Abstract
There is still half oil remaining in the reservoir after polymer flooding. This paper has carried out the laboratory studies on multi-profile control and displacement system to enhance oil recovery after polymer flooding. First of all, the multiple system comprising a gel particle, cross-linking agent and high effective surfactant, is screened according to specific criteria. Then the profile control experiments on binary and ternary system after polymer flooding are separately carried out to verify the potential of enhanced oil recovery. The results show that the multiple injection system not only blocks the high permeable layers and channels, but also makes full use of medium and low permeability layers, finally improving the whole sweep efficiency. Owing to the surfactant injection, the displacement efficiency is simultaneously improved to some extent, and thus greatly improves the oil recovery after polymer flooding.
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Introduction
Field experience has proven that polymer flooding can be an effective means to improve oil recovery after water flooding. Polymer flooding plays the role by adding water-soluble polymer in injection water to increase the injection viscosity (Needham and Doe 1987; Kaminsky et al. 2007). The reason why polymer flooding can enhance oil recovery relies on that it can improve areal and vertical sweep efficiency as well as providing mobility control (Gogarty 1978; Davison and Mentzer 1982; Wang et al. 2002; Wang and Liu 2004). As an important enhanced oil recovery technique, polymer flooding is currently widely used in China’s onshore oilfields. For example, the world’s largest polymer flooding was implemented at Daqing Oilfield, beginning in 1996. By 2007, 22.3 % of total production from the Daqing Oil Field was attributed to polymer flooding (Dong et al. 2008). Polymer flooding, which is also widely used in offshore oilfields in China, has become an important enhanced oil recovery (EOR) technique recently for offshore oilfields development (Ming et al. 2006; Wei et al. 2007; 2008).
Although polymer flooding can boost the oil recovery to over 50 %, which is about 10 % higher than water flooding (Jiecheng et al. 2010), there is still half oil remaining in the reservoir. The effect of polymer flooding is limited due to the following reasons: Firstly, the heterogeneity is aggravated during the polymer flooding process, in which the water and polymer fingering phenomena happens along thief zones and high permeability streak resulting in low sweep efficiency. Secondly, the polymer displacement formula is not able to reduce the interfacial tension, so the displacement efficiency is low. In those means, how to improve the oil recovery after polymer flooding can take both the sweep efficiency and displacement efficiency into account (Jishui and Yiqiang 2002; Ting and Xiusheng 2004; Stoll et al. 2010).
The key to enhance oil recovery after polymer flooding is to improve the sweep efficiency of injected water. The current most used method is polymer gel profile control technology such as preformed gel particles (Coste et al. 2000; Baojun et al. 2007a, b), which can divert the fluid to flow across the upswept area. In consideration of the abundant remaining polymer in the reservoir after polymer flooding, the cross-linking agent can be injected to react with the residual polymer to form the gel, which can block high permeability zone and activate the medium–low permeability zone. As a result, the sweep efficiency of water flooding and oil recovery can be enhanced (Yefei et al. 2006; Dai et al. 2010). The efficient surfactant can also be injected to improve the low permeability layer displacement efficiency and bring down the follow-up water injection pressure. The above three injection agents make up the multiple-profile control system, which not only enlarges the follow-up water flooding sweep efficiency but also increases the displacement efficiency to some extent (Abdo and Chung 1984). The high, medium and low permeability layers are all made full use of, thus the oil recovery after polymer flooding goes up a lot.
Based on previous research, the multiple-profile control system components are screened separately. The major focus is the effect of the system in core flooding after polymer flooding, including the water cut decline, the oil recovery improvement and the injection pressure reduction. The potential of enhancing oil recovery of the multiple-profile control system can be evaluated from the experiment results analysis.
Multiple-profile control system
Gel particle type screening
The layered heterogeneous sand pack cores are used in screening experiment. The core size is 4.5 × 4.5 × 30.0 mm and the permeability max–min ratio is 8 (The terminology describes the degree of permeability heterogeneity, and is defined as the ratio of the max layer permeability and min layer permeability). The cation gel particle and the anion gel particle are going to be screened by the relationship between the injected PV and the recovery factor of the core profile control experiment (Shaodong and Xiangguo 2002). In both profile control experiments, the water flooding is the first displacement stage, and the polymer flooding is the second displacement stage. The gel particle solution is injected after the polymer flooding. The results of the core flooding experiment are shown in Table 1.
