-] as function of temperature t [K], dynamic viscosity dv [Pa·sec]:

    wspXSTDYNVIS(t, dv)

74. Vapor fraction [-] as function of temperature t [K], kinematic viscosity kv [m2/sec]:

    wspXSTKINVIS(t, kv)

75. Vapor fraction [-] as function of temperature t [K], Prandtl number pr [-]:

    wspXSTPRANDTLE(t, pr)

76. Vapor fraction [-] as function of temperature t [K], isoentropic exponent k [-]:

    wspXSTK(t, k)

77. Pressure at line between areas 2 and 3 [Pa] as function of temperature t [K]:

    wspP23T(t)

78. Temperature at line between areas 2 and 3 [K] as function of pressure p [Pa]:

    wspT23P(p)

79. IF-97 region as function of pressure p [Pa], temperature t [K]:

    wspWATERSTATEAREA(p, t)

80. IF-97 region (version 2) as function of pressure p [Pa], temperature t [K]:

    wspWATERSTATEAREA2(p, t)

81. Thermal conductivity coefficient [W/(m·K)] as function of density r [kg/m3], temperature t [K]:

    wspTHERMCONDRT(r, t)

82. Dynamic viscosity [Pa·sec] as function of density r [kg/m3], temperature t [K]:

    wspDYNVISRT(r, t)

83. Specific volume in IF-97 region 1 [m3/kg] as function of pressure p [Pa], temperature t [K]:

    wspV1PT(p, t)

84. Specific internal energy in IF-97 region 1 [J/kg] as function of pressure p [Pa], temperature t [K]:

    wspU1PT(p, t)

85. Specific entropy in IF-97 region 1 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

    wspS1PT(p, t)

86. Specific enthalpy in IF-97 region 1 [J/kg] as function of pressure p [Pa], temperature t [K]:

    wspH1PT(p, t)

87. Specific isobaric heat capacity in IF-97 region 1 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

    wspCP1PT(p, t)

88. Specific isochoric heat capacity in IF-97 region 1 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

    wspCV1PT(p, t)

89. Sound velocity in IF-97 region 1 [m/sec] as function of pressure p [Pa], temperature t [K]:

    wspW1PT(p, t)

90. Specific volume in IF-97 region 2 [m3/kg] as function of pressure p [Pa], temperature t [K]:

    wspV2PT(p, t)

91. Specific internal energy in IF-97 region 2 [J/kg] as function of pressure p [Pa], temperature t [K]:

    wspU2PT(p, t)

92. Specific entropy in IF-97 region 2 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

    wspS2PT(p, t)

93. Specific enthalpy in IF-97 region 2 [J/kg] as function of pressure p [Pa], temperature t [K]:

    wspH2PT(p, t)

94. Specific isobaric heat capacity in IF-97 region 2 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

    wspCP2PT(p, t)

95. Specific isochoric heat capacity in IF-97 region 2 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

    wspCV2PT(p, t)

96. Sound velocity in IF-97 region 2 [m/sec] as function of pressure p [Pa], temperature t [K]:

    wspW2PT(p, t)

97. Pressure in IF-97 region 3 [Pa] as function of density r [kg/m3], temperature t [K]:

    wspP3RT(r, t)

98. Density in IF-97 region 3 [kg/m3] as function of pressure p [Pa], temperature t [K], initial density r0 [kg/m3]:

    wspR3PTR0(p, t, r0)

99. Density in IF-97 region 3 [kg/m3] as function of pressure p [Pa], temperature t [K]:

    wspR3PT(p, t)

100. Specific internal energy in IF-97 region 3 [J/kg] as function of density r [kg/m3], temperature t [K]:

     wspU3RT(r, t)

101. Specific entropy in IF-97 region 3 [J/(kg·K)] as function of density r [kg/m3], temperature t [K]:

     wspS3RT(r, t)

102. Specific enthalpy in IF-97 region 3 [J/kg] as function of density r [kg/m3], temperature t [K]:

     wspH3RT(r, t)

