Discussion of the feasibility of spontaneous ignition, oil requirement, and air requirement for air injection in shale and tight reservoirs

Jiaping Sheng , Erlong Yang , Siyuan Huang , Chaofan Zhu , Weiyu Tang

Petroleum ›› 2025, Vol. 11 ›› Issue (1) : 94 -101.

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Petroleum ›› 2025, Vol. 11 ›› Issue (1) :94 -101. DOI: 10.1016/j.petlm.2024.12.001
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Discussion of the feasibility of spontaneous ignition, oil requirement, and air requirement for air injection in shale and tight reservoirs
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Abstract

Because of the nature of low permeability of shale and tight reservoirs, a gas injection method has the advantage of enhancing oil recovery. Among gases, air has its vast and free resources. And one extra benefit is its thermal effect resulting from combustion. However, issues of feasibility of spontaneous ignition, oil requirement, and air requirement for the continuation of combustion in shale and tight reservoirs need to be addressed. This paper is to address these issues with the aid of numerical simulation. The relevant literature information is reviewed when discussing these issues. It is found that failure of spontaneous ignition may be caused by more factors such as vaporization, fuel displacement by air, etc., in addition to lack of oil exothermicity and heat loss that are commonly believed; the oil saturation difference between the initial oil saturation and the remaining oil saturation after air flooding and low-temperature oxidation is proposed to define the oil content; air requirement may not be satisfied in typical shale or tight reservoirs because of the low injectivity. More factors can complicate the issues of feasibility of spontaneous ignition, oil requirement, and air requirement. Therefore, a simulation approach is more appropriate to address those issues.

Keywords

Spontaneous ignition / Oil requirement / Air requirement / Air injection / Combustion

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Jiaping Sheng, Erlong Yang, Siyuan Huang, Chaofan Zhu, Weiyu Tang. Discussion of the feasibility of spontaneous ignition, oil requirement, and air requirement for air injection in shale and tight reservoirs. Petroleum, 2025, 11(1): 94-101 DOI:10.1016/j.petlm.2024.12.001

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CRediT authorship contribution statement

Jiaping Sheng: Writing-original draft, Visualization, Validation, Supervision, Methodology, Investigation, Formal analysis, Data curation, Conceptualization. Erlong Yang: Writing-review & editing, Resources, Project administration. Siyuan Huang: Writing-review & editing, Software, Data curation. Chaofan Zhu: Writing-review & editing, Resources, Data curation. Weiyu Tang: Writing-review & editing, Visualization, Validation, Data curation.

Declaration of competing interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Acknowledgements

The work presented in this paper is supported by the National Natural Science Foundation of China (No. 51974334), the CNPC Innovation Found (Grant No. 2021DQ02-0202), the Local Universities Reform and Development Personnel Training projects from the Central Authorities, and the Study on nanosystem displacement method of tight reservoir in Daqing Oilfield.

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

C.F. Gates, H.J. Ramey, Field results of South Belridge thermal recovery experiment, Petroleum Transaction, AIME 203 (1958) 236-244.
[2]

D. Gutierrez, A.R. Taylor, V. Kumar, M.G. Ursenbach, R.G. Moore, S.A. Mehta, Recovery factors in high-pressure air injection projects revisited, SPEREE 11 (6) (2008) 1097-1106, https://doi.org/10.2118/108429-PA.
[3]

D. Gutierrez, R.J. Miller, A.R. Taylor, P. Thies, V. Kumar, Buffalo field high-pressure air injection projects 1977 to 2007: technical performance and operational challenges, SPEREE 12 (4) (2009) 542-550.
[4]

V.K. Kumar, D. Gutierrez, R.G. Moore, S.A. Mehta,Case history and appraisal of the West Buffalo Red River Unit high-pressure air injection project, Paper, in: SPE 107715 Presented at the Hydrocarbon Economics and Evaluation Symposium Held in Dallas, 2007. Texas, UAS, 1-3 April.
[5]

B. Niu, S. Ren, Y. Liu, D. Wang, L. Tang, B. Chen, Low-temperature oxidation of oil components in an air injection process for improved oil recovery, Energy Fuels 25 (10) (2011) 4299-4304.
[6]

M. Greaves, S.R. Ren, T.X. Xia,New air injection technology for IOR operations in light and heavy oil reservoirs, Paper, in: SPE 57295 Presented at the SPE Asia Pacific Improved Oil Recovery Conference Held in Kuala Lumpur, 1999. Malaysia, 25-26 October.
[7]

C. Chu, J. Petrol. State-of-the-Art review of fire flood field projects, Technol. 34 (1) (1982) 19-36, https://doi.org/10.2118/9772-PA.
[8]

C.A. Christopher, Air injection for light and medium gravity reservoirs, Paper presented at the, in: DTI Share Meeting (1) Held in London, 1995, 20 July.
[9]

D.V. Yannimaras, D.L. Tiffin, Screening of oils for in-situ combustion at reservoir conditions via accelerating rate calorimetry, SPE RE 10 (1) (1995) 36-39, https://doi.org/10.2118/27791-PA.
[10]

S.A. Abu-Khamsin, A. Iddris, M.A. Aggour, The spontaneous ignition potential of a super-light crude oil, Fuel 80 (10) (2001) 1415-1420.
[11]

H. Jia, J.Z. Zhao, W.F. Pu, Y.M. Li, Z.T. Yuan, C.D. Yuan, Laboratory investigation on the feasibility of light-oil autoignition for application of the high-pressure air injection (HPAI) process, Energy Fuels 26 (9) (2012) 5638-5645.
[12]

C. Clara, M. Durandeau, G. Quenault, T.-H. Nguyen, Laboratory studies for light-oil air injection projects: potential application in handil field, SPEREE 3 (3) (2000) 239-248, https://doi.org/10.2118/64272-PA.
[13]

