Experimental Investigation of Polymer Assisted WAG for Mobility Control in the Highly Heterogeneous North Burbank Unit in Oklahoma, Using Anthropogenic CO2

Tovar, Francisco D.; Barrufet, María A.; Schechter, David S.

doi:10.2118/177174-ms

Cited by 10 publications

(3 citation statements)

References 23 publications

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“…The 13 coreflood experiments in light oil (viscosity = 3.21 cP) were conducted to compare the performance of PAG-CO 2 with other methods. 7 For homogeneous cores, PAG did not show improvement in oil recovery from WAG under immiscible conditions and even worsened oil recovery under miscible conditions as polymer shielded more residual oil. For heterogeneous cores, PAG yielded similar results as WAG because the better mobility control by polymer possibly reduced the fingering dispersion.…”

Section: Introductionmentioning

confidence: 89%

“…The superior performance of PGAW over WAG suggested that more favorable mobility control improved macroscopic displacement efficiency. The 13 coreflood experiments in light oil (viscosity = 3.21 cP) were conducted to compare the performance of PAG-CO 2 with other methods . For homogeneous cores, PAG did not show improvement in oil recovery from WAG under immiscible conditions and even worsened oil recovery under miscible conditions as polymer shielded more residual oil.…”

Section: Introductionmentioning

confidence: 99%

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Direct Investigation of Oil Recovery Mechanism by Polymer-Alternating-Gas CO₂ through Micromodel Experiments

Laochamroonvorapongse,

Beunat,

Pannacci

et al. 2023

Energy Fuels

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CO2 gas is one of the most effective injectants for enhanced oil recovery (EOR). New injection technique like polymer-alternating-gas (PAG) is aimed at further improving oil recovery efficiency from conventional gas injection; however, the oil recovery mechanism and fluid interactions underlying PAG have not yet been studied at a microscopic level. This study conducts the first micromodel study to better understand the relevant mechanisms and interactions of PAG at high pressure and temperature. Traditional methods, including water, polymer, CO2, and water-alternating-gas (WAG), are also investigated and compared with PAG. The experiments use a rock-shaped micromodel glass and decane to represent reservoir oil. An oil miscibility test is performed by injecting CO2 into a micromodel prefilled with decane at a temperature of 40 °C and pressure varying within 70–90 bar. Oil miscibility, as determined by the disappearance of an oil-CO2 interface, is achieved at a pressure of 90 bar. When comparing the WAG and PAG methods, the PAG method is more effective in producing additional oil recovery of up to 6%. This is due to the polymer’s better displacement efficiency, stronger gas flow diversion effects, and slightly higher miscibility level. The observed oil recovery mechanisms are oil displacement, miscibility, flow diversion, oil swelling, and CO2 dissolution and diffusion. This study proposes a simple miscibility test, proves the effectiveness of the PAG method, and demonstrates various phenomena related to oil recovery processes. Integrating those effects and new injection strategies in the simulation study will benefit the CO2-EOR field design.

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Section: Introductionmentioning

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Direct Investigation of Oil Recovery Mechanism by Polymer-Alternating-Gas CO₂ through Micromodel Experiments

Laochamroonvorapongse,

Beunat,

Pannacci

et al. 2023

Energy Fuels

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“…Few coreflood experiments on sandstone cores have been conducted to demonstrate the efficacy of PAG injection, but these experiments either used model crude oil or lacked comprehensive discussion on the displacement mode of crude oil by CO 2 during PAG injection. , A micromodel study was conducted to explain the recovery mechanism of miscible PAG for 0.5 cP oil using SAV55 polymer . Furthermore, Tovar et al studied the effect of heterogeneity on miscible or immiscible displacement of oil by PAG injection in sandstone core, and their findings indicated that a certain level of heterogeneity is necessary for PAG injection to yield beneficial results. It has been observed that most of the studies focused on analyzing individual parameters to explain the additional recovery achieved through PAG injection, without fully integrating the mechanisms or optimizing various parameters such as MMP, IFT reduction, viscosity reduction, CO 2 solubility and crude oil swelling factor, and injection rate of fluids.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Oil Recovery Using Polymer Alternating CO₂ Gas Injection: Mechanisms, Efficiency, and Environmental Benefits

