Carbon dioxide flooding

Carbon dioxide (CO₂) flooding is a process in which carbon dioxide is injected into an oil reservoir to increase the output when extracting oil. This is most often used in reservoirs where production rates have declined due to depletion.

Overview

 

Figure 1. Carbon dioxide pressure-temperature phase diagram

When the amount of recoverable oil in an oil reservoir is depleted through primary and secondary production, around 60 to 70% of oil that was originally in the reservoir may still remain.^[1] In some cases, carbon dioxide (CO₂) flooding may be an ideal tertiary recovery method to recover more of the recoverable oil than could be produced using secondary oil recovery methods.

Because of its special properties, CO₂ improves oil recovery by lowering interfacial tension, swelling the oil, reducing viscosity of the oil, and by mobilizing the lighter components of the oil.^[2] When the injected CO₂ and residual oil are miscible, the physical forces holding the two fluids apart effectively disappears. This results in a viscosity reduction of the hydrocarbon and makes it easier to displace the crude oil from the rock pores and sweep it to the production well.^[3]

In other cases where the CO₂ and residual oil are immiscible, the injected CO₂ may still be used to drive the crude oil through the formation to be produced.^[4] One reason this occurs is because the injected CO₂ can flow into the minute pores that are unavailable to oil and water.^[5]

Process

As an oil field matures and production rates decline, there is a growing incentive to intervene and attempt to increase oil output utilizing tertiary recovery techniques (also termed improved or enhanced oil recovery). Petroleum engineers assess available options for increasing reservoir productivity. The options include chemical flooding, thermal/steam injection, and CO₂ injection.^[2][6]

One of the criteria for determining if CO₂ flooding is a candidate for the recovery of oil from the formation is the pressure of the formation. The miscibility of the CO₂ and the crude oil is dependent upon the pressure and the temperature. However, since it is difficult to change the temperature of the reservoir, the pressure of the reservoir may be adjusted, to an extent, to bring the reservoir to a pressure that keeps the CO₂ in a supercritical state. If a miscible flood is found to be feasible, the pressure is kept above the minimum miscibility pressure (MMP).^[3][2] The pressure may be below the MMP if an immiscible flood is desired.

 

Inverted 5-spot Pattern

A petroleum engineer will then determine a method of using CO₂ flooding to recover petroleum from the reservoir. This may be a continuous injection method, a water alternating gas (WAG) method, or some combination.^[2] The amount, or amounts of CO₂ will be determined by the amount of the pore volume of the formation that is filled with oil. This is known as the hydrocarbon pore volume (HCPV).^[3] The petroleum engineer will also decide if the flood will be a pattern flood or a line drive flood.^[2][6] In a pattern flood, CO₂ is usually injected into a number of injection wells surrounding a producing well. Alternatively, CO₂ may be injected into injector wells surrounded by producing wells. This is called an inverted pattern. In a line drive, the injection wells are located in a straight line parallel to the production wells.^[7]

Optimally, a slug of CO₂ will mobilize a flood front where the mixture of oil and CO₂ will mobilize more oil.^[7][2] This flood front will radiate from each injection well towards the surrounding producing wells where the oil will be produced. The formation of a front is dependent upon the rate that the CO₂ is injected, how fast it mobilizes the oil, and the porosity of the formation.^[7] Injecting the CO₂ too fast will allow the CO₂ to channel from the injector directly to a producing well without mobilizing any oil. Injecting CO₂ too quickly may fracture the formation, which may again allow channeling from the injector to any or all of the producing wells.^[2][6][8] Also, injecting CO₂ may migrate fines, which are small particles of clay and minerals, may plug the pores and prevent the mobilization of oil through the formation.^[9]

In a continuous flood, a slug of CO₂ will be continuously injected and not followed by any other fluid. The amount of CO₂ is usually calculated to be around 100% of the HCPV of the field or pattern. In a water alternating gas (WAG) process, slugs of CO₂ are followed by slugs of water. The overall amount of CO₂ may be between 40% and 50% of the HCPV.^[2][6][8] The WAG process is known to reduce channeling of the CO₂.^[6]

Formations and Oil

 

Drilling rigs in the Permian Basin, where much of the CO2 flooding occurs in the United States.^[8]

Sandstone and carbonate reservoirs (such as limestone or dolomite) are preferred for this method over reservoirs with ultra-low permeability such as shale due to the risk of CO₂ channeling through hydraulic or natural fractures in the rock.^[2][1] CO₂ flooding is still sometimes used in these instances, but usually using the "huff and puff" CO₂ injection method, which allows the CO₂ to soak in a reservoir after being pumped in through the injection well for a period of time before the production well is opened and put back into functionality.^[10][6] This method reduces the chances of unwanted channeling, and increases the amounts of oil that may be recovered as opposed to the more common CO₂ injection water alternating gas process (WAG) or by following a soak of CO₂ with steam.^[1][11]

Miscible CO₂ flooding is a method preferred for medium to light oils due to the mobility ratio between the CO₂ and the oil.^[7] The mobility ratio refers to the ratio of the mobility of the CO₂ fluid injected into a reservoir for secondary or tertiary production versus the mobility of the oil.^[1][2][8] For medium or light oils with a high API gravity, fluids or gases that are less viscous themselves can be used. However, if an injection fluid or gas that had lower viscosity was used on a heavy crude oil or bitumen, the injection fluid or gas would bypass the oil and result in a poorly swept reservoir.^[1]

In cases where the reservoir is filled with extremely heavy oil or bitumen, steam injection, or other methods that employ heat, are much more commonly favored so that the mobility or viscosity of the oil can be lowered and the extraction will become easier.^[1] Generally, reservoirs with lighter oils will have higher recovery percentages with primary and secondary recovery methods, but reservoirs with heavier oils or bitumen will have much lower recovery with primary and secondary recovery methods and the transition from secondary to tertiary methods will have to occur much earlier in the reservoir's lifespan.

