Residual Properties Team Members: Sergio Luna Ain Lockman Kimberly Cagle Harisimran Jakhar.

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Presentation transcript:

Residual Properties Team Members: Sergio Luna Ain Lockman Kimberly Cagle Harisimran Jakhar

Definition  A residual property is the difference between the actual and the ideal value of an extensive thermodynamic property at the same temperature and pressure

General Formula M R = M – M ig Where M is the molar value of the property (e.g.: V,U,H,S or G)

Explanation  A residual Property acts as a correction for the ideal equations for H ig and S ig.  In other words we can use the residual properties to get the actual enthalpy and entropy of a vapor.

Residuals for Liquids  Residual properties are not useful for liquids because of the large enthalpy and entropy changes of vaporization that would have to be included in H R and S R. Instead of calculating H and S, we use the equations

Residual Enthalpy and Entropy (6.46) (6.48)

Compressibility Factor Z  May be calculated from experimental PVT data. Equations 6.46 and 6.48 would be evaluated by numerical or graphical methods.  These equations may be evaluated analytically if Z is expressed as a function of T and P by a volume- explicit equation of state.

Enthalpy and Entropy From Residual Properties Substitute ideal gas equations into the top equation

Enthalpy and Entropy From Residual Properties (cont’d) Chapter 4 Chapter 5 Recall…. Substitution yields…

This example was taken from the book

Calculation of H R and S R at 360K and bar by application of Eqs. (6.46) and (6.48) requires evaluation of two integrals:

 Graphical integration requires simple plots of Values of (z-1)/P are found from the compressibility factor data at 360 K The quantity for (∂Z/∂T) P /P requires evaluation of partial derivative (∂Z/∂T) P given by the plot of Z vs T at constant pressure.

 For this purpose separate plots are made of Z vs T for each pressure at which compressibility factor data are given and a slope is determined at 360 K for each curve ( this can be done by taking a tangent line at 360 k). Data gathered from this is shown below.