The prediction of the thermodynamic properties of fluids and fluid mixtures-II Liquid-vapour equilibrium in the system argon + nitrogen + oxygen

Methods are described for the prediction of the thermodynamic properties based on earlier work on the principle of correspondii states and its extensions. The calculations cover compression factors, enthalpies, Joule-Thomson coefficients, liquid-vapour equilibria, and flash separations. The overall

Methods are described for the prediction of critical loci, upper and lower critical end points, and azeotropic lines in binary and multicomponent mixtures. The results agree quantitatively with experiment for mixtures with only one liquid phase, and describe, at least qualitatively, many of the topo

The principle of corresponding states is a sound but limited principle from which to predict the thermodynamic properties of pure fluids. We describe formal extensions of the principle to cover wide classes of fluids and their mixtures. These extensions are made in a general form, from which most pr

In this paper, a previously developed first-order hard sphere perturbation theory of a ternary fluid mixture (Fotouh and Shukla, 1996, Chem. Enyn9 Sci. 51, 49234931) is applied to predict excess properties of a real ternary fluid mixture using a theoretically consistent combination rule. We consider

The vapour-hqmd eqmhbrla of the system acetlc acid-toluene have been modelled both by extstmg methods and by a new model mcorporatmg a concentration dependent hquld phase association constant The vahdtty of the models was tested by carrying out Barker fits on the Isothermal data avadable m the liter