Foam Propagation in Snorre Reservoir Core - Effects of Oil Saturation and Ageing

Mannhardt, K.; Svorstøl, Idar

doi:10.3997/2214-4609.201406794

Cited by 8 publications

(4 citation statements)

References 8 publications

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“…It is reasonable to believe that foam generates and propagates, according to the established tracer profile in dispersion measurement, which represents areas of lower flow resistance, as this coincided with the start of the foam plateau level in most experiments. Compared to experiments in homogeneous sandstone cores, it is often observed that the foam propagation follows the injection rate. , Thus, it seems like foam propagation in oil-free carbonates is faster than in sandstones, which could be reflecting the heterogeneous nature or the complexity of the pore structure of carbonates.…”

Section: Discussionmentioning

confidence: 89%

“…Compared to experiments in homogeneous sandstone cores, it is often observed that the foam propagation follows the injection rate. 26,27 Thus, it seems like foam propagation in oil-free carbonates is faster than in sandstones, which could be reflecting the heterogeneous nature 33 or the complexity of the pore structure of carbonates.…”

Section: Discussionmentioning

confidence: 99%

“…The focus of foam research in carbonates has been on studies of foams in fractures (see the study by Dong et al). In general, when generating foam, the presence of remaining oil saturation (ROS) reduces the efficiency of foams. − In carbonate core material, aging of the core with crude oil may result in a more oil-wet state. Foam generation combined with wettability alteration in oil-wet low-permeability carbonates has been discussed by Ghosh and Mohanty .…”

Section: Introductionmentioning

confidence: 99%

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Foam Dynamics in Limestone Carbonate Cores

et al. 2020

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There is an increasing interest in foam applications in heterogeneous carbonate reservoirs to improve gas sweep and mitigate a high gas–oil ratio (GOR) in production wells. However, foam has been studied in sandstones more than in carbonates, and there are few experimental investigations considering matrix transport properties of foam in carbonates. Thus, this study takes a fundamental approach to improve our understanding of foam generation and transport process in the absence and presence of remaining oil in carbonates by co-injection of Alpha Olefin Sulfonate (AOS) solution and nitrogen (N2) in outcrop Indiana Limestone at high pressure and temperature after satisfying adsorption. In the oil-free core, development of the foam generation transient period and its transition into steady-state foam was rapid for all gas fractions, where the strongest foam was obtained at 90% gas fraction. Foam properties were successfully reproduced at different gas fractions. At remaining oil saturation, foam generation and propagation were significantly delayed and were observed at a high AOS surfactant concentration (5 wt %). Persistent foams were obtained both with and without remaining oil present, which withstood pressure gradients of N2 up to 0.5 bar/m for extended times. Therefore, if correctly designed, foam gas shut-off can be a low-cost low-risk technique to reduce problems with high GOR, gas-handling, and gas reinjections.

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Section: Discussionmentioning

confidence: 89%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Foam Dynamics in Limestone Carbonate Cores

et al. 2020

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“…The wettability may, in addition to the residual oil saturation, reduce foam propagation rate as foam nucleation sites may be unavailable for foam generation. Mannhardt and Svorstøl (1997) studied foam generation and foam propagation at Snorre reservoir conditions and reported a strong dependence of foam propagation on oil saturation. Higher oil saturation reduced foam propagation and foam propagation in the absence of oil followed the injection rate.…”

Section: Co 2 -Foamsmentioning

confidence: 99%

Foam Generation, Propagation and Stability in Porous Medium

et al. 2019

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There have been several foam field applications in recent years. Foam treatments targeting gas mobility control in injectors as well as gas blocking in production wells have been performed without causing operational problems. The most widely used injection strategy of foam has been injecting alternating slugs of surfactant in brine with gas injection. This procedure seems to be beneficial as injection is easy to perform and control below fracturing pressure. Simultaneous injection of surfactant solution and gas may give difficulties, especially with interpretation of the tests, if fracturing pressure are exceeded during the injection period. This paper reviews critical aspects of foam for reservoir applications and intends to motivate for further field trials. Key parameters for qualification of foam are: foam generation, propagation in porous medium, foam strength and stability of foam. Stability is discussed, especially in the presence of oil at reservoir conditions. Data on each of these topics are included, as well as extracted summary of relevant literature. Experimental studies have shown that foam is generated at low surfactant concentration even below the CMC (critical micelle concentration). Results indicate that in situ foam generation in porous medium may depend on available nucleation sites. In situ generation of foam is complex and has been found to be especially difficult in oil wet carbonate rocks. Foam propagation in porous medium has been summarized, and propagation rate for a given experiment seems to be constant with time and distance. Laboratory studies confirm a propagation rate of 1-3 m/day. Field tests performed have not given reliable information of foam propagation rate, and future field pilots are encouraged to include observation wells in order to gain information of field-scale foam propagation. Foam strength is generally high with all gases. The exception is CO 2 at high pressure where CO 2 becomes supercritical. Stability of foam has been studied in laboratory and field tests, and has confirmed long-term stability of foam.

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Study of blended surfactants to generate stable foam in presence of crude oil for gas mobility control

Memon

Shuker

Elraies

2016

J Petrol Explor Prod Technol

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For controlling the viscous fingering in wateralternating gas injection, addition of foam with formation water is more favorable. Use of foam surfactant is one potential solution for reducing gas mobility. The main objective of this research is to generate stable foam for gas mobility control using surfactant blend formulation. Surfactant blends synergistically exhibit better foaming properties than those of individual surfactants. Surfactant blends improve the foam stability and reduces the destabilizing effect of crude oil. Using foam stabilizers may improve foam stability and apparent viscosity; both of these factors are important for improving gas mobility. Alpha olefin Sulfonate (AOS C14-16 ) was selected as main surfactant, Octylphenol Ethylene Oxide (TX-100) and Lauryl Amido Propyl Amine oxide (LMDO) were selected as additives. Aqueous stability test was performed at 96°C. Foam stability test was performed in the absence and presence of crude oil. The foam stability and longevity was recorded above the liquid level. Liquid drainage and Foam half-life were noted with respect to time. The mobility reduction factor of three formulations was performed with CO 2 by using Berea sandstone cores at 96°C and 1400 psi. Experimental result showed that surfactant blend of 0.6 % AOS ? 0.6 % LMDO was more stable in presence of crude oil and reduced more gas mobility as compared to an individual surfactant of 0.6 % AOS. The maximum generated foam volume and foam half time indicated better performance of the foaming agent. The surfactant blend formulation plays an important role in controlling gas mobility. Strong stability by these formulations indicates that the foam surfactant formulation is of great significance in the field of enhanced oil recovery.

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Foam Propagation in Snorre Reservoir Core - Effects of Oil Saturation and Ageing

Cited by 8 publications

References 8 publications

Foam Dynamics in Limestone Carbonate Cores

Foam Dynamics in Limestone Carbonate Cores

Foam Generation, Propagation and Stability in Porous Medium

Study of blended surfactants to generate stable foam in presence of crude oil for gas mobility control

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