Green Enhanced Oil Recovery for Carbonate Reservoirs
Abstract
:1. Introduction
2. Literature Review
2.1. Surfactant Flooding in Carbonates
2.2. Polymer Flooding in Carbonates
2.3. SP Flooding in Carbonates
- The majority of the publications of surfactant flooding in carbonates deals with synthetic chemical surfactants and co-surfactants. Many of them are not eco-friendly, either surfactant or co-surfactant. Corrosive acid is usually used to increase the productivity of the formulation. Several publications deal with environmentally friendly surfactants and co-surfactants in oil recovery. However, these formulations are applied in a sandstone reservoir. There is not enough information available on the combined effect of a green surfactant, alcohol, ketone, acid, and polymer on EOR in carbonates.
- Polymer flooding, especially synthetic polymer, is a widely used chemical oil recovery method in sandstone reservoirs. Most of the polymers applied in chemical EOR are synthetic such as HPAM or PAM. There are few biopolymers, such as Xanthan gum, used in the sandstone reservoirs. The application of biopolymer in carbonates is restricted due to harsh reservoir conditions.
- Surfactant-based polymer flooding is widespread in sandstone reservoirs but limited in carbonate reservoirs. Several publications of SP or ASP flooding in carbonate in tables deals with chemicals such as surfactant, polymer, alcohol, and alkali. These are synthetic, and many of them are not eco-friendly. There is a knowledge gap in environmentally friendly SP formulation. It requires a step-by-step documentation to understand the role of green SP in carbonate.
3. Carbonate Reservoirs in Saudi Arabia
3.1. Abqaiq
3.2. Haradh
3.3. Khurais
3.4. Khursaniyah
3.5. Qatif
3.6. Manifa
4. Methodology
4.1. Materials
Properties | Formic Acid | Acetic Acid | Acrylic Acid | Acetone | Butanone |
---|---|---|---|---|---|
Chemical Formula | H-COOH | CH3-COOH | CH2=CH-COOH | CH3-CO-CH3 | CH3-CO-CH2CH3 |
Molar mass | 46.025 g/mol | 60.052 g/mol | 72.06 g/mol | 58.08 g/mol | 72.117 g/mol |
Appearance | Colorless liquid | Colorless liquid | Colorless liquid | Colorless liquid | Colorless liquid |
Density | 1.22 g/cm3 | 1.049 g/cm3 | 1.05 g/cm3 | 0.78 g/cm3 at 25 °C | 0.80 g/cm3 at 25 °C |
Boiling point | 100.8 °C | 118 °C | 141 °C | 56.05 °C | 79.64 °C |
Viscosity | 1.57 cP at 20 °C | 1.22 cP at 20 °C | 1.3 cP at 20 °C | 0.29 cP at 25 °C | 0.43 cP at 25 °C |
4.2. Selection of Chemical
4.3. Phase Behavior Modeling
4.4. IFT Measurement
4.5. Core Flood Experiment
5. Results and Discussion
5.1. Optimum Salinity Determination
5.2. IFT Measurement
IFT Values of Formic Acid with APG
5.3. Influence of Ketone Observed in Core Flood Experiment
5.3.1. Acetone, APG 264, and Xanthan Gum Formulation
5.3.2. Butanone, APG 264, and Biopolymer Formulation
5.4. Influence of Acrylic Acid in Carbonate
5.4.1. Acrylic Acid, APG 264, and Xanthan Gum Formulation
5.4.2. Acrylic Acid, Butanol, APG 264, and Xanthan Gum Formulation
5.5. Comparison
Comparison of the Ketones, Acrylic Acids, Butanol, and SP Formulations
5.6. Influence of Formic and Acetic Acids in Sandstone
6. Conclusions
- The sample’s solubilization parameters for oil and brine are calculated using the Healy and Reed correlation and plotted against salinity. The intersecting point of the two best-fit lines gives the optimum salinity. The optimum salinity for the APG–Crude oil system is determined at 4.6% NaCl.
- A core flooding experiment in the carbonate core confirmed that a mixture of 0.5% APG, 1000 mg/L XG, and 0.6% acetone recovered ~8% residual oil. However, the same amount of APG and XG, blinding with 0.6% butanone, produced ~22% incremental oil, which was more than double crude oil. This formulation is efficient in recovering tertiary oil from carbonate core.
