Experimental Study of Enhancing Oil Recovery with Weak Base Alkaline/Surfactant/Polymer

Na2CO3 was used together with surfactant and polymer to form the Alkaline/Surfactant/Polymer (ASP) flooding system. Interfacial tension (IFT) and emulsification of Dagang oil and chemical solutions were studied in the paper. The experiment results show that the ASP system can form super-low interfacial tension with crude oil and emulsified phase. The stability of the emulsion is enhanced by the Na2CO3, surfactant, and the soap generated at oil/water contact. Six core flooding experiments are conducted in order to investigate the influence of Na2CO3 concentration on oil recovery. The results show the maximum oil recovery can be obtained with 0.3 wt% surfactant, 0.6 wt% Na2CO3, and 2000 mg/L polymer. In a heterogeneous reservoir, the ASP flooding could not enhance the oil recovery by reducing IFT until it reaches the critical viscosity, which indicates expanding the sweep volume is the premise for reducing IFT to enhance oil recovery. Reducing or removing the alkali from ASP system to achieve high viscosity will reduce oil recovery because of the declination of oil displacement efficiency. Weak base ASP alkali can ensure that the whole system with sufficient viscosity can start the medium and low permeability layers and enhance oil recovery even if the IFT only reaches 10−2 mN/m.

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The Combined Flooding of Dispersed Particle Gel and Surfactant for Conformance Control and EOR: From Experiment to Pilot Test

10.2118/204324-ms ◽

2021 ◽

Author(s):

Xia Yin ◽

Tianyi Zhao ◽

Jie Yi

Keyword(s):

Oil Recovery ◽

Formation Energy ◽

High Salinity ◽

Surfactant Solution ◽

Pilot Test ◽

Control Performance ◽

Core Flooding ◽

Displacement Efficiency ◽

Conformance Control ◽

And Performance

Abstract The water channeling and excess water production led to the decreasing formation energy in the oilfield. Therefore, the combined flooding with dispersed particle gel (DPG) and surfactant was conducted for conformance control and enhanced oil recovery in a high temperature (100-110°C) high salinity (>2.1×105mg/L) channel reservoir of block X in Tahe oilfield. This paper reports the experimental results and pilot test for the combined flooding in a well group of Block X. In the experiment part, the interfacial tension, emulsifying capacity of the surfactant and the particle size during aging of DPG were measured, then, the conformance control and enhanced oil recovery performance of the combined flooding was evaluated by core flooding experiment. In the pilot test, the geological backgrounds and developing history of the block was introduced. Then, an integrated study of EOR and conformance control performance in the block X are analyzed by real-time monitoring and performance after treatment. In addition, the well selection criteria and flooding optimization were clarified. In this combined flooding, DPG is applied as in-depth conformance control agent to increase the sweep efficiency, and surfactant solution slug following is used for improve the displacement efficiency. The long term stability of DPG for 15 days ensures the efficiency of in-depth conformance control and its size can increase from its original 0.543μm to 35.5μm after aging for 7 days in the 2.17×105mg/L reservoir water and at 110°C. In the optimization, it is found that 0.35% NAC-1+ 0.25% NAC-2 surfactant solution with interfacial tension 3.2×10-2mN/m can form a relatively stable emulsion easily with the dehydrated crude oil. In the double core flooding, the conformance control performance is confirmed by the diversion of fluid after combined flooding and EOR increases by 21.3%. After exploitation of Block X for 14 years, the fast decreasing formation energy due to lack of large bottom water and water fingering resulted in a decreasing production rate and increasing watercut. After combined flooding in Y well group with 1 injector and 3 producers, the average dynamic liquid level, daily production, and tracing agent breakthrough time increased, while the watercut and infectivity index decreased. The distribution rate of injected fluid and real-time monitoring also assured the conformance control performance. The oil production of this well group was increased by over 3000 tons. Upon this throughout study of combined flooding from experiment to case study, adjusting the heterogeneity by DPG combined with increasing displacement efficiency of surfactant enhanced the oil recovery synergistically in this high salinity high temperature reservoir. The criteria for the selection and performance of combined flooding also provides practical experiences and principles for combined flooding.

