Semi-analytical model for the interpretation of oil reservoir tracer test data: Solution of a direct problem for low resistance channels

Authors

DOI:

https://doi.org/10.7242/1999-6691/2024.17.1.2

Keywords:

tracer tests, low resistance channel, objective with small parameters, splitting of the solution, semi-analytical model, mass conservation law, solution verification

Abstract

The article considers the problem of interpretation of tracer tests in oil reservoirs, into which a specific chemical substance - tracer - is injected via an injection well for flow monitoring and tracer concentration measurements in surrounding production wells. The testing data provide evidence of the existence of low resistance channels in the reservoirs, along which the tracer moves at velocities several orders of magnitude higher than in the reservoir. The nature and properties of these channels are unknown, and a semi-analytical model involving two small parameters is proposed to solve this problem. This makes it possible to construct two non-conjugate solutions: universal numerical and analytical. Such an approach allows us to solve both direct and inverse problems. The present article is devoted to solving the direct problem. The problem of pressure distribution in a rectangular reservoir pattern is solved in dimensionless coordinates and is universal, i.e., it does not depend on the size of the area and the pressure drop. This solution is approximated by power functions and is further used to determine the mass transfer between channel and reservoir. The problem of tracer slug propagation through the channel obeys the law of conservation of tracer mass and Darcy's law. Its solution is found by the methods of characteristics under the condition of smallness of the parameter reflecting the ratio of reservoir permeability to channel permeability. The results of the semi-analytical solution are compared with the numerical solutions previously obtained by other authors. The fundamental difference between these solutions is the presence of numerical diffusion when using the finite-difference method of solution, which leads to the «dissipation» of the trace slug edges.

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References

Safarov F.E., Vezhnin S.A., Vulfovich S.L., Ismagilov O.Z., Malykhin V.I., Isaev A.A., Takhautdinov R.S., Telin A.G. Tracer tests and conformance control in the well of Dachnoye field. Neftyanoe khozyaystvo - Oil Industry. 2020. No. 4. P. 38–43. DOI: 10.24887/0028-2448-2020-4-38-43.

Manasyan A.E., Zhuravlev D.A., Kozlov A.N. Experience of using tracer studies of DIII formation of Zapadno-Kommunarskoe oilfield. Oilfield Engineering. 2018. No. 9. P. 41–47. DOI: 10.30713/0207-2351-2018-9-41-47.

Diaghilev V.F., Kononenko A.A., Leontiev S.A. Analysis of the results of tracerial studies on the example of the UV11 of Chistine deposit. Advances in current natural sciences. 2018. No. 1. P. 93–101.

Sokolovskiy E.V., Solovyev G.B., Trenchikov Y.I. Indikatornyye metody izucheniya neftenosnykh plastov. Moscow: Nedra, 1986. 157 p.

Konev D.A. Issledovaniye neftyanykh plastov s pomoshchyu indikatornogo metod. Modern high technologies. 2014. No. 7–2.

P. 23–26.

Beier R.A., Sheely C.Q. Tracer Surveys To Identify Channels for Remedial Work Prior to CO2 Injection at MCA Unit, New Mexico. Society of Petroleum Engineers and US Department of Energy Enhanced Oil Recovery Symposium, Tulsa, USA, 17–20 April 1988. 1988. P. 1–10. DOI: 10.2118/17371-MS.

Lichtenberger G.J. Field Applications of Interwell Tracers for Reservoir Characterization of Enhanced Oil Recovery Pilot Areas. Production Operations Symposium, Oklahoma City, USA, 7–9 April 1991. 1991. P. 1–17. DOI: 10.2118/21652-MS.

Zecheru M., Goran N. The use of chemical tracers to water injection processes applied on Romanian reservoirs. EPJ Web of Conferences. 2013. Vol. 50, no. 02005. P. 02005. DOI: 10.1051/epjconf/20135002005.

Pavlov I.V., Mozgovoy G.S. Tracer methods fof identification and monitoring of fluids inflow into producing wells. Neft. Gas. Novacii. 2020. No. 1. P. 63–66.

Guryanov A., Katashov A., Ovchinnikov K. Diagnostics and monitoring of well inflows using tracers on quantum dots. Coiled Tubing Times. 2017. No. 2. P. 42–51.

Ovchinnikov K.N., Kotenev Y.A., Sultanov S.K., Chibisov A.V., Chudinova D.Y. Regulation of hydrocarbon production process based on dynamic tracer monitoring of horizontal well inflow profile. Georesursy. 2022. Vol. 24, no. 4. P. 126–137. DOI: 10.18599/grs.2022.4.11.

Deans H. Method of determining fluid saturation in reservoirs. 1971. US Patent No. 3623842.

AlAbbad M.A., Sanni M.L., Kokal S., Krivokapic A., Dye C., Dugstad Ø., Hartvig S.K., Huseby O.K. A Step Change for Single-Well Chemical-Tracer Tests: Field Pilot Testing of New Sets of Novel Tracers. SPE Reservoir Evaluation & Engineering. 2018. Vol. 22, no. 1. P. 253–265. DOI: 10.2118/181408-PA.

Mechergui A., Agenet N., Romero C., Nguyen M., Batias J. Design, Operation, and Laboratory Work for Single-Well Tracer Test Campaign in Handil Field Indonesia. SPE Enhanced Oil Recovery Conference, Kuala Lumpur, Malaysia, 2–4 July 2013. 2013.

