In thermodynamics, a departure function is defined for any thermodynamic property as the difference between the property as computed for an ideal gas and the property of the species as it exists in the real world, for a specified temperature T and pressure P. Common departure functions include those for enthalpy, entropy, and internal energy.
Departure functions are used to calculate real fluid extensive properties (i.e. properties which are computed as a difference between two states). A departure function gives the difference between the real state, at a finite volume or non-zero pressure and temperature, and the ideal state, usually at zero pressure or infinite volume and temperature.
For example, to evaluate enthalpy change between two points h(v1,T1) and h(v2,T2) we first compute the enthalpy departure function between volume v1 and infinite volume at T = T1, then add to that the ideal gas enthalpy change due to the temperature change from T1 to T2, then subtract the departure function value between v2 and infinite volume.
Departure functions are computed by integrating a function which depends on an equation of state and its derivative.
Departure functions for Peng–Robinson equation of stateedit
The Peng–Robinson equation of state relates the three interdependent state properties pressure P, temperature T, and molar volume Vm. From the state properties (P, Vm, T), one may compute the departure function for enthalpy per mole (denoted h) and entropy per mole (s):[2]
Typically, one knows two of the three state properties (P, Vm, T), and must compute the third directly from the equation of state under consideration. To calculate the third state property, it is necessary to know three constants for the species at hand: the critical temperatureTc, critical pressurePc, and the acentric factorω. But once these constants are known, it is possible to evaluate all of the above expressions and hence determine the enthalpy and entropy departures.
Referencesedit
^Poling, Prausnitz, O'Connell: The Properties of Gases and Liquids, 5th Ed., McGraw-Hill, 2001. p. 6.5.
^Kyle, B.G.: Chemical and Process Thermodynamics, 3rd Ed., Prentice Hall PTR, 1999. p. 118-123.
departure, function, thermodynamics, departure, function, defined, thermodynamic, property, difference, between, property, computed, ideal, property, species, exists, real, world, specified, temperature, pressure, common, departure, functions, include, those, . In thermodynamics a departure function is defined for any thermodynamic property as the difference between the property as computed for an ideal gas and the property of the species as it exists in the real world for a specified temperature T and pressure P Common departure functions include those for enthalpy entropy and internal energy Departure functions are used to calculate real fluid extensive properties i e properties which are computed as a difference between two states A departure function gives the difference between the real state at a finite volume or non zero pressure and temperature and the ideal state usually at zero pressure or infinite volume and temperature For example to evaluate enthalpy change between two points h v1 T1 and h v2 T2 we first compute the enthalpy departure function between volume v1 and infinite volume at T T1 then add to that the ideal gas enthalpy change due to the temperature change from T1 to T2 then subtract the departure function value between v2 and infinite volume Departure functions are computed by integrating a function which depends on an equation of state and its derivative Contents 1 General expressions 2 Departure functions for Peng Robinson equation of state 3 References 4 Correlated termsGeneral expressions editGeneral expressions for the enthalpy H entropy S and Gibbs free energy G are given by 1 Hig HRT V T Z T V dVV 1 ZSig SR V T Z T V 1 Z dVV ln ZGig GRT V 1 Z dVV ln Z 1 Z displaystyle begin aligned frac H mathrm ig H RT amp int V infty left T left frac partial Z partial T right V right frac dV V 1 Z 2ex frac S mathrm ig S R amp int V infty left T left frac partial Z partial T right V 1 Z right frac dV V ln Z 2ex frac G mathrm ig G RT amp int V infty 1 Z frac dV V ln Z 1 Z end aligned nbsp Departure functions for Peng Robinson equation of state editThe Peng Robinson equation of state relates the three interdependent state properties pressure P temperature T and molar volume Vm From the state properties P Vm T one may compute the departure function for enthalpy per mole denoted h and entropy per mole s 2 hT P hT Pideal RTC Tr Z 1 2 078 1 k aln Z 2 414BZ 0 414B sT P sT Pideal R ln Z B 2 078k 1 kTr k ln Z 2 414BZ 0 414B displaystyle begin aligned h T P h T P mathrm ideal amp RT C left T r Z 1 2 078 1 kappa sqrt alpha ln left frac Z 2 414B Z 0 414B right right 1 5ex s T P s T P mathrm ideal amp R left ln Z B 2 078 kappa left frac 1 kappa sqrt T r kappa right ln left frac Z 2 414B Z 0 414B right right end aligned nbsp where a displaystyle alpha nbsp is defined in the Peng Robinson equation of state Tr is the reduced temperature Pr is the reduced pressure Z is the compressibility factor and k 0 37464 1 54226w 0 26992w2 displaystyle kappa 0 37464 1 54226 omega 0 26992 omega 2 nbsp B 0 07780PrTr displaystyle B 0 07780 frac P r T r nbsp Typically one knows two of the three state properties P Vm T and must compute the third directly from the equation of state under consideration To calculate the third state property it is necessary to know three constants for the species at hand the critical temperature Tc critical pressure Pc and the acentric factor w But once these constants are known it is possible to evaluate all of the above expressions and hence determine the enthalpy and entropy departures References edit Poling Prausnitz O Connell The Properties of Gases and Liquids 5th Ed McGraw Hill 2001 p 6 5 Kyle B G Chemical and Process Thermodynamics 3rd Ed Prentice Hall PTR 1999 p 118 123 Correlated terms editResidual property physics Retrieved from https en wikipedia org w index php title Departure function amp oldid 1123460407, wikipedia, wiki, book, books, library,