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Nonionic Surfactant to Enhance the Performances of Alkaline–Surfactant–Polymer Flooding with a Low Salinity Constraint

Applied Sciences ◽

10.3390/app10113752 ◽

2020 ◽

Vol 10 (11) ◽

pp. 3752 ◽

Cited By ~ 1

Author(s):

Shabrina Sri Riswati ◽

Wisup Bae ◽

Changhyup Park ◽

Asep K. Permadi ◽

Adi Novriansyah

Keyword(s):

Nonionic Surfactant ◽

Oil Recovery ◽

Anionic Surfactant ◽

Pore Volume ◽

Salinity Gradient ◽

Reference Case ◽

Low Salinity ◽

Asp Flooding ◽

Optimum Salinity ◽

Alkaline Surfactant Polymer

This paper presents a nonionic surfactant in the anionic surfactant pair (ternary mixture) that influences the hydrophobicity of the alkaline–surfactant–polymer (ASP) slug within low-salinity formation water, an environment that constrains optimal designs of the salinity gradient and phase types. The hydrophobicity effectively reduced the optimum salinity, but achieving as much by mixing various surfactants has been challenging. We conducted a phase behavior test and a coreflooding test, and the results prove the effectiveness of the nonionic surfactant in enlarging the chemical applicability by making ASP flooding more hydrophobic. The proposed ASP mixture consisted of 0.2 wt% sodium carbonate, 0.25 wt% anionic surfactant pair, and 0.2 wt% nonionic surfactant, and 0.15 wt% hydrolyzed polyacrylamide. The nonionic surfactant decreased the optimum salinity to 1.1 wt% NaCl compared to the 1.7 wt% NaCl of the reference case with heavy alcohol present instead of the nonionic surfactant. The coreflooding test confirmed the field applicability of the nonionic surfactant by recovering more oil, with the proposed scheme producing up to 74% of residual oil after extensive waterflooding compared to 51% of cumulative oil recovery with the reference case. The nonionic surfactant led to a Winsor type III microemulsion with a 0.85 pore volume while the reference case had a 0.50 pore volume. The nonionic surfactant made ASP flooding more hydrophobic, maintained a separate phase of the surfactant between the oil and aqueous phases to achieve ultra-low interfacial tension, and recovered the oil effectively.

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Asphaltene Deposition Induced by Carbon Oxide and its Influence on Displacement Efficiency

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.594-597.2451 ◽

2012 ◽

Vol 594-597 ◽

pp. 2451-2454

Author(s):

Feng Lan Zhao ◽

Ji Rui Hou ◽

Shi Jun Huang

Keyword(s):

Crude Oil ◽

Oil Recovery ◽

Carbon Oxide ◽

Viscosity Reduction ◽

Core Flooding ◽

Displacement Efficiency ◽

Oil Composition ◽

Oil Viscosity ◽

Asphaltene Deposition ◽

Total Oil

CO2is inclined to dissolve in crude oil in the reservoir condition and accordingly bring the changes in the crude oil composition, which will induce asphaltene deposition and following formation damage. In this paper, core flooding device is applied to study the effect of asphaltene deposition on flooding efficiency. From the flooding results, dissolution of CO2into oil leads to recovery increase because of crude oil viscosity reduction. But precipitated asphaltene particles may plug the pores and throats, which will make the flooding effects worse. Under the same experimental condition and with equivalent crude oil viscosity, the recovery of oil with higher proportion of precipitated asphaltene was relatively lower during the CO2flooding, so the asphltene precipitation would affect CO2displacement efficiSubscript textency and total oil recovery to some extent. Combination of static diffusion and dynamic oil flooding would provide basic parameters for further study of the CO2flooding mechanism and theoretical evidence for design of CO2flooding programs and forecasting of asphaltene deposition.

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Indoor Study of Viscosity Reducer for Thickened Oil of Huancai

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.268-270.547 ◽

2012 ◽

Vol 268-270 ◽

pp. 547-550

Author(s):

Qing Wang Liu ◽

Xin Wang ◽

Zhen Zhong Fan ◽

Jiao Wang ◽

Rui Gao ◽

...

Keyword(s):

Interfacial Tension ◽

Oil Recovery ◽

Heavy Oil ◽

High Viscosity ◽

Oil Field ◽

Viscosity Reduction ◽

Oil Viscosity ◽

Low Viscosity ◽

Viscosity Reducer ◽

Oil Water

Liaohe oil field block 58 for Huancai, the efficiency of production of thickened oil is low, and the efficiency of displacement is worse, likely to cause other issues. Researching and developing an type of Heavy Oil Viscosity Reducer for exploiting. The high viscosity of W/O emulsion changed into low viscosity O/W emulsion to facilitate recovery, enhanced oil recovery. Through the experiment determine the viscosity properties of Heavy Oil Viscosity Reducer. The oil/water interfacial tension is lower than 0.0031mN•m-1, salt-resisting is good. The efficiency of viscosity reduction is higher than 90%, and also good at 180°C.

