Vapor–Liquid Equilibria Measurements for the Five Linear C<sub>6</sub> Esters with <i>n</i>-Octane

Cripwell, Jamie T.; Schwarz, Cara E.; Burger, Andries J.

doi:10.1021/acs.jced.5b01058

Cited by 13 publications

(12 citation statements)

References 57 publications

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“…This Results section primarily features low-pressure mixture predictions because the modeling of these systems forms an initial step in evaluating the newly generated groups. The integrity of new group-specific parameters and interaction parameters and the reliability of the pseudo-association approach are important to consider for pure-component 48 and n-nonane + 3-heptanone at 0.400 bar (△) 48 and (b) noctane + n-butyl ethanoate at 0.600 bar ( ◇ ) 50 and n-octane + propyl propanoate at 0.600 bar (△). 50 Figure 5.…”

Section: Resultsmentioning

confidence: 99%

“…The integrity of new group-specific parameters and interaction parameters and the reliability of the pseudo-association approach are important to consider for pure-component 48 and n-nonane + 3-heptanone at 0.400 bar (△) 48 and (b) noctane + n-butyl ethanoate at 0.600 bar ( ◇ ) 50 and n-octane + propyl propanoate at 0.600 bar (△). 50 Figure 5. Liquid-phase property predictions with SAFT-γ Mie (solid blue lines) of binary systems at 298.15 K and 1.013 bar, each containing a newly parametrized group: (a) excess enthalpy of n-heptane + 2butanone ( ◇ ), 47 n-heptane + 3-pentanone (△), 47 and n-heptane + propyl propanoate ( □ ) 60 and (b) speed of sound of n-heptane + 2butanone ( ◇ ) 61 and n-heptane + 3-pentanone (△).…”

Section: Resultsmentioning

confidence: 99%

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Expanding SAFT-γ Mie’s Application to Dipolar Species: 2-Ketones, 3-Ketones, and Propanoate Esters

Hurter

Cripwell

Burger

2020

Ind. Eng. Chem. Res.

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Statistical associating fluid theory (SAFT) equations of state (EoSs) are powerful thermodynamic modeling tools that show promise in application to a wide range of different properties and systems. SAFT-γ Mie, the group-contribution variant of the state-of-the-art SAFT-VR Mie, can describe new systems using transferable functional-group parameters. There had been a void in the modeling of nonself-associating dipolar species prior to this work, in which groups were parametrized for 2-ketones, 3-ketones, and n-alkyl propanoates (viz. CH2CO, CH3CO, and COOpr., respectively). These components occur in a wide variety of industrial processes and modeling them with SAFT-γ Mie presented the opportunity to evaluate the model’s treatment of dipolar interactions without a fundamental dipolar term in the EoS. Our new groups provide reliable binary mixture phase-equilibrium, excess enthalpy, and speed of sound predictions for all of the considered components, despite the fact that 2-ketone pure-component predictions are slightly less accurate than what is expected from such a complex SAFT model. The latter observation suggests that very precise modeling of smaller, highly dipolar molecules is challenging with a first-order group-contribution model, even in the SAFT-VR Mie-based framework. Binary mixture VLE predictions of ketone + n-alkane and ketone +1-alkanol systems are in good agreement with experimental data, suggesting that the pseudo-association approach used to treat the dipolar interactions of ketones is adequate, and that its nonrigorous nature does not inherently produce an erroneous representation of the balance between different intermolecular interactions. Two successful high-pressure binary system VLE predictions were also generated, which may spur further research into using SAFT-γ Mie and the new dipolar groups for modeling high-pressure systems.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Expanding SAFT-γ Mie’s Application to Dipolar Species: 2-Ketones, 3-Ketones, and Propanoate Esters

Hurter

Cripwell

Burger

2020

Ind. Eng. Chem. Res.

