Effect of Asphaltene on Phase Behavior and Thermophysical Properties of Solvent/Bitumen Systems

Azinfar, Bahareh; Haddadnia, Ali; Zirrahi, Mohsen; Hassanzadeh, Hassan; Abedi, Jalal

doi:10.1021/acs.jced.6b00836

Cited by 34 publications

(28 citation statements)

References 29 publications

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“…Its kinematic viscosity is reduced by more than a factor of five after the asphaltenes are removed. The density of DAO was also lower than HFO because asphaltenes possess a higher density due to the large molecular sizes and higher aromatic content [5,64]. The DAO has a slightly lower C content and a slightly higher H content.…”

Section: Resultsmentioning

confidence: 98%

Characterization of deasphalted heavy fuel oil using APPI (+) FT-ICR mass spectrometry and NMR spectroscopy

Jameel

Khateeb

Elbaz

et al. 2019

Fuel

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Section: Resultsmentioning

confidence: 98%

Characterization of deasphalted heavy fuel oil using APPI (+) FT-ICR mass spectrometry and NMR spectroscopy

Jameel

Khateeb

Elbaz

et al. 2019

Fuel

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“…The schematic and details of experimental apparatus were presented in our previous work . The apparatus includes one rocking equilibrium cell, a densitometer, a viscometer, an Isco pump, a Quizix pump, one pressure indicator, one transfer cell, and a sample cell.…”

Section: Methodsmentioning

confidence: 99%

Thermophysical properties of dimethyl ether/Athabasca bitumen system

et al. 2017

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Solvent-aided thermal recovery processes have recently gained practical and research interests among other thermal recovery methods due to their reduced environmental footprint and superior energy efficiency. One of the main challenges in design of solvent-based methods is selection of an appropriate solvent that maximizes the bitumen and solvent recoveries. This study attempts to introduce dimethyl ether (DME) as a non-conventional solvent for heavy oil and bitumen recovery. To investigate the performance of the proposed solvent, thermophysical properties of DME/bitumen are studied. Vapour-liquid equilibrium measurements including solubility, density, and viscosity are performed at three temperatures (100, 125, and 150 8C) and pressures up to 6 MPa. The results were compared with propane/bitumen and butane/bitumen systems. All the measured properties fall between propane and butane systems. The solubility and density data were fairly represented using PR-EoS with AARDs of 10.3 and 1.43 %, respectively, and viscosity data were correlated applying the Pederson corresponding state model with an AARD of 10.7 %. The results suggest that DME is a suitable substitute for solvents such as propane and butane in solvent-aided thermal recovery of bitumen from oil sands.

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“…Furthermore, ruthenium ion-catalyzed oxidation of the immature asphaltene was carried out to calculate the experimental data about the two different structures and densities. One of the two structures is reported to be Athabasca asphaltene (Azinfar et al 2017) and the second proposed structure is associated with asphaltene of Arab crude oil structure. The comparison of these structures with that shown in Fig.…”

Section: Simulation Detailsmentioning

confidence: 99%

A comparative study of density estimation of asphaltene structures using group contribution methods and molecular dynamic simulations for an Australian oil field

Elkahky

Lagat

Sarmadivaleh

et al. 2019

J Petrol Explor Prod Technol

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One of the major challenges faced by oil extraction industry is the unstable behavior of asphaltene formation, yet not fully understood. The prediction of asphaltene formation depends on the small changes in chemical characteristics and composition of the crude oil. Consequently, the study of molecular structure and molecular properties such as density is of a great practical interest. Other properties become very complex to assess when the asphaltene fraction contains 10 5 different molecules. Average molecular parameters are used to obtain information about asphaltenes. The density of the asphaltenes can easily be calculated and, thus, can be used to evaluate predictive capacities of the average structure. This present work of molecular dynamic simulations was carried out to evaluate the asphaltene densities of an Australian oil field. Simulations of molecular dynamics are used to assess the average structure densities representing different asphaltenes in a specific oil field. These simulations assist in predicting the formation of asphaltene structural model. Comparatively, the experimental densities are higher than the calculated ones. However, the calculated values demonstrate the appropriate trend. The chemical structure shows essential accuracy, as evidenced by average structures, which can be used to estimate the densities qualitatively. Hence, systematic study was carried out on the basis of the effects of various structures on the calculated densities of asphaltene. The main characteristics of the molecules which yielded highest densities are those found with low hydrogen-carbon ratio and big condensed aromatic rings. Moreover, better and improved density values were produced by a recently developed group contribution method than simulations of molecular dynamics, which is still being lower than that of experimental values.

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Effect of Asphaltene on Phase Behavior and Thermophysical Properties of Solvent/Bitumen Systems

Cited by 34 publications

References 29 publications

Characterization of deasphalted heavy fuel oil using APPI (+) FT-ICR mass spectrometry and NMR spectroscopy

Characterization of deasphalted heavy fuel oil using APPI (+) FT-ICR mass spectrometry and NMR spectroscopy

Thermophysical properties of dimethyl ether/Athabasca bitumen system

A comparative study of density estimation of asphaltene structures using group contribution methods and molecular dynamic simulations for an Australian oil field

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