Enhanced Heavy Oil Recovery by Intermittent CO2 Injection

Seyyedsar, Seyyed Mehdi; Farzaneh, Seyed Amir; Sohrabi, Mehran

doi:10.2118/175140-ms

Cited by 14 publications

(13 citation statements)

References 12 publications

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“…1 These properties make them excellent solvents for many applications, for example, the production of gasoline, 2 liquefied petroleum gas (LPG) 3 and methanol 4 from syngas, the production of biofuel using alcohols, 5,6 and the use of supercritical CO 2 to improve the recovery factor of oil and gas condensate reservoirs. 7,8 In the vicinity of a critical point, fluids have an asymptotic singular behavior, 9,10 which is different from the one implied by classical equations of state (EOSs). This contrast is due to the long-range fluctuations of the order parameter associated with the critical phase transition, which in vapor−liquid transitions are related to the density of the system.…”

Section: ■ Introductionmentioning

confidence: 97%

“…These properties make them excellent solvents for many applications, e.g. the production of gasoline [2], liquefied petroleum gas (LPG) [3] and methanol [4] from syngas, the production of biofuel using alcohols [5] [6], and the use of supercritical CO 2 to improve the recovery factor of oil and gas condensate reservoirs [7] [8].…”

Section: Introductionmentioning

confidence: 99%

“…Near-critical and supercritical fluids are substances for which temperature and pressure conditions are close to or above the critical value and possess special characteristics; that is, gas-like viscosity and diffusivity, as well as liquid-like density and solvating properties . These properties make them excellent solvents for many applications, for example, the production of gasoline, liquefied petroleum gas (LPG) and methanol from syngas, the production of biofuel using alcohols, , and the use of supercritical CO 2 to improve the recovery factor of oil and gas condensate reservoirs. , …”

Section: Introductionmentioning

confidence: 99%

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Application of a Crossover Equation of State to Describe Phase Equilibrium and Critical Properties of n-Alkanes and Methane/n-Alkane Mixtures

2017

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Crossover equations of state (EOSs) are models that incorporate density fluctuations into mean-field thermodynamic models, changing their behavior close to the critical point. In this way, they are capable of describing the analytical behavior of fluids far from the critical region and the asymptotic one near the critical point. Although several crossover EOSs have been developed in the last decades their use in modeling industrial processes is rather limited. In this work, we use the crossover Soave–Redlich–Kwong (CSRK) to describe phase equilibrium and critical properties of pure n-alkanes and methane/n-alkane binary mixtures and compare the results to two other modeling approaches of the SRK EOS. In the case of the pure fluids, CSRK gives an accurate overall description of the phase equilibrium and critical properties; nevertheless, a minor increase in the deviation of the saturation pressure and other properties is observed when compared to that of the mean-field model. For the binary mixtures, an improvement in the description of the critical volumes is seen, while, for the other properties, similar results are obtained.

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Section: ■ Introductionmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Application of a Crossover Equation of State to Describe Phase Equilibrium and Critical Properties of n-Alkanes and Methane/n-Alkane Mixtures

2017

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“…For instance, the mechanism of extraction of hydrocarbons by CO 2 is generally neglected for heavy oil reservoirs because it is perceived as a slow process. 7,13 These mechanisms include oil viscosity reduction, 6,14 oil swelling, 15 IFT reduction, 12 extraction of hydrocarbons, 16,17 and asphaltene precipitation. 18 In many of the CO 2 EOR studies or field trials in the literature, CO 2 has been a relatively dense fluid, mainly a supercritical fluid and in a handful of cases a liquid fluid.…”

Section: ■ Introductionmentioning

confidence: 99%

“…7,13 Accordingly, it is crucial to investigate the performance of oil recovery by lowdensity CO 2 injection. To accomplish this task, the same core and fluids (e.g., oil, brine, CO 2 ) used in our previous experiments 7,13 were used in the experiments reported in this work to be able to compare the behavior of oil recovery at different conditions.…”

Section: ■ Introductionmentioning

confidence: 99%

Investigation of Low-Density CO₂ Injection for Enhanced Oil Recovery

Seyyedsar

Farzaneh

Sohrabi

2017

Ind. Eng. Chem. Res.

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The density of the CO2-rich phase in a reservoir would play a crucial role in the performance of an enahcned oil recovery (EOR) scheme. Many oil reservoirs are located in deep formations; hence, they have high temperatures. Moreover, the pressure of reservoirs decreases because of natural depletion. Under the conditions of those reservoirs, CO2 would be a low-density gas. A series of coreflood experiments were performed to evaluate the potential of low-density CO2 EOR. The experiments are intermittent CO2 injection, continuous tertiary and secondary CO2 injection, and water alternating CO2 injection followed by the coinjection of a surfactant and CO2. The same oil and gas were mixed to prepare live oil for all the experiments. The initial rate of oil recovery during secondary waterflood was high, but the efficiency of the process decreased after the breakthrough. Three pore volumes (PVs) of secondary CO2 injection resulted in the recovery of around 50% of the initial oil in place, which was 27% higher than the oil recovered during 1 PV of water injection. It was also observed that CO2 injection can improve the recovery factor after waterflood. However, the performance of tertiary CO2 injection is reduced because of the presence of water in pore spaces, which likely makes the oil less accessible to CO2. Waterflood after a period of CO2 injection recovered 20% of initial oil in place mainly because of the dissolution of CO2 in the oil and the resultant oil viscosity reduction. The impact of the rate of CO2 injection on the efficiency of oil recovery was investigated, and it appears that the dissolution of CO2 in the oil is the main mechanism of enhanced recovery. The reduction of oil viscosity as a result of the dissolution of CO2 in the oil as well as the low density of CO2 improved the effect of gravity drainage on oil production. In addition, it was observed that the mechanism of solution gas drive plays an important role in the process of oil recovery. The analysis of the physical properties of the core effluent reveals that CO2 can also improve the quality of produced oil compared to that of the original oil in the rock. The results of this study provide experimental evidence of the potential of low-density CO2 EOR.

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