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Optimization of Surfactant and Polymer for SP Flooding of Zahra Oil

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.535.701 ◽

2014 ◽

Vol 535 ◽

pp. 701-704 ◽

Cited By ~ 1

Author(s):

Peng Lv ◽

Ming Yuan Li ◽

Mei Qin Lin

Keyword(s):

Interfacial Tension ◽

Polymer Solution ◽

Enhanced Oil Recovery ◽

Oil Recovery ◽

High Viscosity ◽

Oil Field ◽

Interfacial Tensions

Producing ultra-low interfacial tensions and maintaining high viscosity is the most important mechanism relating to SP flooding for enhanced oil recovery. The interfacial tension between surfactant (PJZ-2 and BE)/polymer solution and Zahra oil was evaluated in the work. Based on the evaluatiojn of interfacial tension, the polymer FP6040s/surfactant BE system was selected as the SP flooding system for Zahra oil field.

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Improving CO2 storage and oil recovery by injecting alcohol-treated CO2

The APPEA Journal ◽

10.1071/aj19145 ◽

2020 ◽

Vol 60 (2) ◽

pp. 662

Author(s):

Saira ◽

Furqan Le-Hussain

Keyword(s):

Oil Recovery ◽

Co2 Sequestration ◽

Computer Modelling ◽

Co2 Storage ◽

Co2 Injection ◽

Displacement Efficiency ◽

Sweep Efficiency ◽

Numerical Studies ◽

Reservoir Simulator ◽

Enhance Oil Recovery

Oil recovery and CO2 storage related to CO2 enhance oil recovery are dependent on CO2 miscibility. In case of a depleted oil reservoir, reservoir pressure is not sufficient to achieve miscible or near-miscible condition. This extended abstract presents numerical studies to delineate the effect of alcohol-treated CO2 injection on enhancing miscibility, CO2 storage and oil recovery at immiscible and near-miscible conditions. A compositional reservoir simulator from Computer Modelling Group Ltd. was used to examine the effect of alcohol-treated CO2 on the recovery mechanism. A SPE-5 3D model was used to simulate oil recovery and CO2 storage at field scale for two sets of fluid pairs: (1) pure CO2 and decane and (2) alcohol-treated CO2 and decane. Alcohol-treated CO2 consisted of a mixture of 4 wt% of ethanol and 96 wt% of CO2. All simulations were run at constant temperature (70°C), whereas pressures were determined using a pressure-volume-temperature simulator for immiscible (1400 psi) and near-miscible (1780 psi) conditions. Simulation results reveal that alcohol-treated CO2 injection is found superior to pure CO2 injection in oil recovery (5–9%) and CO2 storage efficiency (4–6%). It shows that alcohol-treated CO2 improves CO2 sweep efficiency. However, improvement in sweep efficiency with alcohol-treated CO2 is more pronounced at higher pressures, whereas improvement in displacement efficiency is more pronounced at lower pressures. The proposed methodology has potential to enhance the feasibility of CO2 sequestration in depleted oil reservoirs and improve both displacement and sweep efficiency of CO2.

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Effect of Chromatographic Transport in Hexylamine on Displacement of Oil by Water in Porous Media

Society of Petroleum Engineers Journal ◽

10.2118/619-pa ◽

1964 ◽

Vol 4 (03) ◽

pp. 231-239 ◽

Cited By ~ 3

Author(s):

A.S. Michaels ◽

Arnold Stancell ◽

M.C. Porter

Keyword(s):

