Extended corresponding states model for fluids and fluid mixtures: I. Shape factor model for pure fluids

J. F. Estela-Uribe; J. P.M. Trusler

doi:10.1016/S0378-3812(02)00190-5

Extended corresponding states model for fluids and fluid mixtures: I. Shape factor model for pure fluids

J. F. Estela-Uribe, J. P.M. Trusler

Imperial College London

Producción: Contribución a una revista › Artículo › revisión exhaustiva

16 Citas (Scopus)

Resumen

We present a new and accurate extended corresponded states model for the prediction of thermodynamic properties of pure fluids. This model is based on shape factors expressed as functions of the reduced temperature and density, the acentric factor and the critical compression factor. Substance-dependent coefficients were optimised against volumetric, VLE and acoustic data for the light hydrocarbons from ethane to n-pentane, ethylene, nitrogen, carbon dioxide, oxygen, argon and carbon monoxide. With this model, fluid properties are estimated largely within their experimental uncertainty. The model was tested for reduced temperatures T_r in the interval 0.52≤T_r≤3.33 and for reduced densities up to 2.8. The work reported here is a necessary precursor to the development of an extended corresponding states (ECS) equation of state for natural gas systems and mixtures of natural gas constituents.

Idioma original	Inglés
Páginas (desde-hasta)	15-40
Número de páginas	26
Publicación	Fluid Phase Equilibria
Volumen	204
N.º	1
DOI	https://doi.org/10.1016/S0378-3812(02)00190-5
Estado	Publicada - 15 ene. 2003

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title = "Extended corresponding states model for fluids and fluid mixtures: I. Shape factor model for pure fluids",

abstract = "We present a new and accurate extended corresponded states model for the prediction of thermodynamic properties of pure fluids. This model is based on shape factors expressed as functions of the reduced temperature and density, the acentric factor and the critical compression factor. Substance-dependent coefficients were optimised against volumetric, VLE and acoustic data for the light hydrocarbons from ethane to n-pentane, ethylene, nitrogen, carbon dioxide, oxygen, argon and carbon monoxide. With this model, fluid properties are estimated largely within their experimental uncertainty. The model was tested for reduced temperatures Tr in the interval 0.52≤Tr≤3.33 and for reduced densities up to 2.8. The work reported here is a necessary precursor to the development of an extended corresponding states (ECS) equation of state for natural gas systems and mixtures of natural gas constituents.",

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N2 - We present a new and accurate extended corresponded states model for the prediction of thermodynamic properties of pure fluids. This model is based on shape factors expressed as functions of the reduced temperature and density, the acentric factor and the critical compression factor. Substance-dependent coefficients were optimised against volumetric, VLE and acoustic data for the light hydrocarbons from ethane to n-pentane, ethylene, nitrogen, carbon dioxide, oxygen, argon and carbon monoxide. With this model, fluid properties are estimated largely within their experimental uncertainty. The model was tested for reduced temperatures Tr in the interval 0.52≤Tr≤3.33 and for reduced densities up to 2.8. The work reported here is a necessary precursor to the development of an extended corresponding states (ECS) equation of state for natural gas systems and mixtures of natural gas constituents.

AB - We present a new and accurate extended corresponded states model for the prediction of thermodynamic properties of pure fluids. This model is based on shape factors expressed as functions of the reduced temperature and density, the acentric factor and the critical compression factor. Substance-dependent coefficients were optimised against volumetric, VLE and acoustic data for the light hydrocarbons from ethane to n-pentane, ethylene, nitrogen, carbon dioxide, oxygen, argon and carbon monoxide. With this model, fluid properties are estimated largely within their experimental uncertainty. The model was tested for reduced temperatures Tr in the interval 0.52≤Tr≤3.33 and for reduced densities up to 2.8. The work reported here is a necessary precursor to the development of an extended corresponding states (ECS) equation of state for natural gas systems and mixtures of natural gas constituents.

KW - Compressibility factor

KW - Corresponding states

KW - Density

KW - Equation of state

KW - Heat capacities

KW - Speed of sound

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Extended corresponding states model for fluids and fluid mixtures: I. Shape factor model for pure fluids

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