Carbon dioxide injection into the Achimov formations using reinjection technology by the example of Ach_3-4 formation in the Novo-Urengoy area of the Urengoy field

   The prerequisites for the study are the calculation results for the cycling process, where carbon dioxide is proposed as the injection agent into the Achimov formations instead of dry gas, with the goal of increasing the condensate recovery factor.

   The work is focused on the efficiency assessment of carbon dioxide reinjection technology and reducing carbon footprint at a late stage of field development.

   The research object is the Аch_3-4 formation within the Novo-Urengoy license area of the Urengoy field.

   The leading method to identify this problem is the results of the full-scale composite dynamic model in the ECLIPSE 300 format.

   The model takes into account the history of field development on depletion. The articles deals with two schemes for injecting carbon dioxide into the formation. In the first scheme, pure carbon dioxide is injected in a closed-loop system, but carbon neutrality through storage is not achieved. In the second scheme, carbon dioxide is injected using reinjection technology. Once injection begins, gas production stops. Only the condensate separated from the formation gas during low-temperature separation is sold and sent for further processing. After allocation of the condensate, the mixture of natural gas and carbon dioxide, in a specific proportion, is sent to the compressor station for reinjection into the formation in a gaseous state. Injecting pure carbon dioxide achieves a condensate recovery factor similar to that of gas injection with a 30 % carbon dioxide mixture. However, this option is less economically viable compared to the base and other scenarios due to high capital costs for upgrading the existing gas processing equipment (requiring the construction of an amine treatment unit). With carbon dioxide injection using reinjection technology, in addition to recovering extra condensate that had condensed during natural depletion, a reduction in the carbon footprint is also achieved. To maximize the condensate recovery factor, the optimal concentration of carbon dioxide in the injection mixture has been determined. The optimal timing for the start of injection was identified to maximize gas recovery. Economic efficiency is expected from the additional recovery of condensate trapped in the reservoir and from achieving carbon neutrality through the monetization and storage of carbon dioxide.

1. Rusanov, А. S., Reitblat, Е. А., & Glumov, D. N. (2024). Simulating the Reservoir Pressure Maintenance Strategy by injecting HC and non-HC gases into the Achimov reservoirs. Oil and Gas Stuides, 3(165), pp. 83-99. (In Russian). DOI: 10.31660/0445-0108-2024-3-83-99

2. Klubkov, S., Emel'yanov, K., & Zotov, N. (2021). CCUS: Monetizatsiya vybrosov CO₂. (In Russian). Availale at: https://vygon-consulting.ru/upload/iblock/967/jzgys72b7ome167wi4dbao9fnsqsfj13/vygon_consulting_CCUS.pdf

3. Sklyar, V., & Tikhonova, A. (2021). ESG i dekarbonizatsiya. (In Russian). Availale at: https://www.vtbcapital.ru/upload/iblock/9da/SG_and_Decarbonisation_211129_abr_rus.pdf

4. Mirzadzhanzade, A. Kh. (1967). Teoriya i praktika razrabotki gazokondensatnykh mestorozhdeniy. Мoscow, Nedra Publ., 356 p. (In Russian).

5. Ter-Sarkisov, R. M., Gritsenko, A. I., & Shandrygin, A. N. (1996). Razrabotka gazokondensatnykh mestorozhdeniy s vozdeystviem na plast. Мoscow, Nedra Publ., 239 p. (In Russian).

6. Gurevich, G. R., Sokolov, V. A., & Shmyglya, P. T. (1976). Razrabotka gazokondensatnykh mestorozhdeniy s podderzhaniem plastovogo davleniya. Мoscow, Nedra Publ., 186 p. (In Russian).

7. Monger, T. G., Khakoo, A. (1981). The Phase Behavior of CO₂ - Applacachian Oil Systems. SPE Annual Technical Conference and Exhibition. (In English). doi: 10.2118/10269-MS

8. Filatov, V. S., & Glumov, D. N. (2022). Razrabotka kontseptsii khraneniya SO₂ na neftegazodobyvayushchikh aktivakh PAO NK "Rosneft'". Otchet o NIR. Tyumen, Tyumenskiy neftyanoy nauchnyy tsentr Publ., 86 p. (In Russian).