Contact Angle ◽

Porous Media ◽

Interfacial Tension ◽

Oil Recovery ◽

Water Flooding ◽

Massachusetts Institute ◽

Massachusetts Institute Of Technology ◽

Displacement Efficiency ◽

Institute Of Technology ◽

Increased Oil Recovery

MICHAELS, A.S., MASSACHUSETTS INSTITUTE OF TECHNOLOGY, CAMBRIDGE, MASS. MEMBER AIME STANCELL, ARNOLD, MASSACHUSETTS INSTITUTE OF TECHNOLOGY, CAMBRIDGE, MASS. PORTER, M.C., MASSACHUSETTS INSTITUTE OF TECHNOLOGY, CAMBRIDGE, MASS. Abstract Previous laboratory studies have demonstrated that the injection of small quantities of reverse wetting agents during water displacement can increase oil recovery from unconsolidated porous media. In the present investigation, an attempt has been made to determine more fully the effects of reverse wetting treatments and to clarify the mechanism by which increased oil recovery is effected Water-oil displacements were performed in beds of 140–200 mesh silica sand. Hexylamine slugs (injected after 0.25 pore volume of water through put), when adequate in size and concentration, were effective in promoting additional oil recovery. Their effectiveness increased with the quantity of amine injected. However, slugs of sufficient size and concentration to stimulate oil production at water flow rates of 34 ft/day did not do so at 4 ft/day.Visual studies in a glass grid micromodel have shown that the stimulation of oil production, via aqueous bexylamine, is a result of transient changes in the oil wettability of the pore walls. If the am in e slug is of sufficient size and concentration to induce significant changes in the adhesion-tension, large continuous oil masses will be formed. If the superficial water velocity is high enough to result in rapid desorption of the am in e, a favorable "wettability gradient" may be established across the masses; under such conditions, high oil mobility is observed, and increased oil recovery results. Introduction It is generally agreed that the efficiency of oil displacement by water in porous media is limited in part by capillary forces which cause the retention of isolated masses of oil - resulting in the so-called "irreducible minimum oil saturation". Recent estimates indicate that there are about 220 billion bbl of petroleum in United States reservoirs which are not economically recoverable with present techniques (such as water flooding). This amounts to almost five times the known recoverable reserves. It has been recognized for some time that a suitable alteration in the water-oil interfacial tension and/or the contact angle, as measured between the water-oil interface and the solid surface, should result in better displacement efficiency. Surface active agents can be used as interfacial tension depressants to accomplish this objective, but unfortunately, the additional oil recovery is seldom commensurate with the treatment cost.In contrast to interfacial tension depressants, the effect of contact angle alterations on water- oil displacements has received relatively little attention in the literature. It is known that the wettability affects the displacement process. Displacements in water-wet systems generally result in lower residual oil saturations than those in oil-wet systems. The effect of "transient" wettability alterations concurrent with the displacement process have been investigated by Wagner, Leach and coworkers, wherein it has been demonstrated that the establishment of water- wet conditions during water flooding of oil-wet, oil-saturated porous media is accompanied by significant increase in oil displacement efficiency. Michaels and Timmins studied the effects of transient contact angle alterations resulting from chromatographic transport of reverse wetting agents through unconsolidated sand. It was demonstrated that chromatographic transport of short-chain (C4 through C8) primary aliphatic amines can improve oil recovery and that the recovery increases with the quantity of amine injected (i.e., with either the amine concentration or the volume of the slug injected). Circumstantial evidence indicated that the increased displacement efficiency resulted primarily from transient changes in wettability of the porous medium.In the present investigation, additional information has been obtained on the effects of reverse wetting treatments and the mechanism by which increased oil recovery is accomplished. SPEJ P. 231^

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Study on Influence of Injection Method on the Effect of Oil Displacement of Nanometer Microspheres

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.734-737.1272 ◽

2013 ◽

Vol 734-737 ◽

pp. 1272-1275

Author(s):

Ji Hong Zhang ◽

Zhi Ming Zhang ◽

Xi Ling Chen ◽

Qing Bin He ◽

Jin Feng Li

Keyword(s):

Oil Recovery ◽

Experimental Result ◽

Displacement Efficiency ◽

Oil Displacement ◽

Profile Control ◽

Oil Displacement Efficiency ◽

Injection Methods ◽

The One ◽

Deep Profile ◽

Enhance Oil Recovery

Nanometer microspheres injection is a new deep profile control technology. Nanometer microspheres could inflate with water, resulting in plugging step by step in reservoirs, which could improve the swept efficiency in the reservoir and enhance oil recovery. By using non-homogeneous rectangular core, oil displacement efficiency experiment was conducted for studying the influence of different injection methods on the effect of injection nanometer microspheres. The experimental result shows that, compared with development effect of single-slug injection or triple-slug injection, the one of double-slug injection is better. Nanometer microspheres can enhance oil recovery significantly in medium and low permeability reservoir.

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Research on Characteristics of Combination Flooding System and Oil Displacement Efficiency

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.391-392.1047 ◽

2011 ◽

Vol 391-392 ◽

pp. 1047-1050 ◽

Cited By ~ 1

Author(s):

Yan Chang Su ◽

Wen Xiang Wu

Keyword(s):

Binary System ◽

Interfacial Tension ◽

Physical Simulation ◽

Displacement Efficiency ◽

Weak Base ◽

Simulation Experiments ◽

Oil Displacement ◽

Oil Displacement Efficiency ◽

Heterogeneous Cores

By physical simulation experiments, the features of alkali-free binary flooding system (polymer and a new surfactant BS) were contrasted with weak base ternary flooding system and alkali ternary flooding system. The experiment results showed that interfacial tension of BS binary system is the lowest. In the absence of alkali, the viscosity and elasticity of binary system were higher than those of other two ternary flooding systems. By physical simulation experiments with artificial heterogeneous cores, the recovery of BS binary flooding system was 2 percent higher than that of weak base ternary flooding system, and 1.4 percent higher than that of alkali ternary flooding system.