History

Using CO₂ for enhanced oil recovery was first investigated and patented in 1952.^[12] In 1964, a field test was conducted at the Mead Strawn Field, which involved the injection of a large slug of CO₂ (25% of the hydrocarbon pore volume or HCPV) followed by carbonated water at reservoir conditions. Results indicated that 53 to 82 percent more oil was produced by the CO₂ flood than was produced by water in the best areas of the waterflood.^[13]

The process was first commercially attempted in 1977 in Scurry County, Texas.^[13] Since then, the process has become extensively used in the Permian basin region of the US and is now more recently is being pursued in many different states.^[1] It is now being more actively pursued in China and throughout the rest of the world.^[2][14][15]

Sequestration of Carbon Dioxide

In connection with greenhouse gas emissions and global warming, CO₂ flooding may be used to sequester CO₂ underground and therefore offset CO₂ emissions elsewhere.^[16]

See also

• Petroleum Industry
• Supercritical carbon dioxide

References

1. Speight, James G. (2019). "Chapter 2 - Nonthermal Methods of Recovery". Heavy Oil Recovery and Upgrading. Gulf Professional Publishing. pp. 49–112. doi:10.1016/b978-0-12-813025-4.00002-7. ISBN 978-0-12-813025-4.
2. Verma, Mahendra (2015). Fundamentals of carbon dioxide-enhanced oil recovery (CO2-EOR): a supporting document of the assessment methodology for hydrocarbon recovery using CO2-EOR associated with carbon sequestration (Report). Open-File Report. doi:10.3133/ofr20151071.
3. "Carbon Dioxide Enhanced Oil Recovery" (PDF). U.S. Department of Energy. March 2010.
4. Zhang, Na; Wei, Mingzhen; Bai, Baojun (April 2018). Comprehensive Review of Worldwide CO2 Immiscible Flooding. SPE Improved Oil Recovery Conference. Tulsa, Oklahoma, USA.
5. Pingping, Shen; Xinglong, Chen; Jishun, Qin (2010). "Pressure characteristics in CO₂ flooding experiments". Petroleum Exploration and Development. 37 (2): 211–215. Bibcode:2010PEDO...37..211P. doi:10.1016/S1876-3804(10)60026-2.
6. Riley, Ronald; Harper, John; Harrison III, William; Barnes, David; Nuttall, Brandon; Avary, Katharine; Wahr, Amanda; Baranoski, Mark; Slater, Brian; Harris, David; Kelley, Stephen. Evaluation of Co2-Enhanced Oil Recovery and Sequestration Opportunities in Oil and Gas Fields in the MRCSP Region (Report). DOE-NETL.
7. Hughes, Richard (September 2009). Evaluation and Enhancement of Carbon Dioxide Flooding Through Sweep Improvement (Report). doi:10.2172/983791. OSTI 983791.
8. Kuuskraa, Vello A.; Van Leewen, Tyler; Wallace, Matt (June 2011). Improving Domestic Energy Security and Lowering CO₂ Emissions with 'Next Generation' CO₂-Enhanced Oil Recovery (CO₂-EOR) (Report). doi:10.2172/1503260.
9. Xie, Quan; Saeedi, Ali; Delle Piane, Claudio; Esteban, Lionel; Brady, Patrick (September 2017). "Fines migration during CO2 injection: Experimental results interpreted using surface forces". International Journal of Greenhouse Gas Control. 65: 32–39. Bibcode:2017IJGGC..65...32X. doi:10.1016/j.ijggc.2017.08.011. OSTI 1421635.
10. Ahmadi, Mohammad Ali (2018). "Chapter Nine - Enhanced Oil Recovery (EOR) in Shale Oil Reservoirs". In Bahadori, Alireza (ed.). Fundamentals of Enhanced Oil and Gas Recovery from Conventional and Unconventional Reservoirs. Gulf Professional Publishing. pp. 269–290. doi:10.1016/b978-0-12-813027-8.00009-6. ISBN 978-0-12-813027-8.
11. US 4,736,792  "Viscous oil recovery method"
12. US 2,623,596  "Method for producing oil by means of carbon dioxide"
13. Summary of Carbon Dioxide Enhanced Oil Recovery (CO₂EOR) Injection Well Technology (Report). American Petroleum Institute. 2007.
14. Hill, Bruce; Li, XiaoChun; Wei, Ning (2020). "CO₂-EOR in China: A comparative review". International Journal of Greenhouse Gas Control. 103: 103173. Bibcode:2020IJGGC.10303173H. doi:10.1016/j.ijggc.2020.103173. S2CID 228835796.
15. Chen, H. Q.; Hu, Y. L.; Tian, C. B. (2012). "Advances in CO2 displacing oil and CO2, sequestrated researches". Oil-Field Chemistry. 29 (1): 116–127.
16. Aminu, Mohammed D.; Nabavi, Seyed Ali; Rochelle, Christopher A.; Manovic, Vasilije (2017). "A review of developments in carbon dioxide storage". Applied Energy. 208: 1389–1419. doi:10.1016/j.apenergy.2017.09.015. hdl:1826/12765. ISSN 0306-2619.

External links

• [1] PetroWiki - Miscible flooding
• [2] PetroWiki - Enhanced Oil Recovery (EOR)