wspTHERMCONDMSPT (p, t)
wspDYNVISMSPT (p, t)
Prandtl number of meta-stable supercooled steam as function of pressure p [Pa], temperature t [K]:
wspPRANDTLEMSPT (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)
wspTHERMCONDEXPANSIONPTPEFF (p0, t0, p1, eff)
wspKINVISEXPANSIONPTPEFF (p0, t0, p1, eff)
wspDYNVISEXPANSIONPTPEFF (p0, t0, p1, eff)
wspPRANDTLEEXPANSIONPTPEFF (p0, t0, p1, eff)
wspKEXPANSIONPTPEFF (p0, t0, p1, eff)
Joule-Thompson coefficient [K/Pa] as function of pressure p [Pa], temperature t [K]:
wspJOULETHOMPSONPT (p, t)
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]:
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)
Thermal conduction [W/(m·K)] as function of pressure p [Pa], specific enthalpy h [J/kg]:
wspTHERMCONDPH (p, h)
Isoentropic exponent as function of pressure p [Pa], specific enthalpy h [J/kg]:
Joule-Thompson coefficient [K/Pa] as function of pressure p [Pa], specific enthalpy h [J/kg]:
wspJOULETHOMPSONPH (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)]:
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)]:
Thermal conduction [W/(m·K)] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
wspTHERMCONDPS (p, s)
Joule-Thompson coefficient [K/Pa] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
wspJOULETHOMPSONPS (p, s)
Joule-Thompson coefficient in area 1 [K/Pa] as function of pressure p [Pa], temperature t [K]:
Joule-Thompson coefficient in area 2 [K/Pa] as function of pressure p [Pa], temperature t [K]:
Joule-Thompson coefficient in area 3 [K/Pa] as function of density r [kg/m3], temperature t [K]:
Joule-Thompson coefficient in area 3 [K/Pa] as function of pressure p [Pa], temperature t [K]:
Temperature in area 1 [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Joule-Thompson coefficient in area 5 [K/Pa] as function of pressure p [Pa], temperature t [K]:
Temperature in area 1 [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Temperature in area 2a [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Temperature in area 2a [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Temperature in area 2b [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Temperature in area 2b [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Temperature in area 2c [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Temperature in area 2c [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Temperature in area 2 [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Temperature in area 2 [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Temperature in area 3 [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Temperature in area 3 [K] as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Temperature in area 5 [K] as function of pressure p [Pa], specific enthalpy h [J/kg]:
Temperature in area 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]:
Water State Area as function of pressure p [Pa], specific enthalpy h [J/kg]:
Water State Area as function of pressure p [Pa], specific entropy s [J/(kg·K)]:
Joule-Thompson coefficient of steam at saturation line [K/Pa] as function of temperature t [K]:
Joule-Thompson coefficient of water at saturation line [K/Pa] as function of temperature t [K]:
Degree of dryness as function of temperature t [K], Joule-Thomspon coefficient jt [K/Pa]:
Set and return internal tolerance of the WaterSteamPro as function of tolerance tolerance:
Set and return a mode of management of tolerance as function of mode mode:
Surface tension [N/m] as function of temperature t [K]:
wspSURFTENT (t)
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]:
Sound velocity [m/sec] as function of pressure p [Pa], temperature t [K]:
Thermal conduction [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], degree of dryness x:
Specific entropy [J/(kg·K)] as function of pressure p [Pa], temperature t [K], degree of dryness x:
Specific enthalpy [J/kg] as function of pressure p [Pa], temperature t [K], degree of dryness x:
Sound velocity [m/sec] as function of pressure p [Pa], temperature t [K], degree of dryness x:
Thermal conduction [W/(m·K)] as function of pressure p [Pa], temperature t [K], degree of dryness x:
wspTHERMCONDPTX (p, t, x)
Dynamic viscosity [Pa·sec] as function of pressure p [Pa], temperature t [K], degree of dryness x:
wspDYNVISPTX (p, t, x)
Prandtl number as function of pressure p [Pa], temperature t [K], degree of dryness x:
wspPRANDTLEPTX (p, t, x)
Kinematic viscosity [m2/sec] as function of pressure p [Pa], temperature t [K], degree of dryness x:
wspKINVISPTX (p, t, x)