S. Huang, J.J. Sheng, An innovative method to build a comprehensive kinetic model for air injection using TGA/DSC experiments, Fuel 210 (2017) 98-106.
[14]

J.D.M. Belgrave, R.G. Moore, M.G. Ursenbach, D.W. Bennion, A comprehensive approach to in-situ combustion modeling, SPE Adv. Technol. 1 (1) (1993) 98-107.
[15]

S. Huang, J.J. Sheng, Discussion of thermal experiments' capability to screen the feasibility of air injection, Fuel 195 (2017) 151-164.
[16]

H. Jiang, J. Yang, J. Huang, W. Lv, J. Tang, Q. Xu, Y. Han, L. Shi, Heat release model for the low temperature oxidation of heavy oils from experimental analyses and numerical simulations, Energy Fuels 33 (5) (2019) 3970-3978.
[17]

L. Wang, L. Tang, L. Zhang, Q. Duan, Z. Chen, Study on low-temperature oxidation experiments and kinetics model for heavy oil, Appl. Chem. Ind. 42 (2) (2013) 259-263.
[18]

B. Sequera, R.G. Moore, S.A. Mehta, M.G. Ursenbach, Numerical simulation of in-situ combustion experiments operated under low temperature conditions, J. Can. Petrol. Technol. 49 (1) (2010) 55-64.
[19]

L. Shi, C. Xi, P. Liu, X. Li, Z. Yuan, In fill wells assisted in-situ combustion following SAGD process in extra-heavy oil reservoirs, J. Petrol. Sci. Eng. 157 (2017) 958-970.
[20]

L. Shi, Q. Xu, Fundamental research and application of air injection technology in heavy oil reservoirs, J. Tsinghua Univ. (Sci. Technol.) 62 (4) (2022) 722734.
[21]

S. Zhao, W. Pu, M. Varfolomeev, C. Yuan, J. Zhang, X. Han, Y. Yang, X. Peng, J. Wu, Comprehensive investigations into low temperature oxidation of heavy crude oil, J. Petrol. Sci. Eng. 171 (2018) 835-842.
[22]

Y. Chen, H. Yin, D. He, H. Gong, Z. Liu, Y. Liu, X. Zhang, W. Pu, Low temperature oxidized coke of the ultra-heavy oil during in-situ combustion process: structural characterization and evolution elucidation, Fuel 313 (2022) 122676.
[23]

Y. Chen, W. Pu, X. Liu, Y. Li, M. Varfolomeev, J. Hui, A preliminary feasibility analysis of in situ combustion in a deep fractured-cave carbonate heavy oil reservoir, J. Pet. Sci. Eng. 174 (2019) 446-455.
[24]

Y. Zhang, J.J. Sheng, The mechanism of the oxidation of light oil, Petrol. Sci. Technol. 35 (12) (2017) 1224-1233.
[25]

D.A. Frank-Kamenetskii, Towards temperature distributions in a reaction vessel and the stationary theory of thermal explosion, Dokl. Akad. Nauk SSSR 18 (1938) 411-412, 1938.
[26]

D.A. Frank-Kamenetskii, Ignition and extinction of solid surfaces, Dokl. Akad. Nauk SSSR, Ser. A 30 (1941) 734-737, 1941.
[27]

F. Restuccia, N. Ptak, G. Rein, Self-heating behavior and ignition of shale rock, Combust. Flame 176 (2017) 213-219, 2017.
[28]

B.F. Gray, Spontaneous combustion and self-heating, in: M. New York USA, SFPE Handbook of Fire Protection Engineering, 2016, pp. 604-632.
[29]

L. Yang, J.J. Sheng, Feasibility of using the Frank-Kamenetskii theory to predict the spontaneous ignition of the crude Oil-Sand mixture, Energy Fuels 33 (2019) 4816-4825.
[30]

T.W. Nelson, J.S. McNeil, How to engineer an in situ combustion project, Oil Gas J. 69 (23) (1961) 58-65.
[31]

C.F. Gates, H.J. Ramey, A method for engineering in-situ combustion oil recovery projects, J. Petrol. Technol. (1980) 285-294. February.
[32]

B. Hughes, H.K. Sarma, Burning reserves for greater recovery? Air injection potential in Australian light oil reservoirs, Paper, in: SPE 101099 Presented at the SPE Asia Pacific Oil & Gas Conference and Exhibition Held in Adelaide, 2006, https://doi.org/10.2118/101099-MS. Australis,11-13September.
[33]

W.E. Showalter, Combustion-drive tests, SPE J. (March) (1963) 53-58.
[34]

R. Kharrat, S. Vossoughi, Feasibility study of the in-situ combustion process using TGA/DSC techniques, JPT (August) (1985) 1441-1445.
[35]

M.R. Fassihi, A.R. Kovscek, Low-Energy Processes for Unconventional Oil Recovery, Society of Petroleum Engineers, Richardson, Texas, USA, 2017.
[36]

J. Tingas, Numerical Simulation of Air Injection Processes in High Pressure Light & Medium Oil Reservoirs, PhD dissertation, University of Bath, Somerset, England, 2000.
[37]

W.L. Martin, J.D. Alexander, J.N. Dew, Process variables of in situ combustion, Petroleum Transactions, AIME 213 (1958) 28-35.
[38]

Y. Barzin, R.G. Moore, S.A. Mehta, M.G. Ursenbach, F. Tabasinejad, Impact of distillation on the combustion kinetics of high pressure air injection (HPAI), Paper, in: SPE 129691 Presented at the SPE Improved Oil Recovery Symposium Held in Tulsa, 2010, https://doi.org/10.2118/129691-MS. Oklahoma, USA, 24-28April.
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