Prakash,

Joshi,

Ojha

et al. 2024

Energy Fuels

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In light of the depletion of conventional oil reserves and rising global warming, the CO 2 -EOR has garnered global attention among stakeholders for its potential to evolve into a net carbon-negative technique for extracting residual oil. CO 2 -EOR is a method of extracting additional crude oil beyond primary and secondary recovery from the reservoir using CO 2 as an injection fluid. Among CO 2 -EOR methods, water alternating gas (WAG) injections have been adopted in over 90% of CO 2 -EOR projects worldwide due to improved mobility control and better volumetric sweep efficiency as compared to conventional gas and water injections. However, the sweep efficiency can be further improved by substituting water with the polymer, owing to its greater viscosity. This paper aims to study the mechanisms involved in the miscible and immiscible displacement of medium crude oil by polymer alternating gas (PAG) injection. The miscibility of crude oil with CO 2 was determined using slim tube experiment. The oil displacement mechanism by CO 2 injection was studied by using interfacial tension (IFT) measurements and the rheology of crude oil under different CO 2 equilibrium pressure conditions. Observations revealed that as the CO 2 equilibrium pressure increased, there was a reduction in the IFT between the crude oil and the CO 2 system, attributed to the exchange of CO 2 and intermediate hydrocarbons (HCs) across the interface. The rheological studies of crude oil indicated a decreasing trend in oil viscosity with increasing CO 2 pressure, thereby improving the oil mobility. The solubility of CO 2 in oil and the swelling factor were quantified for different CO 2 saturation pressures using pressure decay data and the density of the CO 2 -saturated crude oil. The rheological and injectivity studies of the polymer were conducted using hydrodynamic dimension analysis, resistance factor, and residual resistance factor to assess the flowability of the polymer within the core. In the case of immiscible PAG, an additional 26% of OOIP was recovered following waterflooding, while 42% of the oil was recovered under the miscible mode. Furthermore, the CO 2 net utilization factor was greater for PAG in the miscible mode compared to that in the immiscible mode. In summary, PAG has huge potential to extract medium oil from low-permeable carbonates, and its efficiency is highly dependent on the mode of CO 2 injection, polymer hydrodynamic dimensions, and mobility control offered by the polymer.

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A comprehensive review of minimum miscibility pressure determination and reduction strategies between CO2 and crude oil in CCUS processes

Chen,

Zhang

2025

Fuel

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Experimental Investigation of Polymer Assisted WAG for Mobility Control in the Highly Heterogeneous North Burbank Unit in Oklahoma, Using Anthropogenic CO2

Cited by 10 publications

References 23 publications

Direct Investigation of Oil Recovery Mechanism by Polymer-Alternating-Gas CO₂ through Micromodel Experiments

Direct Investigation of Oil Recovery Mechanism by Polymer-Alternating-Gas CO₂ through Micromodel Experiments

Enhanced Oil Recovery Using Polymer Alternating CO₂ Gas Injection: Mechanisms, Efficiency, and Environmental Benefits

A comprehensive review of minimum miscibility pressure determination and reduction strategies between CO2 and crude oil in CCUS processes

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Experimental Investigation of Polymer Assisted WAG for Mobility Control in the Highly Heterogeneous North Burbank Unit in Oklahoma, Using Anthropogenic CO2

Cited by 10 publications

References 23 publications

Direct Investigation of Oil Recovery Mechanism by Polymer-Alternating-Gas CO2 through Micromodel Experiments

Direct Investigation of Oil Recovery Mechanism by Polymer-Alternating-Gas CO2 through Micromodel Experiments

Enhanced Oil Recovery Using Polymer Alternating CO2 Gas Injection: Mechanisms, Efficiency, and Environmental Benefits

A comprehensive review of minimum miscibility pressure determination and reduction strategies between CO2 and crude oil in CCUS processes

Contact Info

Product

Resources

About

Direct Investigation of Oil Recovery Mechanism by Polymer-Alternating-Gas CO₂ through Micromodel Experiments

Direct Investigation of Oil Recovery Mechanism by Polymer-Alternating-Gas CO₂ through Micromodel Experiments

Enhanced Oil Recovery Using Polymer Alternating CO₂ Gas Injection: Mechanisms, Efficiency, and Environmental Benefits