The results show that the recovery factors of water and polymer flooding for cation and anion are nearly same, but the recovery factor of cationic gel particle is eight percents higher than anion after profile control displacement stage. The reason lies in the electrostatic adsorption reaction between the cationic gel particle and the anion residual polymer on the rock surface, which larges the grain diameter of cationic gel particle. Therefore, the blocking effect of cationic gel is better than anion gel particle.
Cross-linking agent concentration screening
The screening experiment is also adopting the layered heterogeneous sand pack core, the displacement experiments of different concentration cross-linking agent are carried out after polymer flooding (Dejun and Hui 2002. The recovery factor of different scenes are shown in Table 2.
The results show that the recovery factor after polymer flooding is basically same for the heterogeneous cores with same permeability max–min ratio. The cross-linking agent can considerably improve the recovery factor after polymer flooding. The concentration 100 mg/L obtained the highest rate of EOR effect.
High effective surfactant concentration screening
The optimal surfactant concentration can be screened according to the interfacial tension of different surfactant concentration solution (XiaoQuan and Xijing 2004; Monika et al. 2011). The interfacial tension variation can be seen from Fig. 1. When the concentration is 0.2 %, the interfacial tension achieves the minimum value. So the 0.2 % will be used as the optimal concentration.
In order to verify the depressurization effects of the 0.2 % concentration surfactant, the low permeability core displacement experiment is conducted. The injection pressure data with injected PV is recorded. The results of 0.1 and 0.2 % are shown in Fig. 2.
It can be seen that the pressure in water and polymer flooding stage is almost the same, when it turns to surfactant flooding, the pressure begins to dramatically decline and the pressure continues to reduce at the following water flooding stage. This phenomenon certifies that the surfactant system can bring down the injection pressure by reducing the water–oil interfacial tension and residual oil saturation to raise the water phase relative permeability.
Core flooding experiment
Experiment equipment
Material
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Reinjection water from a oil production plant in Daqing Oilfield, the salinity is 2841.2 mg/L, the injection water belongs to bicarbonate-sodium type water and the impurities are removed using 0.2 μm polycarbonate membrane filtration;
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Cross-linking agent for the field application in Daqing Oilfield with 67 % trivalent chromium ion and blackish green color;
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Polymer with the molecular weight 16–19 million and the hydrolyzing degree is 20 %;
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Cationic gel particles used in Daqing Oilfield;
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Efficient surfactant (anion sulfonic acid salt) with 50 % effective content and the relative molecular weight is 420;
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Oil mixture of dehydrated crude oil and jet fuel (the viscosity of crude oil is 9.8 mPa s at 45 °C, and the density is 0.925 g/cm3);
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Artificial quartz sandstone core.
Instruments
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Particle mixing device;
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High pressure displacement pump: velocity range is 0.01–200 mL/min, working pressure is not less than 30 MPa;
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Annular pump: working pressure is not less than 20 MPa; core holder: core sample size is 4.5 × 4.5 cm × 30 cm and the working pressure is not less than 16 MPa;
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Manometer: Electronic pressure gauge, the measuring range is selected according to the experiment requirement; multi-pass set;
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Graduated cylinder: Certificated graduated cylinder, the range is 20–50 mL;
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Electronic balance: sensibility reciprocal 10 mg.
The flow chart of the experiment is illustrated as Fig. 3.
Experiment procedure
Binary injection system profile control experiment
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Vacuumize the core and saturate the core with water;
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Saturate the core with oil;
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Inject water until the water cut reaches 98 %;
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Inject 0.7 PV polymer solution with the concentration 1,000 mg/L;
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Inject 0.3 PV water;
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Inject 1 PV mixture solution with 100 mg/L cross-linking agent and 2,000 mg/L cationic gel particles;
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Keep for 2 days at 45 °C constant temperature;
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Inject water until the water cut reaches 98 %.
Multiple injection system profile control experiment
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Vacuumize the core and saturate the core with water;
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Saturate the core with oil;
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Inject water until the water cut reaches 98 %;
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Inject 0.7 PV polymer solution with the concentration 1,000 mg/L;
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Inject 0.3 PV water;
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Inject 0.3 PV 2,000 mg/L cationic gel particles solution;
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Inject 0.2 PV 100 mg/L cross-linking agent solution;
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Inject 0.2 PV 0.2 % surfactant solution;
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Keep for 2 days at 45 °C constant temperature;
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Inject water until the water cut reaches 98 %.
Experimental results and analysis
The Binary injection system profile control experiment
Profile control effect
The breakthrough pressure of different displacement ways is recorded in the core flooding process and the core permeability is measured after binary system injection. The blocking ratio (BR) and residual resistance factor (RRF) are obtained by calculation which is illustrated in Table 3.