- A combination of 0.5% APG, 1000 mg/L XG, and 0.5% acrylic acid gave ~11% incremental oil recovery. However, the same amount of APG, XG, and acrylic acid, mixing with 0.6% butanol, recovered ~18% tertiary oil. The SP, acrylic acid, and alcohol blend is effective in producing residual.
- The blending of APG, XG with butanone is more effective in recovering residual crude than the mixture of APG, XG, acrylic acid, and butanol from the carbonate core.
7. Recommendations
- It would be better to evaluate the oil recovery potential of formic acid and SP mixture and acetic acid and SP combination in carbonate core.
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
Appendix A. Surfactant and Polymer Field Application
Appendix A.1. Surfactant Flooding in Carbonates
S/L | Surfactant | Synthetic/Bio/Green | Formation | Field | Country | Ref. |
---|---|---|---|---|---|---|
1 | Petrostep-B100 | Synthetic | carbonate | Cretaceceous upper Edwards | USA | [60] |
2 | Polyoxyethylene alcohol | Synthetic | carbonate | The cottonwood creek | [61,62] | |
3 | A combination of petroleum sulfonate and alkylaryl ether sulphate | Synthetic | Bob slaughter block | [63] | ||
4 | Non-ionic ethoxy alcohol | Green | carbonate | Yates field | [61] | |
5 | ORS-4l | Synthetic | sandstone | Tanner | [64] | |
6 | Petroleum sulfonate, lignosulfonate, alkyl benzene sulfonate (ABS), petroleum carboxylate, bio-surfactant | Synthetic, Green and Bio | sandstone | Daging | China | [65,66,67,68,69] |
7 | Petroleum sulfonate | Synthetic | sandstone | Karamay | [70,71] | |
8 | Petroleum sulfonate | Synthetic | sandstone | Viraj | India | [72] |
9 | Petrostep B-100 | sandstone | West kiehl | [73] | ||
10 | Petroleum sulonate | Synthetic | sandstone | Minas | Indonesia | [74] |
11 | carbonates | Baturaja | [75] | |||
12 | SS-6066 | Synthetic | Chihuido de la sierra negra | Argentina | [76] | |
13 | Olefin sulfonate | Synthetic | sandstone | bramberge | Germany | [77] |
Appendix A.2. Polymer Flooding in Carbonates
S/L | Polymer | Synthetic/Bio | Formation | Field | Country | Ref |
---|---|---|---|---|---|---|
1 | HPAM | Synthetic | Sandstone | North Burbank | USA | |
2 | HPAM | Synthetic | Sandstone | West Kiehli | [66] | |
3 | PAM | Synthetic | Sandstone | Cambridge Minnelusa | [78] | |
4 | PAM | Synthetic | Sandstone | Tanner | [65] | |
5 | HPAM | Synthetic | Sandstone | Tambaredjo | [79] | |
6 | HPAM | Synthetic | Sandstone | Daqing | China | [61] |
7 | HPAM | Synthetic | Sandstone | Gudong | [60] | |
8 | HPAM | Synthetic | Sandstone | Xing Long Tai | [63] | |
9 | Xanthan | Bio | Sandstone | Voador Offshore Feild | Brazil | [80] |
10 | HPAM | Synthetic | Sandstone | Viraj | India | [69] |
11 | PAM | Synthetic | Sandstone | Sanand | [70] | |
12 | HPAM | Synthetic | Sandstone | Matzen | Austria | [73] |
13 | HPAM | Synthetic | Sandstone | Pelican Lake | Canada | [79] |
14 | PAM | Synthetic | Sandstone | David Pool | [75] | |
15 | Xanthan | Bio | Sandstone | Eddesse-Nord | Germany | [80] |
16 | Hydroxyethylcellulose (HEC) | Bio | Sandstone | Russia Romashkino Field | Russia | [76,80] |