P. 1–13. DOI: 10.2118/165227-MS.

Mukhutdinova A.R., Bolotov A.V., Anikin O.V., Varfolomeev M.A. Algorithm for estimating boundary conditions of a distributed tracer for application in a single-well tracer test. Georesursy. 2022. Vol. 24, no. 4. P. 75–81. DOI: 10.18599/grs.2022.4.6.

Tarasov M.G., Volkov V.N., Sianisyan E.S., Trunov N.M. On forming technogenous hydrodynamic system when producing oil-fields. Actual Problems of Oil and Gas. 2015. No. 2. P. 1–8. DOI: 10.29222/ipng.2078-5712.2015-12.art9.

Victorin V.D. Vliyaniye osobennostey karbonatnykh kollektorov na effektivnost’ razrabotki neftyanykh zalezhey. Moscow: Nedra, 1988. 149 p.

Khisamov R.S., Fayzullin I.N., Kubarev P.N., Antonov G.P., Galimov I.F. Tracer tests to study properties of fractured reservoirs developed by water drive with forced fluid withdrawal. Neftyanoe khozyaystvo - Oil Industry. 2011. No. 7. P. 36–39.

Izotov A.A., Sokolov S.V. The reasonability of a smooth start of injection wells. Exposition Oil and Gas. 2021. No. 1. P. 40–44. DOI: 10.24412/2076-6785-2021-1-40-44.

Izotov A.A., Afonin D.G. The technogenic transformation of productive formations due to the increased discharge pressure during flooding. Oilfield Engineering. 2021. No. 5. P. 18–25. DOI: 10.33285/0207-2351-2021-5(629)-18-25.

Pavlov V., Korelskiy E., Butula K.K., Kluybin A., Maximov D., Zinovyev A., Zadvornov D., Grachev O. 4D Geomechnical Model Creation for Estimation of Field Development Effect on Hydraulic Fracture Geometry. SPE Russian Petroleum Technology Conference and Exhibition, Moscow, Russia, 24–26 October 2016. 2016. P. 1–17. DOI: 10.2118/182020-MS.

Asalkhuzina G.F., Davletbaev A.Y., Fedorov A.I., Yuldasheva A.R., Efremov A.N., Sergeychev A.V., Ishkin D.Z. Identification of Refracturing Reorientation using Decline-Analysis and Geomechanical Simulator. SPE Russian Petroleum Technology Conference, Moscow, Russia, 16–18 October 2017. 2017. P. 1–11. DOI: 10.2118/187750-MS.

Kuzmina S., Butula K.K., Nikitin A. Reservoir Pressure Depletion and Water Flooding Influencing Hydraulic Fracture Orientation in Low-Permeability Oilfields. SPE European Formation Damage Conference, Scheveningen, The Netherlands, 27–29 May 2009. 2009. P. 1–18. DOI: 10.2118/120749-MS.

Zazovsky A.F. Propellant fracturing revisited. Proceedings of the 6th North America Rock Mechanics Symposium, Gulf Rocks, USA, 5–9 June 2004. 2004.

Bulygin D.V., Nikolaev A.N., Elesin A.V. Hydrodynamic evaluation of the efficiency of flow deflecting technologies in conditions of formation of man-made filtration channels. Georesursy. 2018. Vol. 20, no. 3. P. 172–177. DOI: 10.18599/grs.2018.3.172- 177.

Kireev T.F., Bulgakova G.T. Interpretation of interwell tracer tests using discrete fracture model. Computational Continuum Mechanics. 2018. Vol. 11, no. 3. P. 252–262. DOI: 10.7242/1999-6691/2018.11.3.19.

Samarskiy A.A., Gulin A.V. Chislennyye metody. Moscow: Nauka, 1989. 432 p.

Barenblatt G.I., Entov V.M., Ryzhik V.M. Theory of fluid flows through natural rocks. Dordrecht: Kluwer Academic Publishers, 1990. 396 p.

Anisimov L.A., Kilyakov V.N., Vorontsova I.V. The Use of Tracers for Reservoir Characterization. SPE Middle East Oil and Gas Show and Conference, Manama, Bahrain, 15–18 March 2009. 2009. P. 1–8. DOI: 10.2118/118862-MS.

Eldaoushy A.S., Al-Ajmi M., Ashkanani F. Utilization of Interwell Water Tracer to Study Subsurface Flow of the Injected Water and Optimize Waterflood in Mauddud Carbonate Reservoir, Raudhatain Field, North Kuwait. SPE Kuwait Oil and Gas Show and Conference, Mishref, Kuwait, 11–14 October 2015. 2015. P. 1–12. DOI: 10.2118/175200-MS.

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Published

2024-05-12

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Vol. 17 No. 1 (2024)

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Articles

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How to Cite

Fedorov, K. M., Gilmanov, A. Y., Shevelev, A. P., Izotov, A. A., & Kobyashev, A. V. (2024). Semi-analytical model for the interpretation of oil reservoir tracer test data: Solution of a direct problem for low resistance channels. Computational Continuum Mechanics, 17(1), 15-23. https://doi.org/10.7242/1999-6691/2024.17.1.2