Comparative Study of CO<sub>2</sub>and N<sub>2</sub>Foams in Porous Media at Low and High Pressure−Temperatures

Farajzadeh, R.; Andrianov, Alexey; Bruining, Hans; Zitha, Pacelli L.J.

doi:10.1021/ie801760u

Cited by 209 publications

(166 citation statements)

References 55 publications

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“…Core flood studies have been carried out using many different types of cores (Kristiansen and Holt, 1992;Mannhardt et al 2000;Kovscek and Bertin, 2003;Zitha et al 2006;Nguyen et al, 2009;Farajzadeh et al, 2009Farajzadeh et al, , 2010, sand packs (Khatib et al 1988;Osterloh and Jante, 1992;Apaydin and Kovscek, 2001;Ma et al 2013) and bead packs (Khatib et al 1988;Falls et al 1989;Aronson et al 1994). These tests have been very useful in providing information on a wide range of aspects of foam behavior, from the effect of surfactant type and concentration, to the interaction of the foam with oil, to foam flow properties such as apparent viscosity and mobility control.…”

Section: Introductionmentioning

confidence: 99%

“…The information from these core flood tests can also be fed back into the foam models (Ma et al, 2013;Boeije and Rossen, 2013;Ma et al 2014). The cores used in these tests typically, but not always (Moradi-Araghi et al, 1997;Nguyen et al, 2009;Farajzadeh et al, 2009), have diameters of at least 3.5 cm, with lengths of 30 cm and above, and these larger pore volume systems have the advantage that any small heterogeneities in the rock have no significant effect on the foam behavior.…”

Section: Introductionmentioning

confidence: 99%

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Small Core Flood Experiments for Foam EOR - Screening Surfactant Applications

Jones¹,

Bent²,

Farajzadeh³

et al. 2015

Proceedings

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Aqueous foams are a means of increasing the sweep efficiency of enhanced oil recovery processes. An understanding of how a foam behaves in the presence of oil is therefore of great importance when selecting suitable surfactants for EOR processes. The consensus is currently that the most reliable method for determining the foam behavior in the presence of oil is to inject foam through a rock core. Coreflood tests, however, are typically carried out using large rock cores (e.g. diameter = 4 cm, length = 40 cm or longer), and hence foam flow tests can take days or weeks to achieve steady-state flow.In this study, we present the preliminary results for a core-flood system where the rock core is pen-sized (diameter = 1 cm, length = 17 cm). These small cores allow for short-duration foam flow tests, where steady-state flow is achieved in a few hours. Using this system, the foam quality/effective viscosity response curves can be plotted, both with and without oil in the system. These small size cores then enable rapid screening of surfactants and foam properties in different rocks and with different oils. Benefits and limitations of these small coreflood experiments are discussed.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Small Core Flood Experiments for Foam EOR - Screening Surfactant Applications

Jones¹,

Bent²,

Farajzadeh³

et al. 2015

Proceedings

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“…A number of laboratory studies find that CO 2 foams have greater mobility that N 2 foams -in the jargon of foam EOR, the CO 2 foams are "weaker" (Kuhlman, 1990;Chou, 1991;Kibodeaux, 1997;Farajzadeh et al, 2009) A direct, conclusive comparison is difficult, because a surfactant optimized for one gas may not be optimal for another. If CO 2 foams are inherently weaker, then this could mean that the bubbles are larger, though part of the difference could reflect smaller surface tension of CO 2 against surfactant solution (Rossen, 1996;Chaubert et al, 2012), and the consequent reduced capillary resistance to flow.…”

Section: Introductionmentioning

confidence: 99%

“…There are numerous differences between CO 2 and N 2 foams: greater solubility of CO 2 in surfactant solution; faster diffusion of CO 2 through lamellae (Farajzadeh et al, 2009); lower pH with CO 2 foam; lower surface tension of supercritical CO 2 against the lamella (Rossen, 1996;Chaubert et al, 2012); different ionic strength because of dissolved HCO 3 in the aqueous phase of CO 2 foam; greater density and viscosity of the nonaqueous phase with supercritical CO 2 ; different stability because of different Hamaker constant across the lamella (Kibodeaux, 1997), etc. In particular, the faster diffusion of CO 2 through lamellae is cited as a possible cause of this difference between CO 2 and N 2 foam (Farajzadeh et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

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A 2D Model for the Effect of Gas Diffusion on Mobility of Foam for EOR

Nonnekes¹,

Cox²,

Rossen³

2012

ECMOR XIII - 13th European Conference on the Mathematics of Oil Recovery

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SUMMARYTransport of gas across liquid films between bubbles is cited as one reason why CO2 foams for enhanced oil recovery (EOR) are usually weaker than N2 foams and why steam foams are weaker than foams of steam mixed with N2.We examine here the effect of inter-bubble gas diffusion on flowing bubbles in a simplified model of a porous medium (a periodically constricted tube in 2D) and in particular its effect on the bubble-size distribution and capillary resistance to flow. Bubbles somewhat smaller than a pore disappear by diffusion as the bubbles move. For bubbles larger than a pore, as expected in EOR, diffusion does not affect bubble size. Instead, diffusion actually increases capillary resistance to flow (i.e. makes foam stronger): lamellae spend more time in positions where lamella curvature resists movement. When fit to pressures and diffusion and convection rates representative of field application of foams, diffusion is not expected to alter the bubble-size distribution in a foam, but instead modestly increases the resistance to flow. The reason for the apparent weakness of CO2 foam therefore evidently lies in factors other than CO2's large diffusion rate through foam.

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Application of foam floods for enhancing heavy oil recovery through stability analysis and core flood experiments

2014

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This work concerns the investigation of foam application to enhance heavy oil recovery through stability analysis tests, core floods, and data assessment. Monitoring transient behaviour of foam heights in a glass column showed that salt/alkaline concentration/type significantly affects the stability of foam. Meanwhile, the ionic nature of the surfactant and gas type also plays a crucial role. Therefore, the foam stability analysis should be helpful for the successful design of foam floods in enhanced oil recovery (EOR) processes. The surfactants that gave the most stable foam were used in core floods, and found that an increase in surfactant alternating gas (SAG) ratio decreases the oil recovery; furthermore, the efficiency of Cetrimonium Bromide (CTAB) is lower than that of Sodium Dodecyl Sulfate (SDS) in a sandstone core. Finally, the Leverage approach was used to assess the obtained data points of stability as well as core flooding tests through the developed least square supported vector machine (LS-SVM) models. It confirms the validity of experimental data.

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Comparative Study of CO₂and N₂Foams in Porous Media at Low and High Pressure−Temperatures

Cited by 209 publications

References 55 publications

Small Core Flood Experiments for Foam EOR - Screening Surfactant Applications

Small Core Flood Experiments for Foam EOR - Screening Surfactant Applications

A 2D Model for the Effect of Gas Diffusion on Mobility of Foam for EOR

Application of foam floods for enhancing heavy oil recovery through stability analysis and core flood experiments

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Comparative Study of CO2and N2Foams in Porous Media at Low and High Pressure−Temperatures

Cited by 209 publications

References 55 publications

Small Core Flood Experiments for Foam EOR - Screening Surfactant Applications

Small Core Flood Experiments for Foam EOR - Screening Surfactant Applications

A 2D Model for the Effect of Gas Diffusion on Mobility of Foam for EOR

Application of foam floods for enhancing heavy oil recovery through stability analysis and core flood experiments

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Product

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Comparative Study of CO₂and N₂Foams in Porous Media at Low and High Pressure−Temperatures