Liquid-Phase Thermodynamic Properties for Propane (1), <i>n</i>-Butane (2), and Isobutane (3)

Kayukawa, Yohei; Hasumoto, Masaya; Kano, Yasunobu; Watanabe, Koichi

doi:10.1021/je049672l

Cited by 36 publications

(61 citation statements)

References 60 publications

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“…The behaviors of density values calculated from the pressure-explicit mBWR-type equation of state developed by Younglove and Ely [16] and the multi-parameter Helmholtz-type equation of state developed by Span and Wagner [17] are also included for comparisons. The new literature data (Claus et al [10], Glos et al [11], and Kayukawa et al [12]) reasonably agreed with the present measurements. In the higher pressure region above 103 MPa, the behavior of calculated density values from three models (by Younglove and Ely [16], Miyamoto and Watanabe [15], and Span and Wagner [17]) and the present measurements agreed reasonably as shown in Fig.…”

Section: Resultssupporting

confidence: 91%

“…Figure 3 shows relative pressure deviations of the present measurements from the Wagner-type vapor-pressure correlation for propane proposed by Miyamoto and Watanabe [15]. The vapor-pressure data by Reamer et al [3], Helgeson and Sage [18], Teichmann [19], Kratzke [20], Thomas and Harrison [6], Glos et al [11], and Kayukawa et al [12] were also included in Fig. 3.…”

Section: Resultsmentioning

confidence: 67%

“…. , Younglove-Ely model [16]; --, Span-Wagner model [17]; , Claus et al [10]; , Glos et al [11]; * , Kayukawa et al [12]. +, Teichmann [19]; , Kratzke [20]; , Thomas and Harrison [6]; ♦, Glos et al [11]; ×, Kayukawa et al [12].…”

Section: Resultsunclassified

“…In previous publications [1,2] we reported measurements of the vapor pressure and ( p, ρ, T ) properties for isobutane by a metal-bellows variable volumometer at temperatures from 280 to 440 K at pressures up to Reamer [3] 306 Mercury piezometer 0.1-69 1-576 311-511 Dittmer [4] 336 Isochoric method 1.0-103 320-590 273-413 Ely [5] 222 Isochoric method 0.3-43 508-652 166-324 Thomas [6] 736 Mercury piezometer 0.6-40 35-549 258-623 Haynes [7] 196 Magnetic suspension densimeter 0.6-37 493-741 90-300 Kratzke [8] 60 Isochoric method 2.2-61 441-565 247-491 Straty [9] 144 Burnett expansion (isochoric) 0.2-35 2-347 363-598 Claus [10] 130 Single-sinker densimeter 2.0-30 24-506 340-520 Glos [11] 72 Two-sinker densimeter 0.2-12 3-727 95-340 Kayukawa [12] 200 MPa. In this paper, the results of (p, ρ, T) measurements for propane using the same apparatus are presented for the compressed liquid phase for temperatures from 340 to 400 K at pressures up to 200 MPa.…”

Section: Introductionmentioning

confidence: 99%

“…On the other hand, comparatively new information for (p, ρ, T) property measurements were reported from 2002 to 2005 as summarized in Table I. These sets of accurate measurements from three sources were obtained by means of buoyancy methods (single-sinker densimeter below 30 MPa [10] and two-sinker densimeter below 12 MPa [11]) and vibrating tube densimeter below 7 MPa [12].…”

Section: Introductionmentioning

confidence: 99%

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Measurements of Vapor Pressures from 280 to 369 K and (p, ρ, T) Properties from 340 to 400 K at Pressures to 200 MPa for Propane

Miyamoto

Uematsu

2006

Int J Thermophys

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Measurements of (p, ρ, T) properties for compressed liquid propane have been obtained by means of a metal-bellows variable volumometer at temperatures from 340 to 400 K at pressures up to 200 MPa. The volumefraction purity of the propane sample was 0.9999. The expanded uncertainties (k = 2) of temperature, pressure, and density measurements have been estimated to be less than 3 mK; 1.5 kPa (p < = 7 MPa), 0.06% (7 MPa

150 MPa); and 0.11%, respectively. Four (p, ρ, T) measurements at the same temperatures and pressures as literature values have been conducted for comparisons. In addition, vapor pressures were measured at temperatures from 280 to 369 K. Furthermore, comparisons of available equations of state with the present measurements are reported.

