Theoretical assessment of CO2 injection into low-temperature water zones for non-leaking storage in hydrate form
Keywords:
CO2 storage, frac-pack, well injectivity, permissible pressureAbstract
Concerns exist about CO2 leaks from conventional supercritical CO2 storage reservoirs. This study investigates injecting CO2 into low-temperature offshore reservoirs to lock it in a solid state, thus preventing potential leaks. An analytical model was developed to predict CO2 injectivity into frac-packed injection wells in these low-temperature reservoirs. While the initial transient flow model was complex with Bessel functions and exponential integral, it was further simplified for practical field application. Sensitivity analysis of the model reveals that injectivity is less sensitive to reservoir permeability but more sensitive to fracture conductivity. The analytical model suggests injectivity is directly proportional to fracture width and fracture permeability. The case study utilizing field data from the South China Sea indicates feasible injection rates ranging from 6 to 17 tons/day depending on fracture conductivity. This work provides an analytical tool to predict injectivity for CO2 storage in frac-packed low-temperature offshore reservoirs, contributing to carbon reduction and neutralization goals.
Document Type: Short communication
Cited as: Guo, B., Zhang, P. Theoretical assessment of CO2 injection into low-temperature water zones for non-leaking storage in hydrate form. Advances in Geo-Energy Research, 2023, 10(1): 1-6. https://doi.org/10.46690/ager.2023.10.01
ReferencesAnya, A., Emadi, H., Watson, M. A novel apparatus and method for lab-scale study of wellbore integrity using CT imaging and analysis. Journal of Petroleum Science and Engineering, 2023, 220: 111209.
Cha, M., Shin, K., Lee, H., et al. Kinetics of methane hydrate replacement with carbon dioxide and nitrogen gas mixture using in situ NMR spectroscopy. Environmental Science & Technology, 2015, 49(3): 1964-1971.
Dake, L. P. Fundamentals of Reservoir Engineering. New York, USA, Elsevier Science, 1983.
Davies, S. R., Sloan, E. D., Sum, A. K., et al. In situ studies of the mass transfer mechanism across a methane hydrate film using high-resolution confocal Raman spectroscopy. The Journal of Physical Chemistry C, 2010, 114(2): 1173-1180.
Dawe, R. A., Thomas, S. A large potential methane source-natural gas hydrates. Energy Sources, Part A, 2007, 29(3): 217-229.
Duguid, A., Guo, B., Nygaard, R. Well integrity assessment of monitoring wells at an active CO2-EOR flood. Energy Procedia, 2017, 114: 5118-5138.
Frölicher, T. L., Winton, M., Sarmiento, J. L. Continued global warming after CO2 emissions stoppage. Nature Climate Change, 2014, 4(1): 40-44.
Gaurina-Medimurec, N., Mavar, K. N. Carbon capture and storage (CCS): Geological sequestration of CO2, in CO2 Sequestration, edited by L. A. Frazao, A. M. Silva-Olaya, J. C. Silva, IntechOpen, London, pp. 1-21, 2019.
Ghalambor, A., Ali, S. A., Norman, W. D. Frac Packing Handbook. Richardson, USA, Society of Petroleum Engineers, 2009.
Hangx, S. J. T., Linden, A., Marcelis, F., et al. Defining the brittle failure envelopes of individual reaction zones observed in CO2-exposed wellbore cement. Environmental Science & Technology, 2016, 50(2): 1031-1038.
Huang, J., Griffiths, D. V., Wong, S. W. Initiation pressure, location and orientation of hydraulic fracture. International Journal of Rock Mechanics and Mining Sciences, 2012, 49: 59-67.
Khasanov, M. K., Musakaev, N. G., Stolpovsky, M. V., et al. Mathematical model of decomposition of methane hydrate during the injection of liquid carbon dioxide into a reservoir saturated with methane and its hydrate. Mathematics, 2020, 8(9): 1482.
Kvenvolden, K. A. Gas hydrates-geological perspective and global change. Reviews of Geophysics, 1993, 31(2): 173-187.
Lamont, N., Jessen, F. W. The effects of existing fractures in rocks on the extension of hydraulic fractures. Journal of Petroleum Technology, 1963, 15(2): 203-209.
Lin, Y., Deng, K., Yi, H., et al. Integrity tests of cement sheath for shale gas wells under strong alternating thermal loads. Natural Gas Industry B, 2020, 7(6): 671-679.
Liu, C., Ye, Y., Meng, Q., et al. The characteristics of gas hydrates recovered from Shenhu Area in the South China Sea. Marine Geology, 2012, 307: 22-27.
Lu, C., Li, M., Guo, J. C., et al. Engineering geological characteristics and the hydraulic fracture propagation mechanism of the sand-shale interbedded formation in the Xu5 reservoir. Journal of Geophysics and Engineering, 2015, 12(3): 321-339.
Shaibu, R., Sambo, C., Guo, B., et al. An assessment of methane gas production from natural gas hydrates: Challenges, technology and market outlook. Advances in Geo-Energy Research. 2021, 5(3):318-32.
Soeder, D. J. Greenhouse gas sources and mitigation strategies from a geosciences perspective. Advances in Geo-Energy Research, 2021, 5(3): 274-285.
Sukor, N. R., Shamsuddin, A. H., Mahlia, T. M., et al. Technoeconomic analysis of CO2 capture technologies in offshore natural gas field: Implications to carbon capture and storage in Malaysia. Processes, 2020, 8(3): 350.
Zhang, P., Guo, B., Liu, N. Numerical simulation of CO2 migration into cement sheath of oil/gas wells. Journal of Natural Gas Science and Engineering, 2021, 94: 104085.