Isoentropic exponent as function of pressure p [Pa], temperature t [K], degree of dryness x:
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]:
Water state area as function of pressure p [Pa], temperature t [K]:
wspWATERSTATEAREA (p, t)
Water state area (version 2) as function of pressure p [Pa], temperature t [K]:
wspWATERSTATEAREA2 (p, t)
Thermal conduction [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 area 1 [m3/kg] as function of pressure p [Pa], temperature t [K]:
Specific internal energy in area 1 [J/kg] as function of pressure p [Pa], temperature t [K]:
Specific entropy in area 1 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:
Specific enthalpy in area 1 [J/kg] as function of pressure p [Pa], temperature t [K]:
Sound velocity in area 1 [m/sec] as function of pressure p [Pa], temperature t [K]:
Specific volume in area 2 [m3/kg] as function of pressure p [Pa], temperature t [K]:
Specific internal energy in area 2 [J/kg] as function of pressure p [Pa], temperature t [K]:
Specific entropy in area 2 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:
Specific enthalpy in area 2 [J/kg] as function of pressure p [Pa], temperature t [K]:
Sound velocity in area 2 [m/sec] as function of pressure p [Pa], temperature t [K]:
Pressure in area 3 [Pa] as function of density r [kg/m3], temperature t [K]:
Density in area 3 [kg/m3] as function of pressure p [Pa], temperature t [K]:
Specific internal energy in area 3 [J/kg] as function of density r [kg/m3], temperature t [K]:
Specific entropy in area 3 [J/(kg·K)] as function of density r [kg/m3], temperature t [K]:
Specific enthalpy in area 3 [J/kg] as function of density r [kg/m3], temperature t [K]:
Sound velocity in area 3 [m/sec] as function of density r [kg/m3], temperature t [K]:
Specific volume in area 3 [m3/kg] as function of pressure p [Pa], temperature t [K]:
Specific internal energy in area 3 [J/kg] as function of pressure p [Pa], temperature t [K]:
Specific entropy in area 3 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:
Specific enthalpy in area 3 [J/kg] as function of pressure p [Pa], temperature t [K]:
Sound velocity in area 3 [m/sec] as function of pressure p [Pa], temperature t [K]:
Specific volume in area 5 [m3/kg] as function of pressure p [Pa], temperature t [K]:
Specific internal energy in area 5 [J/kg] as function of pressure p [Pa], temperature t [K]:
Specific entropy in area 5 [J/(kg·K)] as function of pressure p [Pa], temperature t [K]:
Specific enthalpy in area 5 [J/kg] as function of pressure p [Pa], temperature t [K]:
Sound velocity in area 5 [m/sec] as function of pressure p [Pa], temperature t [K]:
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]:
Thermal conduction of steam at saturation line [W/(m·K)] as function of temperature t [K]:
Thermal conduction of water at saturation line [W/(m·K)] 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], degree of dryness x:
Specific enthalpy in double phase area [J/kg] as function of temperature t [K], degree of dryness x:
Sound velocity in double phase area [m/sec] as function of temperature t [K], degree of dryness x:
wspTHERMCONDSTX (t, x)
wspDYNVISSTX (t, x)
Prandtl number in double phase area as function of temperature t [K], degree of dryness x:
wspPRANDTLESTX (t, x)
wspKINVISSTX (t, x)
Isoentropic exponent in double phase area as function of temperature t [K], degree of dryness x:
Degree of dryness as function of temperature t [K], specific volume v [m3/kg]:
Degree of dryness as function of temperature t [K], specific internal energy u [J/kg]:
Degree of dryness as function of temperature t [K], specific entropy s [J/(kg·K)]:
Degree of dryness as function of temperature t [K], specific enthalpy h [J/kg]:
Degree of dryness as function of temperature t [K], sound velocity w [m/sec]:
Degree of dryness as function of temperature t [K], thermal conduction tc [W/(m·K)]:
wspXSTTHERMCOND (t, tc)
Degree of dryness as function of temperature t [K], dynamic viscosity dv [Pa·sec]:
wspXSTDYNVIS (t, dv)
Degree of dryness as function of temperature t [K], kinematic viscosity kv [m2/sec]:
wspXSTKINVIS (t, kv)
Degree of dryness as function of temperature t [K], Prandtl number pr:
wspXSTPRANDTLE (t, pr)
Degree of dryness as function of temperature t [K], Isoentropic exponent 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]:
Set and return initial value for water in area 3 [kg/m3] as function of density r [kg/m3]:
Set and return the initial value for steam in area 3 [kg/m3] as function of density r [kg/m3]: