An Investigation of Mechanistic Foam Modeling for Optimum Field Development of CO2 Foam EOR Application

Izadi, Mohammad; Nguyen, Phuc H.; Fleifel, Hazem; Maestre, Doris Ortiz; Kam, Seung Ihl

doi:10.2118/205494-pa

Cited by 6 publications

(4 citation statements)

References 25 publications

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“…27 In addition, the polymer can compete with the surfactant at the interface for adsorption, reducing the surfactant adsorption loss and, thereby, enhancing the stability of the foam in the porous media. 28 According to the classification of gas types, foam can generally be divided into air foam, 29,30 CO 2 foam, 31,32 N 2 foam, 33,34 natural gas foam, 35,36 and the like. Nitrogen is chosen as the gas source for the foam system herein because it is an inert gas, non-toxic, and difficult to burn and has the advantages of an abundant source, high compression coefficient, and significant expansion.…”

Section: Introductionmentioning

confidence: 99%

“…According to the classification of gas types, foam can generally be divided into air foam, , CO 2 foam, , N 2 foam, , natural gas foam, , and the like. Nitrogen is chosen as the gas source for the foam system herein because it is an inert gas, non-toxic, and difficult to burn and has the advantages of an abundant source, high compression coefficient, and significant expansion.…”

Section: Introductionmentioning

confidence: 99%

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Experimental Investigation of a Polymer-Enhanced N₂ Foam Performance for Enhanced Oil Recovery

et al. 2023

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The Bohai oilfield is a typical common heavy oil reservoir with high water cut after long-term water injection development. Considering the characteristics of selective plugging, polymer-enhanced foam (AOS–DYG) flooding was adopted in this study as a subsequent enhanced oil recovery (EOR) technology in the Bohai Sea. A polymer can promote foam stability by reducing the foam drainage rate and enhancing interfacial adsorption behavior. As a result of its low cost and abundant sources, nitrogen is selected as the air source of foam in this paper. The interaction between the polymer DYG and the surfactant AOS was clarified from the aspects of surface adsorption properties, surface dilated rheological properties, bulk phase rheological properties, and micromorphology. That is, the addition of polymer can increase the thickening ability of the foam-based liquid phase, the thickness of the liquid film, and the strength of the gas–liquid interface adsorption layer, all of which dramatically improve the stability of the foam. The core displacement test results further confirmed that the AOS–DYG foam displaced an excellent mobility control ability in porous media. When the foam mass (gas–liquid ratio) was 70% and the injection flow rate was 1 mL/min, the resistance factor and residual resistance factor at 2264.7 mD reached 246.11 and 127.33, respectively. With an increased core permeability, the oil displacement performance of the AOS–DYG foam increased. The enhanced oil recovery (EOR) of the 0.4 PV AOS–DYG foam in the 2547.8 mD core reached 32.19%, demonstrating an outstanding oil displacement capacity. The findings of the investigation supported the potential application of the AOS–DYG foam in EOR.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Experimental Investigation of a Polymer-Enhanced N₂ Foam Performance for Enhanced Oil Recovery

et al. 2023

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“…NPs are an effective additive for foam stability. As a result of the increased diffusivity and greater interface of NPs, researchers discovered that foam made with NPs shows high stability. , Foam usually consists of both liquid and gas. The gas may be air, CO 2 , nitrogen gas, or any other gas suited for the creation of foam.…”

Section: Compositions Of Foam and Their Influences On Foamingmentioning

confidence: 99%

Perspectives of Foam Generation Techniques and Future Directions of Nanoparticle-Stabilized CO₂ Foam for Enhanced Oil Recovery

2023

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Global demand for energy is increasing day by day rapidly as a result of the population, industrial, and economic growth of developing countries, especially in emerging market economies. Hence, to meet this growing and continuing global crude oil demand, innovative enhanced oil recovery (EOR) techniques are required to emerge, and currently, implemented techniques need to be revisited and optimized to recover more residual oil trapped in the reservoirs. Among different chemicals, foam has good mobility control in the oil recovery method. Nowadays, the study on the stability of foam is an utmost interest for petroleum engineers to find a way to obtain stable foam for application in EOR. In this review, the basics of foam and its preparations, properties, application, and some special applications mainly in the oil industry have been depicted to convey an idea of the degree of foam research in EOR. Basically, this review will provide a detailed discussion on the applications of foam in oil recovery and some short ideas that can be applied in the near future for nanoparticle (NP)-assisted stable CO2 foam flooding in EOR. Increasing the NP concentration initially improved foam stability because a higher number of NPs participated in strengthening the gas bubble and initially increased oil recovery as a result of the formation of more stable foam. The polymer-coated, nanoclay–surfactant-stabilized foam and surface-modified silica nanoparticles have exceptional foaming ability and foam stability at high temperatures, making them suitable for the production from heavy oil reservoirs. Some other nanoparticles, like Al2O3, ZrO2, TiO2, Fe2O3, and NiO, have also been used for enhancing foam stability by preventing liquid drainage from lamella. Also, NP-stabilized CO2 foam flooding can enhance oil recovery by 10–15% after secondary recovery by creating a more homogeneous gas front for better mobility control.

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“…The gas saturation should be much higher there because the presence of foam in that zone can increase the trapped gas saturation. Therefore, we assume that 70% of gas is trapped in the transition zone [34].…”

Section: Sweep Efficiency With Two Injection Strategiesmentioning

confidence: 99%

Mitigation of Gravity Segregation by Foam to Enhance Sweep Efficiency

Wang¹,

Su²,

Huang

et al. 2023

Applied Sciences

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Foam-assisted gas injection exhibits promising potential for enhancing sweep efficiency through the amelioration of gravity segregation, particularly within reservoirs characterized by heterogeneity. In this work, the implicit-texture (IT) model featuring two flow regimes is employed to examine the impact of heterogeneity on gravity segregation. The validation of the numerical results for water–gas coinjection and pre-generated foam injection is accomplished through a comparative analysis with analytical solutions. A hypothetical two-layer model with varying permeabilities and thickness ratios is used to examine the impact of foam on gravity segregation. The numerical findings demonstrate satisfactory conformity with analytical solutions in homogeneous reservoirs. A high-permeability top layer in a layered model with a fixed injection rate results in sweep efficiency similar to that of a homogeneous reservoir with each individual permeability. A low-permeability top layer could increase the sweep efficiency, but with severe permeability contrast, the bottom high-permeability layer could impact the displacement process, even with a thin thickness. The sweep efficiency increases with the thickness of the high-permeability top layer and decreases with a thicker low-permeability top layer under fixed injection pressure. The predicted segregation length through a single-layer approximation cannot match the results of the layered models where the permeability contrast is too great or the thickness of two layers is comparable.

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An Investigation of Mechanistic Foam Modeling for Optimum Field Development of CO2 Foam EOR Application

Cited by 6 publications

References 25 publications

Experimental Investigation of a Polymer-Enhanced N₂ Foam Performance for Enhanced Oil Recovery

Experimental Investigation of a Polymer-Enhanced N₂ Foam Performance for Enhanced Oil Recovery

Perspectives of Foam Generation Techniques and Future Directions of Nanoparticle-Stabilized CO₂ Foam for Enhanced Oil Recovery

Mitigation of Gravity Segregation by Foam to Enhance Sweep Efficiency

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An Investigation of Mechanistic Foam Modeling for Optimum Field Development of CO2 Foam EOR Application

Cited by 6 publications

References 25 publications

Experimental Investigation of a Polymer-Enhanced N2 Foam Performance for Enhanced Oil Recovery

Experimental Investigation of a Polymer-Enhanced N2 Foam Performance for Enhanced Oil Recovery

Perspectives of Foam Generation Techniques and Future Directions of Nanoparticle-Stabilized CO2 Foam for Enhanced Oil Recovery

Mitigation of Gravity Segregation by Foam to Enhance Sweep Efficiency

Contact Info

Product

Resources

About

Experimental Investigation of a Polymer-Enhanced N₂ Foam Performance for Enhanced Oil Recovery

Experimental Investigation of a Polymer-Enhanced N₂ Foam Performance for Enhanced Oil Recovery

Perspectives of Foam Generation Techniques and Future Directions of Nanoparticle-Stabilized CO₂ Foam for Enhanced Oil Recovery