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Integral Simulation of Oil Displacement by Water

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Journal of Engineering Physics and Thermophysics Aims and scope

An integral model of the displacement of oil from a stratum by water has been developed, and, using it, solutions of the coupling equations defining nonstationary liquid flows in the stratum–well system with regard for the deformability of the stratum have been constructed. The results obtained allow one to determine the parameters of the waterflooding of a stratum with account of the dynamic coupling of the stratum–well system and the wellheard pressure of a production well in it.

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References

  1. L. S. Leibeizon, Underground Fluid Dynamics [in Russian], Izd. Akad. Nauk SSSR, Moscow (1953).

  2. G. S. Braginskaya and V. M. Entov, On the Nonisothermal Oil Displacement by an Active Impurity Solution, Preprint No. 112, Keldysh Inst. Prikl. Mat., Moscow (1978).

  3. G. R. Gurevich and A. F. Zazovskii, Mathematical simulation of the oil displacement by flue gas, Neft’ Gaz, No. 8, 49–54 (1987).

  4. V. M. Entov and A. F. Zazovskii, On the oil displacement by a solution of two impurities (active and passive), Mekh. Zhidk. Gaza, No. 6, 74–83 (1982).

  5. V. M. Entov and A. F. Zazovskii, On the effect of the oil displacement by a solution of an active impurity nonmonotonically influencing the distribution function of flows, Mekh. Zhidk. Gaza, No. 1, 76–82 (1986).

  6. A. F. Zazovskii, On the Oil Displacement of Solvents and Solubilizing Solutions of Surface Active Substances, Preprint No. 195, Keldysh Inst. Prikl. Mat., Moscow (1982).

  7. A. F. Zazovskii, On the influence of the local-water salts on the efficiency of the oil displacement by carbonated water, Mekh. Zhidk. Gaza, No. 1, 81–92 (1983).

  8. A. F. Zazovskii, On the calculation of the technological parameters of the oil displacement by carbonated water, Mekh. Zhidk. Gaza, No. 2, 65–72 (1985).

  9. A. F. Zazovskii and G. R. Gurevich, Oil displacement by nitrogenated gas, Neft. Khoz., No. 1, 34–38 (1988).

  10. V. P. Kosyakov and S. P. Rodionov, Obtaining exact solutions of the Buckley–Leverette problem for a stratum with zonal nonuniformity, Vestn. Tyumensk. Gos. Univ., No. 6, 36–42 (2010).

  11. V. P. Kosyakov and S. P. Rodionov, Determination of the best arrangement of a well gallery in a stratum with zonal nonuniformity with regard for the thermophysical properties of the fluids on the basis of an analytical solution, Vestn. Tyumensk. Gos. Univ., No. 4, 14–21 (2012).

  12. V. P. Kosyakov, S. P. Rodionov, P. N. Solyanov, and O. N. Pichugin, Investigation of the efficiency of the mutual arrangement of the injection and production well in an oil stratum with zonal nonuniformity, Neft. Khoz., No. 1, 2–4 (2012).

  13. Danial Kaviani, Jerry L. Jensen, Larry W. Lake, and Mashhad Fahes, Estimation of interwell connectivity in the case of fluctuating bottomhole pressures, SPE. Abu Dhabi Int. Petroleum Exh. and Conf., 3–6 November 2008, Abu Dhabi, UAE (2008).

  14. I. A. Charnyi, Unsteady Motion of a Real Liquid in Pipes [in Russian], Nedra, Moscow (1975).

  15. M. A. Guseinzade, L. I. Drichina, O. N. Petrova, and M. F. Stepanova, Hydrodynamic Processes in Complex Pipeline Systems [in Russian], Nedra, Moscow (1991).

  16. É. M. Abbasov and N. A. Agaeva, Determination of the pressure field in a reservoir-deformed bed exposed to vibrowaves, J. Eng. Phys. Thermophys., 90, No. 1, 43–49 (2017).

    Article  Google Scholar 

  17. É. M. Abbasov and Kh. A. Feizullaev, Mathematical simulation of the flow of a gas–liquid mixture in a stratum and in a well with regard for the dynamic coupling of the stratum–well system, Zh. Vych. Mat. Mat. Fiz., 56, No. 1, 142–154 (2016).

    Google Scholar 

  18. K. S. Basniev, A. M. Vlasov, I. N. Kochina, and V. M. Maksimov, Underground Fluid Dynamics [in Russian], Nedra, Moscow (1986).

  19. G. Dech, Handbook of Practical Application of the Laplace Transform [Russian translation], Nauka, Moscow (1965).

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Authors and Affiliations

  1. Oil and Gas Research and Design Institute, 88a Zardabi Ave., Az1012, Baku, Azerbaijan

    É. M. Abbasov & T. S. Kengerli

Authors
  1. É. M. Abbasov
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  2. T. S. Kengerli
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Correspondence to É. M. Abbasov.

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Translated from Inzhenerno-Fizicheskii Zhurnal, Vol. 92, No. 2, pp. 459–467, March–April, 2019.

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Abbasov, É.M., Kengerli, T.S. Integral Simulation of Oil Displacement by Water. J Eng Phys Thermophy 92, 441–449 (2019). https://doi.org/10.1007/s10891-019-01949-z

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  • DOI: https://doi.org/10.1007/s10891-019-01949-z

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