HIGH-PRESSURE PHASE-EQUILIBRIA FOR CARBON-DIOXIDE METHANOL-WATER SYSTEM - EXPERIMENTAL-DATA AND CRITICAL-EVALUATION OF MIXING RULES
Equilibrium phase compositions for the carbon dioxide-methanol-water system were measured at 313.2 K and pressures of 70, 100, and 120 bar. Three-phase equilibria for this system were also measured at 305.15, 308.15, and 311.15 K, temperatures and pressures near the critical point of carbon dioxide. The two- and three-phase equilibrium data were correlated with the Soave-Redlich-Kwong and Patel-Teja equations of state incorporated with various types of the local composition and Huron-Vidal mixing rules. The Huron-Vidal mixing rules were found to be superior to the local composition models in predicting two-phase equilibria. Since the pressure range covering the three-phase region was very narrow, the Huron-Vidal mixing rules could not accurately predict the experimental three-phase equilibria. However, if there were a slight change of pressure in phase calculation, the Huron mixing models could correctly predict the experimental three-phase region and equilibrium compositions.
- Publisher
- AMER CHEMICAL SOC
- Issue Date
- 1993-11
- Language
- English
- Article Type
- Article
- Keywords
VAPOR-LIQUID-EQUILIBRIUM; GIBBS ENERGY MODELS; ELEVATED PRESSURES; MULTIPHASE EQUILIBRIA; CUBIC EQUATION; STATE; MIXTURES; ETHANOL; UNIFAC
- Citation
INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH , v.32, no.11, pp.2881 - 2887
- ISSN
- 0888-5885
- Appears in Collection
- CBE-Journal Papers(저널논문)
- Files in This Item
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