Appendix A.3. SP Flooding in Carbonates
SP or ASP | Synthetic/Bio/Green | Field and Country | Formation | Oil Recovery % | Ref. |
---|---|---|---|---|---|
S: Petroleum sulfonate and alkyl ether sulfate P: PAM | Synthetic | Wichita County Regular Gunsight reservoir, Texas, USA | Carbonate | 22.0 | [81] |
S: Petroleum sulfonates and Alkyl ether sulfate P: PAM | Synthetic | Wesgum field Smackover reservoir, Arkansas, USA | Carbonate | 26.7 | [82] |
S: Alkyl ether sulfates and Witco petroleum sulfonate | Synthetic | Bob slaughter block lease San andres reservoir, Wyming, USA | Carbonate | 12.0 | [63] |
Na2CO3 and anionic polymers | Synthetic | Isenhour, Wyming, USA | Carbonate | 26.4 | [83] |
A: Na2CO3 S: Petrostep B-100 P: Alcoflood1175A | Synthetic | Cambridge Minnelusa, Wyming, USA | Carbonate | 36.0 | [78] |
S: nonionic ethoxy alcohol (Shell 91-8) and Stepan CS-460 anionic ethoxy sulfate surfactant | Synthetic | Yates field, san andres reservoir, Texas, USA | Carbonate | 15.0 | [84,85] |
S: Nonionic polyoxyethylene alcohol (POA) | Synthetic | Cottonwood Creek field, Wyming, USA Bighorn basin | Carbonate | 10.4 | [31,32] |
A: Sodium carbonate alkaline solution S: 0.5% of surfactants in 200 gallons per ft of diesel oil and 0.5% of surfactants in 55 gallons per ft of xylene. | Synthetic | Mauddud carbonate reservoir, Bahrain | Carbonate | 10–15 | [86] |
S: Nonionic surfactants | Synthetic | Semoga field, baturaja Formation, Indonesia | Carbonate | 58,000 bbl per month | [70] |
SP or ASP Formulation | Synthetic/Bio/Green | Reservoir | Permeability (mD) | Oil Recovery % | Ref. |
---|---|---|---|---|---|
Amphoteric petrostep B-100 surfactant and pusher 700E Polymer and sodium tripolyphosphate and sodium carbonate alkali. | Synthetic | Cretaceous Upper Edwards Reservoir Carbonate Formations From central Texas | 75 | 45 | [60] |
Cationic surfactants of the type tetra alkyl ammonium Anionic surfactants | Synthetic | Outcrop chalk From stevns Klint Copenhagen | 2–7 | 10–75 | [87] |
Anionic (ethoxylated and propoxylated sulfate) surfactants and sodium carbonate alkali mixture. | Synthetic | Dolomite cores | 40–122 | 40–50 | [21] |
Nonionic ethoxy alcohol surfactants | Synthetic | Dolomite cores | - | [88] | |
Anionic ethoxylated and propoxylated sulfate surfactants Cationic (CTAB) surfactants | Synthetic | Calcite, Lithographic Limestone, Marble Dolomite plates | 35–55 | [89] | |
Cationic C12TAB surfactants | Synthetic | Outcrop chalk from Stvens Klint Copenhagen | 1–3 | 50–90 | [90] |
Cationic C12TAB surfactants | Synthetic | Outcrop chalk | 2–3 | 20–60 | [91] |
Five anionic (sulfonate, disulfonate and sulfate) surfactants | Synthetic | Calcites plates limestones cores | 15 | 60–75 | [92] |
Anionic (sulfonate, disulfonate and sulfate) surfactants | Synthetic | Calcites plates limestones cores | 15 | 30–50 | [93] |
Two anionic surfactants (ethoxylated sulfonate: AV-70, AV-150) Three nonionic surfactants (NP ethoxylate, 15-s-ethoxylate, TDA 30EO) Four cationic surfactants (CTAB, DTAB, Arquad C-50, Arquad T-50) surfactants | Synthetic | Limestone | 70–80 | [94] | |