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“…The equilibrium temperature was measured with a 4-wire Pt-100 probe connected to a digital Hart Scientific Thermometer, with a calibrated uncertainty of 0.1 K between 313 and 413 K. The calibration was performed by a SANAS (South African National Accreditation System) approved laboratory, adhering to international calibration standards. The unit is the same as that used in our previous works and the reader is directed to the paper dealing with the ester/nalkane systems 20 for a detailed account of the experimental procedure. Duplicate analytical samples were prepared from each equilibrium phase using 2-ethyl-1-hexanol as a solvent.…”

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

“…In two previous works, a more systematic approach was taken in the generation of new phase equilibrium data for binary systems of hydrocarbons with medium length linear ketones 19 and esters. 20 There, VLE data for different structural isomers of the polar molecule coupled with the same n-alkane were generated and, in this way, the effect of the polar functional group location on phase behavior of the different isomers could be investigated. The rationale for this theoretical approach is to use the systematically measured phase equilibrium data, previously unavailable in the literature, as a test for the analytical capacity of predictive thermodynamic models.…”

Section: Introductionmentioning

confidence: 99%

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Vapor–Liquid Equilibria Measurements for Di-n-Propyl Ether and Butyl Ethyl Ether with n-Heptane

2016

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Isobaric vapor−liquid equilibrium (VLE) data were measured for two binary systems comprising n-heptane with one of di-n-propyl ether (DNPE) or butyl ethyl ether (BEE) at 60 kPa. Slight positive deviations from ideality were apparent in both systems, but not so strong as to result in azeotropic behavior. The data for both systems were shown to be thermodynamically consistent using both the Wisniak L/W and McDermott-Ellis consistency tests. Data were further well correlated by the nonrandom twoliquid (NRTL) activity coefficient model and fairly predicted using the Dortmund-modified UNIFAC model. The data presented serve to fill the gap in the literature for data sets of structural isomers of C 6 ethers with n-heptane, where data for the linear isomers are absent. This data, combined with that available for the branched isomers, serve to highlight the role of polar functional group location on associated mixture behavior in such systems.

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Enhancement of the Lee–Kesler–Plöcker Equation of State for Calculating Thermodynamic Properties of Long-Chain Alkanes

Sabozin,

Jäger,

Thol

2024

Int J Thermophys

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Two optimization approaches to correct the physical limitations of the Lee–Kesler–Plöcker equation of state for the application to long-chain hydrocarbons are presented. The quality of the approaches is evaluated by comparisons with experimental data and reference equations of state. The calculation of thermodynamic properties for alkanes up to squalane is possible with both approaches, for some of which no highly accurate fundamental equation of state is available in the literature. For the first approach, the original parameter set was refitted with constraints guaranteeing correct behavior of the equation in the liquid state. The densities of long-chain hydrocarbons are reproduced with small deviations, while the results for some short-chain alkanes are worsened. For the second approach, existing Helmholtz energy equations of state are utilized, while keeping the linear interpolation scheme via the acentric factor. Significant improvements are achieved for all fluids considered.

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Vapor–Liquid Equilibria Measurements for the Five Linear C₆ Esters with n-Octane

Cited by 13 publications

References 57 publications

Expanding SAFT-γ Mie’s Application to Dipolar Species: 2-Ketones, 3-Ketones, and Propanoate Esters

Expanding SAFT-γ Mie’s Application to Dipolar Species: 2-Ketones, 3-Ketones, and Propanoate Esters

Vapor–Liquid Equilibria Measurements for Di-n-Propyl Ether and Butyl Ethyl Ether with n-Heptane

Enhancement of the Lee–Kesler–Plöcker Equation of State for Calculating Thermodynamic Properties of Long-Chain Alkanes

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Vapor–Liquid Equilibria Measurements for the Five Linear C6 Esters with n-Octane

Cited by 13 publications

References 57 publications

Expanding SAFT-γ Mie’s Application to Dipolar Species: 2-Ketones, 3-Ketones, and Propanoate Esters

Expanding SAFT-γ Mie’s Application to Dipolar Species: 2-Ketones, 3-Ketones, and Propanoate Esters

Vapor–Liquid Equilibria Measurements for Di-n-Propyl Ether and Butyl Ethyl Ether with n-Heptane

Enhancement of the Lee–Kesler–Plöcker Equation of State for Calculating Thermodynamic Properties of Long-Chain Alkanes

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Product

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Vapor–Liquid Equilibria Measurements for the Five Linear C₆ Esters with n-Octane