103. Specific isobaric heat capacity in IF-97 region 3 [J/(kg·K)] as function of density r [kg/m3], temperature t [K]:

     wspCP3RT(r, t)

104. Specific isochoric heat capacity in IF-97 region 3 [J/(kg·K)] as function of density r [kg/m3], temperature t [K]:

     wspCV3RT(r, t)

105. Sound velocity in IF-97 region 3 [m/sec] as function of density r [kg/m3], temperature t [K]:

     wspW3RT(r, t)

106. Specific volume in IF-97 region 3 [m3/kg] as function of pressure p [Pa], temperature t [K]:

     wspV3PT(p, t)

107. Specific internal energy in IF-97 region 3 [J/kg] as function of pressure p [Pa], temperature t [K]:

     wspU3PT(p, t)

108. Specific entropy in IF-97 region 3 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

     wspS3PT(p, t)

109. Specific enthalpy in IF-97 region 3 [J/kg] as function of pressure p [Pa], temperature t [K]:

     wspH3PT(p, t)

110. Specific isobaric heat capacity in IF-97 region 3 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

     wspCP3PT(p, t)

111. Specific isochoric heat capacity in IF-97 region 3 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

     wspCV3PT(p, t)

112. Sound velocity in IF-97 region 3 [m/sec] as function of pressure p [Pa], temperature t [K]:

     wspW3PT(p, t)

113. Specific volume in IF-97 region 5 [m3/kg] as function of pressure p [Pa], temperature t [K]:

     wspV5PT(p, t)

114. Specific internal energy in IF-97 region 5 [J/kg] as function of pressure p [Pa], temperature t [K]:

     wspU5PT(p, t)

115. Specific entropy in IF-97 region 5 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

     wspS5PT(p, t)

116. Specific enthalpy in IF-97 region 5 [J/kg] as function of pressure p [Pa], temperature t [K]:

     wspH5PT(p, t)

117. Specific isobaric heat capacity in IF-97 region 5 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

     wspCP5PT(p, t)

118. Specific isochoric heat capacity in IF-97 region 5 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:

     wspCV5PT(p, t)

119. Sound velocity in IF-97 region 5 [m/sec] as function of pressure p [Pa], temperature t [K]:

     wspW5PT(p, t)

120. Set and return a mode of checking the range of functions arguments as function of mode mode:

     wspSETCHECKRANGEMODE(mode)

121. Mode of checking the range of functions arguments:

     wspGETCHECKRANGEMODE()

122. Set and return a last error code as function of error code ErrCode:

     wspSETLASTERROR(ErrCode)

123. Last error code:

     wspGETLASTERROR()

124. Set and return maximum difference between saturation temperature and input temperature for function wspWATERSTATEAREA [K] as function of temperature delta delta [K]:

     wspSETDELTATS(delta)

125. Maximum difference between saturation temperature and input temperature for function wspWATERSTATEAREA [K]:

     wspGETDELTATS()

126. Set and return maximum iteration's count for Newton method as function of maximum iteration maxiteration:

     wspSETMAXITERATION(maxiteration)

127. Maximum iteration's count for Newton method:

     wspGETMAXITERATION()

128. Set and return maximum difference between pressure values at estimation of the area 3 parameters [Pa] as function of delta pressure delta [Pa]:

     wspSETDELTAPRESSURE(delta)

129. Maximum difference between pressure values at estimation of the area 3 parameters [Pa]:

     wspGETDELTAPRESSURE()

130. Set and return initial value for density of water in IF-97 region 3 [kg/m3] as function of density r [kg/m3]:

     wspSETINITWATERDENSITY(r)

131. Initial value for density of water in IF-97 region 3 [kg/m3]:

     wspGETINITWATERDENSITY()

132. Set and return the initial value for density of steam in IF-97 region 3 [kg/m3] as function of density r [kg/m3]:

     wspSETINITSTEAMDENSITY(r)

133. Initial value for density of steam in IF-97 region 3 [kg/m3]:

     wspGETINITSTEAMDENSITY()