Anionic surfactants: alkyl propoxy sulfates and their blends with internal olefin sulfonates, alkyl xylene sulfonates | Synthetic | Silurian dolomite outcrop cores | 195 | 26–80 | [95] |
Two anionic and two nonionic surfactants | Synthetic | Siliceous and carbonate shale cores | - | [96] | |
Anionic Guerbet alkoxy carboxylate (GAC) surfactants | Synthetic | Silurian dolomite (478 mD) Estaillade limestone core | 478 and 187 | 90–94.5 | [97] |
Nonionic branched nonylphenol ethoxylates (Huntsman SURFONICS N-120 & Huntsman SURFONICS N-150) and branched isotridecyl ethoxylate (Huntsman SURFONICS TDA-9) surfactants | Synthetic | SACROC carbonate cores | 13–16 | - | [98] |
Appendix B. Core Properties Measurement
Appendix B.1. Properties and Calculation Procedure of Core Sample 4
Appendix B.2. Pore Volume
Appendix B.3. Porosity
Appendix B.4. Permeability
Flow Rate (cc/min) | Inlet Pressure (psi) | Outlet Pressure (psi) | Permeability (mD) |
---|---|---|---|
4 | 1017.4 | 1012.3 | 205.49 |
3 | 1040.4 | 1036 | 178.67 |
2 | 1051.3 | 1048.8 | 149.71 |
1 | 1099.7 | 1098.7 | 262.00 |
Appendix B.5. Saturation
PV (mL) | Brine Produced (mL) | Tube Volume (mL) | Brine Produced from Core (mL) | Soi | Swi |
---|---|---|---|---|---|
32 | 28 | 11 | 17 | 0.53 | 0.47 |
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Salinity (%) | Initial Vol of Oil (mL) | Initial Vol of Slug (mL) | Final Oil Volume (mL) | Final Vol of Slug (mL) | Vol of Microemulsion (mL) | Phase Position |
---|---|---|---|---|---|---|
0.00 | 4.50 | 4.50 | 5.50 | 0 | 3.50 | Upper |
1.00 | 4.50 | 4.50 | 1.50 | 3.00 | 4.50 | Upper |
2.00 | 4.50 | 4.50 | 3.80 | 1.00 | 4.20 | Upper |
3.00 | 4.50 | 4.50 | 1.10 | 3.40 | 4.50 | Upper |
4.00 | 4.50 | 4.50 | 3.10 | 3.00 | 2.90 | Middle |
5.00 | 4.50 | 4.50 | 1.60 | 3.70 | 3.70 | Middle |
6.00 | 4.50 | 4.50 | 1.00 | 4.50 | 3.50 | Lower |
7.00 | 4.50 | 4.50 | 3.20 | 4.30 | 1.50 | Lower |
Core Plug | Length (cm) | Diameter (cm) | Pore Volume (CC) | Dry Weight (gm) | Porosity (%) | Permeability (mD) Ka |
---|---|---|---|---|---|---|
C1 | 15.09 | 3.79 | 32 | 398.80 | 18.91 | 102.00 |
C2 | 15.5 | 3.80 | 33.24 | 400.16 | 19.94 | 91.16 |
C3 | 15.24 | 3.81 | 33.2 | 368.60 | 19.10 | 121.58 |
C4 | 15.24 | 3.81 | 32 | 372.38 | 18.40 | 185.97 |
C5 | 15.02 | 3.78 | 30.32 | - | 17.80 | 190.00 |
S6 | 15.05 | 3.79 | 35.04 | 355.45 | 20.17 | 124.2 |
S7 | 15.18 | 3.80 | 35.14 | 358.84 | 20.22 | 129.02 |
Sample No. | Concentration (%) | IFT (dyne/cm) |
---|---|---|
1 | 2% NaCl | 23.00 |
2 | 0.5% APG + 2% NaCl | 0.285 |
3 | 0.5% APG + 0.2% Formic Acid + 2% NaCl | 0.190 |
4 | 0.5% APG + 0.4% Formic Acid + 2% NaCl | 0.266 |
5 | 0.5% APG + 0.6% Formic Acid + 2% NaCl | 0.220 |
6 | 0.5% APG + 0.8% Formic Acid + 2% NaCl | 0.250 |
7 | 0.5% APG + 1.0% Formic Acid + 2% NaCl | 0.200 |
Sample No. | Concentration of Acetone/Butanone/Formic Acid (%) | IFT (dyne/cm) | ||
---|---|---|---|---|
Acetone | Butanone | Formic Acid | ||
1 | 0 | 23 | 23 | 23 |
2 | 0.1 | 0.31 | 0.31 | 0.29 |
