Direct Investigation of Oil Recovery Mechanism by Polymer-Alternating-Gas CO<sub>2</sub> through Micromodel Experiments

Laochamroonvorapongse, Rapheephan; Beunat, Virginie; Pannacci, Nicolas; Douarche, Frederic; Chewaroungroaj, Jirawat; Srisuriyachai, Falan

doi:10.1021/acs.energyfuels.3c02855

Cited by 5 publications

(3 citation statements)

References 32 publications

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“…An early attempt to mimic the realistic PAG flooding scenario involved sand-pack flooding, highlighting the effectiveness of immiscible PAG injection in extracting heavy oil where PAG injection in the tertiary mode yielded 19% oil recovery . 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.…”

Section: Introductionmentioning

confidence: 99%

“…33,34 A micromodel study was conducted to explain the recovery mechanism of miscible PAG for 0.5 cP oil using SAV55 polymer. 35 Furthermore, Tovar et al 36 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%

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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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Section: Introductionmentioning

confidence: 99%

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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show abstract

“…The implementation of CO 2 – EOR can be done under several schemes, including the injection of miscible/immiscible CO 2 , water alternating CO 2 gas injection (WAG CO 2 ), polymer alternating gas CO 2 (PAG), simultaneous water CO 2 gas injection, foam assisted CO 2 , low salinity water–surfactant–CO 2 , and hybrid schemes with surfactant polymer (SP). − Most CO 2 – EOR processes are commonly confronted to satisfy two objectives consisting of maximizing ORF and minimizing the production of CO 2 (this latter means the increase in the storage performance). − However, it is worth mentioning that many published studies and experimental tests demonstrated the superiority of the miscible type (single–phase flow) of CO 2 – EOR processes in reaching higher ORF compared to the immiscible type (two–phase flow). , The suitable design of a CO 2 – EOR process depends greatly on the so-called minimum miscibility pressure (MMP) since this parameter allows the determination of the injection type, i.e., miscible or immiscible. MMP represents the cutoff pressure at reservoir temperature (T R ) above which miscibility between the reservoir fluid and the injected gas occurs after multiple contacts. − …”

Section: Introductionmentioning

confidence: 99%

Utilizing Artificial Intelligence Techniques for Modeling Minimum Miscibility Pressure in Carbon Capture and Utilization Processes: A Comprehensive Review and Applications

Amar,

Djema,

Ourabah

et al. 2024

Energy Fuels

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The carbon dioxide (CO 2 ) based enhanced oil recovery methods (EORs) are considered among the promising techniques for increasing the recovery factor from mature oil reservoirs and reducing the amount of CO 2 emission in the atmosphere. Determining the minimum miscibility pressure (MMP) of CO 2 − oil systems is a crucial step for successfully implementing CO 2 − EOR processes. Therefore, various approaches have been proposed for determining this key parameter. However, the laboratory tests are expensive and timeconsuming, while most available correlations present moderate accuracy. To address these shortcomings, various studies have applied artificial intelligence (AI) techniques to model the MMP of the CO 2 − oil systems. In this study, we reviewed the published works for predicting the MMP of the CO 2 − oil systems using AI-based models. Our analyses revealed the robustness of these techniques in modeling MMP. In this context, it was noticed that more than 70 AI-based paradigms have been utilized for estimating the MMP of CO 2 − oil systems. Among the applications, the hybrid schemes combining machine learning and nature-inspired algorithms (ML-NIA) take the top spot, accounting for 27% of applications. Additionally, the investigation demonstrated that the artificial neural network (ANN) is the most utilized ML method in the modeling phase, while the genetic algorithm (GA) is the most widely applied NIA for improving ML performance. In the second part of this study, we suggest an updated correlation based on gene expression programming (GEP) for the accurate prediction of MMP of CO 2 − oil systems. Our proposed explicit correlation yielded excellent predictive performance, achieving overall root-mean-square error and determination coefficient (R 2 ) values of 0.9253 and 09713, respectively. These promising statistical metrics enabled the newly updated GEP-based correlation to outperform the preexisting models. Besides, the physical validity and interpretability of the proposed correlation were proven using the trend analysis and the Shape Dependence Analysis plot, respectively. Lastly, the findings of this study provide a dual benefit, the review and the illustration of the published studies on applying AI techniques for modeling the MMP of the CO 2 − oil systems; and second, the newly implemented GEP-based correlation can significantly enhance the effective prediction of the MMP in CO 2 -oil systems, thus, facilitating the simulation of various CO 2 − based EOR processes.

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Surfactant–Polymer Viscosity Effects on Enhanced Oil Recovery Across Pore Structures: Microfluidic Insights from Pore Scale to Darcy Scale

Gao,

Tang,

et al. 2024

Energy Fuels

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

Cited by 5 publications

References 32 publications

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

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

Utilizing Artificial Intelligence Techniques for Modeling Minimum Miscibility Pressure in Carbon Capture and Utilization Processes: A Comprehensive Review and Applications

Surfactant–Polymer Viscosity Effects on Enhanced Oil Recovery Across Pore Structures: Microfluidic Insights from Pore Scale to Darcy Scale

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

Cited by 5 publications

References 32 publications

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

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

Utilizing Artificial Intelligence Techniques for Modeling Minimum Miscibility Pressure in Carbon Capture and Utilization Processes: A Comprehensive Review and Applications

Surfactant–Polymer Viscosity Effects on Enhanced Oil Recovery Across Pore Structures: Microfluidic Insights from Pore Scale to Darcy Scale

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Product

Resources

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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

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