The BR is defined as following:
Where, the subscript “i” indicates the initial core permeability and the subscript “f” indicates the final core permeability after profile control treatment.
The residual resistance factor is defined as following:
where Krw is the initial water phase relative permeability and Krp is the water relative permeability after profile control treatment.
It can be seen that the breakthrough pressure of water flooding after binary system injection increased significantly. This phenomenon is created by the blocking effect of binary system. The grain diameter of gel particle is increasing as a result of electrostatic adsorption and swelling capacity after polymer flooding. The large pores are blocked by the big gel particles. The cross-linking agent cannot only form the cross-linking polymer with the residual polymer in large throats but also penetrate into small throats with low permeability which blocks the flow path to force the water flow into throats with lower permeability. The injection pressure continues to rise on account of the blocking effect.
Comparative analysis between binary injection and single injection
The binary system injection and single injection (cross-linking agent or gel particles) are separately conducted on the cores with the same permeability (1,200 mD). The injection pressure variation curve is shown as in Fig. 4.
It can be seen from the figure that the injection pressure is nearly the same at the water and polymer flooding stage for the three injection methods. However, the injection pressure starts to show a great difference at the sequent water flooding stage for the three injection methods. The breakthrough pressure of sequent water flooding after cross-linking agent injection is relatively low and finally maintains a stable low pressure. The breakthrough of sequent water flooding after gel particles injection increases and shows some fluctuation. The breakthrough pressure of sequent water flooding after binary system injection is high. Both the fluctuation range and fluctuation extent are higher than single injection situation.
The results show that the binary system injection is better than single injection. The binary system can block the medium–high throats using the residual polymer preferably. The blocking effect can change the sequent water displacement path to improve the water flood sweep efficiency.
The multiple injection system profile control experiment
The recovery factor variation curve (Fig. 5) and recovery factor table (Table 4) can be obtained by the relationship between recover extent and injection volume factor at different injection stage of the multiple injection system core flooding experiment.
It can be seen from Table 4 and Fig. 5 that the recovery factors of water flooding and polymer flooding are limited and the recovery factors increase in various degrees at the cationic gel particle, cross-linking agent and surfactant injection stages.
The injection pressure variation curve is shown as in Fig. 6. The injection pressure at water and polymer flooding stage is relatively low. The injection pressure rises up to 4 MPa after the gel particle injection and a 1.5-MPa pressure fluctuation phenomenon comes out. The pressure continues to stay the same extent as the cross-linking agent is injected. The surfactant injection raises the injection pressure further and the injection pressure of the sequent water flooding basically stays at about 2 MPa, which is largely improved comparing with the water and polymer flooding.
In consideration of the actual construction requirements and the pumping-in equipment safety, the pumping-in pressure is usually not too high. In comparison with the binary injection system (gel particle/cross-linking agent), the sequent water flooding injection pressure of multiple injection system decreased significantly. Due to the low injection pressure and good profile control effect, the multiple injection system has pretty good practical application value.
Multiple injection system, which is used to conduct profile control in heterogeneous formations, cannot only make use of the middle-low permeability formations but also increase the pressure of the following water flooding. The multiple injection system can enhance oil recovery to a great extent.
Conclusion
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The cationic gel particles have been screened to be used in this study; different cross-linking concentrations have different pressurization and production increasing effect, and the higher the cross-linking concentration is, the better the production performance is; the surfactant has a good depressurization and production enhanced effect and the 0.2 % is the best concentration.
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The profile control effect of binary injection system is better than that of single injection. The binary system can block the medium–high throats by using the residual polymer preferably. The blocking effect can change the sequent water displacement path to improve the water flood sweep efficiency.
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The multiple injection system can enhance oil recovery to a great extent. The multiple injection system can not only make use of the middle-low permeability formations but also increase the pressure of the following water flooding.
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Acknowledgments
This work was sponsored by the National 863 Program (Grant No. 2007AA06Z00) for research on enhanced oil recovery technology after polymer flooding, the National Natural Science Foundation (Grant No. 40974056) on the particle gel profile control technology.
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Feng, Q.H., Chen, X.C. & Sun, M.D. Study of the multiple-profile control system to enhance oil recovery after polymer flooding. J Petrol Explor Prod Technol 2, 133–139 (2012). https://doi.org/10.1007/s13202-012-0029-7
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DOI: https://doi.org/10.1007/s13202-012-0029-7