3 | 0.2 | 0.3 | 0.25 | 0.19 |
4 | 0.4 | 0.37 | 0.24 | 0.27 |
5 | 0.6 | 0.2 | 0.25 | 0.22 |
6 | 0.8 | 0.25 | 0.25 | 0.25 |
7 | 1 | 0.25 | 0.25 | 0.2 |
Formulation 1: 0.5% APG + 0.6% Acetone + 1000 mg/L XG + 2% NaCl Water | ||||||||
---|---|---|---|---|---|---|---|---|
Core | PV (cc) | Oil Volume (cc) | Soi (%) | Water Flood Recovery | S.P. Flood Recovery | Total | ||
cc | % | cc | % | % | ||||
C1 | 32 | 17 | 52.6 | 7.8 | 46 | 1.43 | 8.44 | 54.44 |
Formulation 2: 0.5% APG + 0.6% Butanone + 1000 mg/L XG + 2% NaCl Water | ||||||||
---|---|---|---|---|---|---|---|---|
Core | PV (cc) | Oil Volume (cc) | Soi (%) | Water Flood Recovery | S.P. Flood Recovery | Total | ||
cc | % | cc | % | % | ||||
C2 | 33.24 | 17 | 51.14 | 7.96 | 46.82 | 7.21 | 22.59 | 69.41 |
Formulation 3: 0.4% Acrylic Acid + 0.5% APG + 1000 mg/L XG + 2% NaCl Water Formulation 4: 0.5% Acrylic Acid + 0.5% APG + 1000 mg/L XG + 2% NaCl Water | ||||||||
---|---|---|---|---|---|---|---|---|
Core | PV (cc) | Oil Volume (cc) | Soi (%) | Water Flood Recovery | S.P. Flood Recovery | Total | ||
cc | % | cc | % | % | ||||
C3 | 33.24 | 17 | 51.2 | 7.514 | 44.20 | 2.02 | 11.86 | 56.06 |
C4 | 33 | 17 | 53.1 | 7.95 | 46.75 | 1.93 | 11.35 | 58.10 |
Formulation 5: 0.5% Acrylic Acid + 0.5% Butanol + 0.5% APG + 1000 mg/L XG + 2% NaCl | ||||||||
---|---|---|---|---|---|---|---|---|
Core | PV (cc) | Oil Volume (cc) | Soi (%) | Water Flood Recovery | S.P. Flood Recovery | Total | ||
cc | % | cc | % | % | ||||
C5 | 30.4 | 18.4 | 61 | 7.54 | 41 | 3.22 | 18 | 59 |
Core | Formulation | Water Flood Recovery (%) | S.P. Flood Recovery (%) | Total (%) |
---|---|---|---|---|
C1 | 0.6% Acetone + 0.5% APG + 1000 mg/L XG + 2% NaCl | 46 | 8.44 | 54.44 |
C2 | 0.6% Butanone + 0.5% APG + 1000 mg/L XG + 2% NaCl | 46.82 | 22.59 | 69.41 |
C3 | 0.4% Acrylic Acid + 0.5% APG + 1000 mg/L XG + 2% NaCl | 44.20 | 11.86 | 56.06 |
C4 | 0.5% Acrylic Acid + 0.5% APG + 1000 mg/L XG + 2% NaCl | 46.75 | 11.35 | 58.10% |
C5 | 0.5% Acrylic Acid + 0.5% Butanol + 0.5% APG + 1000 mg/L XG + 2% NaCl | 41 | 18 | 59 |
Formulation 6: 0.5% Formic Acid + 0.5% APG + 1000 mg/L XG + 2% NaCl Water Formulation 7: 0.5% Acetic Acid + 0.5% APG + 1000 mg/L XG + 2% NaCl Water | ||||||||
---|---|---|---|---|---|---|---|---|
Core | PV (cc) | Oil Volume (cc) | Soi (%) | Water Flood Recovery | S.P. Flood Recovery | Total | ||
cc | % | cc | % | % | ||||
S6 | 35.04 | 59.93 | 42.2 | 12.9 | 55 | |||
S7 | 35.14 | 59.75 | 42.7 | 15.7 | 58.7 |
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Haq, B. Green Enhanced Oil Recovery for Carbonate Reservoirs. Polymers 2021, 13, 3269. https://doi.org/10.3390/polym13193269
Haq B. Green Enhanced Oil Recovery for Carbonate Reservoirs. Polymers. 2021; 13(19):3269. https://doi.org/10.3390/polym13193269
Chicago/Turabian StyleHaq, Bashirul. 2021. "Green Enhanced Oil Recovery for Carbonate Reservoirs" Polymers 13, no. 19: 3269. https://doi.org/10.3390/polym13193269
APA StyleHaq, B. (2021). Green Enhanced Oil Recovery for Carbonate Reservoirs. Polymers, 13(19), 3269. https://doi.org/10.3390/polym13193269