Single Well Alkaline-Surfactant Injectivity Improvement Test in the Big Sinking Field

Miller, Bernie J.; Pitts, Malcolm; Dowling, Phillip; Wilson, Dan

doi:10.2118/89384-ms

Cited by 11 publications

(2 citation statements)

References 6 publications

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“…It's characteristics have been described elsewhere. 1 Polymers used in the linear corefloods are listed in Table 1. Chemicals were dissolved in 1.0 wt% sodium chloride.…”

Section: Methodsmentioning

confidence: 99%

Coupling the Alkaline-Surfactant-Polymer Technology and the Gelation Technology to Maximize Oil Production

Pitts¹,

Qi²,

Wilson³

et al. 2005

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Gelation technologies have been developed to provide more efficient vertical sweep efficiencies for flooding naturally fractured oil reservoirs or more efficient areal sweep efficiency for those with high permeability contrast "thief zones". The field proven alkaline-surfactant-polymer technology economically recovers 15% to 25% OOIP more oil than waterflooding from swept pore space of an oil reservoir. However, alkaline-surfactant-polymer technology is not amenable to naturally fractured reservoirs or those with thief zones because much of injected solution bypasses target pore space containing oil. This work investigates whether combining these two technologies could broaden applicability of alkaline-surfactant-polymer flooding into these reservoirs.A prior fluid-fluid report discussed interaction of different gel chemical compositions and alkaline-surfactant-polymer solutions. Gel solutions under dynamic conditions of linear corefloods showed similar stability to alkaline-surfactant-polymer solutions as in the fluid-fluid analyses. Aluminum-polyacrylamide, flowing gels are not stable to alkaline-surfactant-polymer solutions of either pH 10.5 or 12.9. Chromium acetate-polyacrylamide flowing and rigid flowing gels are stable to subsequent alkaline-surfactant-polymer solution injection. Rigid flowing chromium acetate-polyacrylamide gels maintained permeability reduction better than flowing chromium acetate-polyacrylamide gels. Silicate-polyacrylamide gels are not stable with subsequent injection of either a pH 10.5 or a 12.9 alkaline-surfactant-polymer solution. Chromium acetate-xanthan gum rigid gels are not stable to subsequent alkaline-surfactantpolymer solution injection. Resorcinol-formaldehyde gels were stable to subsequent alkalinesurfactant-polymer solution injection. When evaluated in a dual core configuration, injected fluid flows into the core with the greatest effective permeability to the injected fluid. The same gel stability trends to subsequent alkaline-surfactant-polymer injected solution were observed.Aluminum citrate-polyacrylamide, resorcinol-formaldehyde, and the silicate-polyacrylamide gel systems did not produce significant incremental oil in linear corefloods. Both flowing and rigid flowing chromium acetate-polyacrylamide gels and the xanthan gum-chromium acetate gel system produced incremental oil with the rigid flowing gel producing the greatest amount. Higher oil recovery could have been due to higher differential pressures across cores. None of the gels tested appeared to alter alkaline-surfactant-polymer solution oil recovery. Total waterflood plus chemical flood oil recovery sequence recoveries were all similar.

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“…It's characteristics have been described elsewhere. 1 Polymers used in the linear corefloods are listed in Table 1. Chemicals were dissolved in 1.0 wt% sodium chloride.…”

Section: Methodsmentioning

confidence: 99%

Coupling the Alkaline-Surfactant-Polymer Technology and the Gelation Technology to Maximize Oil Production

Pitts¹,

Qi²,

Wilson³

et al. 2005

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“…Tertiary methods, specifically recognized as enhanced oil recovery (EOR) techniques, come into play in this stage. EOR techniques contribute to a comprehensive enhancement in the effectiveness of oil displacement, considering both microscopic and macroscopic parameters. , EOR methods frequently employ polymers, surfactants, and alkalis, − chosen for their widespread application in modifying the characteristics of both rock surfaces and reservoir fluids. Chemical enhanced oil recovery (CEOR) methods boost oil recovery by enhancing the efficiency of injected water in displacing oil within the reservoir.…”

Section: Introductionmentioning

confidence: 99%

Unraveling the Impact of Ethylenediaminetetraacetic Acid Chelating Agents on the Oil Recovery Processes: An Insight into Its Role in Fluid–Fluid and Rock–Fluid Interactions

Mohammadi Khanghah,

Parhizgar Keradeh

2024

Langmuir

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In recent years, chelating agents have garnered increasing attention due to their unique capabilities in addressing challenges associated with chemically enhanced oil recovery materials. Most previous studies have primarily focused on examining the influence of chelating agents on rock–fluid interactions. However, their effects on fluid–fluid interactions, specifically on interfacial tension (IFT) characteristics under various conditions, remain relatively unknown. This study investigates the effect of crucial reservoir parameters on the performance of ethylenediaminetetraacetic acid (EDTA) chelating agents in the IFT between crude oil and brine. Furthermore, the study evaluated the impact of varying concentrations of this agent on rock wettability alteration, zeta potential, and spontaneous imbibition. The results illustrated that introducing EDTA at high concentration into seawater (SW) solution reduced the IFT by 85%. Additionally, while higher pH levels contributed to IFT reduction due to increased hydroxyl ions, excessive salinity levels resulted in elevated IFT. Raising the temperature from 30 to 75 °C further decreased the IFT, changing the IFT for optimal EDTA concentration from 20.43 to 2.56 mN/m (∼88% reduction). The changes in zeta potential and contact angle measurements indicated that solutions of 5 and 7 wt % EDTA shifted rock wettability from oil-wet to strongly water-wet, resulting in the wettability alteration index of 1.01 and 1.02, respectively. Inductively coupled plasma analysis, on the other hand, revealed substantial chelation of metal ions from both the solution and rock when EDTA was added to the rock/SW system. This resulted in a significant increase in Ca2+ ions and a decrease in Mg2+ ions, attributed to the multi-ion exchange phenomenon.

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Alkaline-surfactant polymer (ASP)

Nourani

Sadeghnejad

2022

Chemical Methods

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Single Well Alkaline-Surfactant Injectivity Improvement Test in the Big Sinking Field

Cited by 11 publications

References 6 publications

Coupling the Alkaline-Surfactant-Polymer Technology and the Gelation Technology to Maximize Oil Production

Coupling the Alkaline-Surfactant-Polymer Technology and the Gelation Technology to Maximize Oil Production

Unraveling the Impact of Ethylenediaminetetraacetic Acid Chelating Agents on the Oil Recovery Processes: An Insight into Its Role in Fluid–Fluid and Rock–Fluid Interactions

Alkaline-surfactant polymer (ASP)

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