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Study of Enhanced-Oil-Recovery Mechanism of Alkali/Surfactant/Polymer Flooding in Porous Media From Experiments

SPE Journal ◽

10.2118/126128-pa ◽

2009 ◽

Vol 14 (02) ◽

pp. 237-244 ◽

Cited By ~ 39

Author(s):

Pingping Shen ◽

Jialu Wang ◽

Shiyi Yuan ◽

Taixian Zhong ◽

Xu Jia

Keyword(s):

Porous Media ◽

Fluid Flow ◽

Oil Recovery ◽

Production Performance ◽

Residual Oil ◽

Flow Mechanism ◽

Displacement Efficiency ◽

High Permeability ◽

Heterogeneous Reservoir ◽

Asp Flooding

Summary The fluid-flow mechanism of enhanced oil recovery (EOR) in porous media by alkali/surfactant/polymer (ASP) flooding is investigated by measuring the production performance, pressure, and saturation distributions through the installed differential-pressure transducers and saturation-measurement probes in a physical model of a vertical heterogeneous reservoir. The fluid-flow variation in the reservoir is one of the main mechanisms of EOR of ASP flooding, and the nonlinear coupling and interaction between pressure and saturation fields results in the fluid-flow variation in the reservoir. In the vertical heterogeneous reservoir, the ASP agents flow initially in the high-permeability layer. Later, the flow direction changes toward the low- and middle-permeability layers because the resistance in the high-permeability layer increases on physical and chemical reactions such as adsorption, retention, and emulsion. ASP flooding displaces not only the residual oil in the high-permeability layer but also the remaining oil in the low- and middle-permeability layers by increasing both swept volume and displacement efficiency. Introduction Currently, most oil fields in China are in the later production period and the water cut increases rapidly, even to more than 80%. Waterflooding no longer meets the demands of oilfield production. Thus, it is inevitable that a new technology will replace waterflooding. The new technique of ASP flooding has been developed on the basis of alkali-, surfactant-, and polymer-flooding research in the late 1980s. ASP flooding uses the benefits of the three flooding methods simultaneously, and oil recovery is greatly enhanced by decreasing interfacial tension (IFT), increasing the capillary number, enhancing microscopic displacing efficiency, improving the mobility ratio, and increasing macroscopic sweeping efficiency (Shen and Yu 2002; Wang et al. 2000; Wang et al. 2002; Sui et al. 2000). Recently, much intensive research has been done on ASP flooding both in China and worldwide, achieving some important accomplishments that lay a solid foundation for the extension of this technique to practical application in oil fields (Baviere et al. 1995; Thomas 2005; Yang et al. 2003; Li et al. 2003). In previous work, the ASP-flooding mechanism was studied visually by using a microscopic-scale model and double-pane glass models with sand (Liu et al. 2003; Zhang 1991). In these experiments, the water-viscosity finger, the residual-oil distribution after waterflooding, and the oil bank formed by microscopic emulsion flooding were observed. In Tong et al. (1998) and Guo (1990), deformation, threading, emulsion (oil/water), and strapping were observed as the main mechanisms of ASP flooding in a water-wetting reservoir, while the interface-producing emulsion (oil/water), bridging between inner pore and outer pore, is the main mechanism of ASP flooding in an oil-wetting reservoir. For a vertical heterogeneous reservoir, ASP flooding increases displacement efficiency by displacing residual oil through decreased IFT, simultaneously improving sweep efficiency by extending the swept area in both vertical and horizontal directions. Some physical and chemical phenomena, such as emulsion, scale deposition, and chromatographic separation, occur during ASP flooding (Arihara et al. 1999; Guo 1999). Because ASP flooding in porous media involves many complicated physicochemical properties, many oil-recovery mechanisms still need to be investigated. Most research has been performed on the microscopic displacement mechanism of ASP flooding, while the fluid-flow mechanism in porous media at the macroscopic scale lacks sufficient study. In this paper, a vertical-heterogeneous-reservoir model is established, and differential-pressure transducers and saturation-measuring probes are installed. The fluid-flow mechanism of increasing both macroscopic sweep efficiency and microscopic displacement efficiency is studied by measuring the production performance and the variation of pressure and saturation distributions in the ASP-flooding experiment. An experimental database of ASP flooding also is set up and provides an experimental base for numerical simulation.

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