Quantitative and visual characterization of asphaltenic components of heavy-oil after solvent interaction at different temperatures and pressures

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• 作者：Laura Moreno Arciniegas ; Tayfun Babadagli ; ^{tayfun@ualberta.ca" class="auth_mail}
• 关键词：Asphaltene precipitation ; Heavy-oil ; Elevated temperature and pressure ; Flocculation ; Visual analysis of asphaltene
• 刊名：Fluid Phase Equilibria
• 出版年：25 March, 2014
• 年：2014
• 卷：366
• 期：Complete
• 页码：74-87
• 全文大小：4968 K

文摘

Due to inefficiency of steam injection caused by technical, economic, and operational reasons, solvent methods have received special attention in heavy oil and bitumen recovery recently. Solvent-based recovery processes improves crude oil production and quality because underground in situ upgrading takes place after heavy oil is diluted with a light hydrocarbon solvent. Consequently, crude oil mobility increases due to significant reduction in viscosity caused by the asphaltene precipitation. However, solvent driven recovery processes are quite complex on account of the 鈥渁sphaltene destabilization鈥?that takes place due to changes in temperature, pressure, crude oil composition, and solvent dissolved in oil. As a result of this destabilization, the asphaltene particles start to flocculate, and eventually may plug the pores in the reservoir due to larger asphaltene particle agglomeration in the reservoir.

In this paper, the deasphalting of a heavy oil sample [8.67掳API] was carried out using an optical PVT cell. The experiments were undertaken at different temperature ranges [122 掳F (50 掳C)-230 掳F (110 掳C)] and pressure ranges (30-500 psig), which are the suggested ranges applicable to typical Canadian oilsands or similar shallow heavy-oil deposits around the world. Three light hydrocarbon solvents (propane, n-hexane, and n-decane) were used to break the stability of the asphaltene in the crude oil. An experimental methodology for 鈥渁sphaltene precipitation fraction鈥?was developed in order to determine the effect of temperature, pressure, and solvent type on the amount of asphaltene precipitation. The experimental methodology was complemented through visual observations of asphaltene characteristics on the PVT cell as well as using optical microscopy. In addition, the refractive index measurements at the onset of precipitation were used to evaluate the changes in the oil after interacting with the solvent at different temperatures and pressures.

Overall, the results showed that precipitated asphaltene fraction increases when the concentration of the resins goes down after the deasphalting of crude oil with solvent. In addition, the aggregation of asphaltene particles increases with increasing temperature [122 掳F (50 掳C)-230 掳F (110 掳C)] and pressure (from 30 psig to 500 psig), and decreasing solvent carbon number (from C10 to C3). At the end, a comparative analysis of the quantitative and qualitative results from the experiments is provided. Based on these observations, the characteristics of asphaltene were classified in terms of their shape, size, and amount for different oil/solvent types, pressure, and temperature. This study will eventually lead to the identification of the effects of asphaltene characteristics on pore plugging during heavy-oil/bitumen recovery by gravity drainage from oilsands.