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Section: Resultssupporting

confidence: 91%

Section: Resultsmentioning

confidence: 67%

Section: Resultsunclassified

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Measurements of Vapor Pressures from 280 to 369 K and (p, ρ, T) Properties from 340 to 400 K at Pressures to 200 MPa for Propane

Miyamoto

Uematsu

2006

Int J Thermophys

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Three‐parameter cubic equation of state for pure components of heavy oils

Kumar

Henni

2010

Can J Chem Eng

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A three-parameter cubic equation of state for pure hydrocarbons is proposed to model PVT properties of heavy hydrocarbons found in heavy oils. Thirty hydrocarbons up to C40 and some commonly found (associated) non-hydrocarbons in heavy oils have been used to regress the parameters. Predicted results from the proposed equation for the liquid density, vapour pressure, saturated liquid density, and saturated vapour density have been compared with the widely used Peng-Robinson (PR), Soave-Redlich-Kwong (SRK), and Patel and Teja (PT) equations of state.With the increase in carbon number in hydrocarbon, the % average absolute errors in liquid density, vapour pressure, and saturated liquid density prediction using PR, SRK, and PT equations of state were found to increase, whereas the proposed equation shows consistency in the prediction, with a % average absolute error of 2.5% only.Uneéquation d'état cubiqueà trois paramètres pour hydrocarbures purs est proposée pour modéliser les propriétés PVT d'hydrocarbures lourds que l'on trouve dans les pétroles lourds. Trente hydrocarbures allant jusqu'à C40 et certains autres composés non hydrocarbures que l'on trouve couramment (associés) dans les pétroles lourds ontété utilisés pour la régression des paramètres. Les résultats prédits provenant de l'équation proposée pour la densité de liquide, la pression de vapeur, la densité de liquide saturé et la densité de vapeur saturée ontété comparés avec leś equations d'état largement utilisées de Peng-Robinson (PR), Soave-Redlich-Kwong (SRK) et Patel et Teja (PT). Avec l'augmentation du nombre d'atomes de carbone dans l'hyrocarbure, les erreurs absolues moyennes en % augmentent sur les prédictions de la densité de liquide, de la pression de vapeur et la densité de liquide saturé en utilisant leséquations d'état de PR, SRK et PT. En revanche, l'équation proposée montre une certaine homogénéité avec les prédictions, avec une erreur absolue moyenne en pourcentage de 2,5 seulement.

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Rapid Measurements of Thermodynamic Properties for Alternative Refrigerants with Vibrating-Tube Densimeter

et al. 2005

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More than 2000 PVT data in the liquid phase, vapor phase, and at saturation boundaries have been obtained for pure compounds of several alternative refrigerants. In addition, more than 1000 liquid-density data have been obtained for several binary and ternary mixtures. The alternative refrigerants measured in the present study include CF 3 OCH 3 (trifluoromethyl methyl ether) and CF 3 CF 2 OCH 3 (pentafluoroethyl methyl ether), which are hydrofluoroethers developed by RITE (the Research Institute of Innovative Technology for the Earth, Japan), and typical hydrocarbons, such as propane, n-butane, isobutene, and their binary and ternary mixtures. The measurement uncertainties are estimated to be 3 to 7 mK for temperature, 0.26 kPa or 0.022% whichever is greater for pressure, and 0.07 kg · m −3 or 0.024% whichever is greater for density. The present measurement system took only a few minutes to get one PVT datum, and one or two days to complete all the measurements for a single fluid at temperatures from 240 to 380 K and at pressures up to 7 MPa. In addition, an empirical equation of state (EoS) for the liquid phase was developed on the basis of the present data, and the EoS nicely reproduces not only the present data but also existing data reported by other researchers.

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Liquid-Phase Thermodynamic Properties for Propane (1), n-Butane (2), and Isobutane (3)

Cited by 36 publications

References 60 publications

Measurements of Vapor Pressures from 280 to 369 K and (p, ρ, T) Properties from 340 to 400 K at Pressures to 200 MPa for Propane

Measurements of Vapor Pressures from 280 to 369 K and (p, ρ, T) Properties from 340 to 400 K at Pressures to 200 MPa for Propane

Three‐parameter cubic equation of state for pure components of heavy oils

Rapid Measurements of Thermodynamic Properties for Alternative Refrigerants with Vibrating-Tube Densimeter

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