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W2018201043 startingPage "147" @default.
W2018201043 abstract "Five different objective functions were studied with the purpose of analyzing their performance for parameters estimation of vapor–liquid equilibrium models for a series of 13 non-polar and 13 polar asymmetric binary mixtures at high pressures. Peng–Robinson equation of state coupled with the Wong–Sandler mixing rules were used for modeling the VLE in all cases. The first two objective functions are based on the calculation of the distribution coefficients for each component in the mixture and the remaining objective functions involve additional calculations of other quantities such as the bubble point pressure. In general, the optimal parameters obtained from all objective functions showed a good prediction capacity of the behavior of the vapor phase. It is also demonstrated that a good prediction of the pressure depends on the form of the objective function. It was found that one objective function has slight advantages over the other analyzed objective functions: first, it does not involve additional iterative calculations as the bubble point or isothermal flash for each data point; second, the optimal second virial coefficient interaction parameter shows to be in concordance with the statistical thermodynamic postulates; and finally, VLE predictions using the optimal parameters obtained with the help of this objective function show very good representations of both the vapor phase and pressure." @default.
W2018201043 created "2016-06-24" @default.
W2018201043 creator A5012825202 @default.
W2018201043 creator A5014817838 @default.
W2018201043 creator A5081603506 @default.
W2018201043 date "2006-10-01" @default.
W2018201043 modified "2023-09-27" @default.
W2018201043 title "Objective functions analysis in the minimization of binary VLE data for asymmetric mixtures at high pressures" @default.
W2018201043 cites W1965602029 @default.
W2018201043 cites W1972589292 @default.
W2018201043 cites W1973550406 @default.
W2018201043 cites W1974430435 @default.
W2018201043 cites W1975902503 @default.
W2018201043 cites W1976246681 @default.
W2018201043 cites W1978743252 @default.
W2018201043 cites W1980977480 @default.
W2018201043 cites W1982186589 @default.
W2018201043 cites W1982378548 @default.
W2018201043 cites W1982393635 @default.
W2018201043 cites W1983873509 @default.
W2018201043 cites W1989629764 @default.
W2018201043 cites W1989980380 @default.
W2018201043 cites W1991089924 @default.
W2018201043 cites W1991261261 @default.
W2018201043 cites W1992199226 @default.
W2018201043 cites W1995140675 @default.
W2018201043 cites W1995524747 @default.
W2018201043 cites W1997851763 @default.
W2018201043 cites W2000350896 @default.
W2018201043 cites W2007116953 @default.
W2018201043 cites W2008660941 @default.
W2018201043 cites W2009441149 @default.
W2018201043 cites W2009695771 @default.
W2018201043 cites W2011043234 @default.
W2018201043 cites W2011975015 @default.
W2018201043 cites W2013280991 @default.
W2018201043 cites W2016347476 @default.
W2018201043 cites W2017580037 @default.
W2018201043 cites W2019841178 @default.
W2018201043 cites W2031179965 @default.
W2018201043 cites W2032547362 @default.
W2018201043 cites W2036922457 @default.
W2018201043 cites W2037487590 @default.
W2018201043 cites W2038974771 @default.
W2018201043 cites W2040917064 @default.
W2018201043 cites W2041346605 @default.
W2018201043 cites W2045194735 @default.
W2018201043 cites W2046592699 @default.
W2018201043 cites W2050007531 @default.
W2018201043 cites W2052972838 @default.
W2018201043 cites W2052979193 @default.
W2018201043 cites W2056473329 @default.
W2018201043 cites W2058872660 @default.
W2018201043 cites W2058952255 @default.
W2018201043 cites W2059637197 @default.
W2018201043 cites W2060554410 @default.
W2018201043 cites W2061254544 @default.
W2018201043 cites W2065232503 @default.
W2018201043 cites W2068689087 @default.
W2018201043 cites W2070965450 @default.
W2018201043 cites W2075413746 @default.
W2018201043 cites W2079456126 @default.
W2018201043 cites W2079956471 @default.
W2018201043 cites W2084734754 @default.
W2018201043 cites W2088375058 @default.
W2018201043 cites W2090238496 @default.
W2018201043 cites W2092046123 @default.
W2018201043 cites W2094572804 @default.
W2018201043 cites W2094913295 @default.
W2018201043 cites W2098740155 @default.
W2018201043 cites W2099586872 @default.
W2018201043 cites W2105530273 @default.
W2018201043 cites W2107026614 @default.
W2018201043 cites W2129288307 @default.
W2018201043 cites W2132165791 @default.
W2018201043 cites W2158657468 @default.
W2018201043 cites W2171250148 @default.
W2018201043 cites W2497853401 @default.
W2018201043 cites W4232704756 @default.
W2018201043 cites W4247654807 @default.
W2018201043 cites W2076315449 @default.
W2018201043 doi "https://doi.org/10.1016/j.fluid.2006.08.003" @default.
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