Разработка композиционного гидродинамического симулятора процессов повышения нефтеотдачи пластов химическими методами

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Для принятия решений и обеспечения успешной разработки месторождений нефтедобывающие компании используют инструменты численного моделирования, в том числе, и гидродинамические симуляторы. Данная работа посвящена разработке гидродинамического симулятора, основанного на новой формулировке дифференциальных уравнений в частных производных композиционной модели химического заводнения пласта, а также его тестированию путём сравнения результатов моделирования традиционного и ASP заводнения с аналогичными результатами широко известных симуляторов.

Об авторах

Бахберген Ермекбаевич Бекбауов

ТОО «КМГ Инжиниринг»

Автор, ответственный за переписку.
Email: b.bekbauov@niikmg.kz

доктор PhD, директор департамента новых технологий и повышения нефтеотдачи пластов

Казахстан, Нур-Султан

Мерей Мерекеұлы Темірқас

Satbayev University; ТОО «КМГ Инжиниринг»

Email: mtemirkas@gmail.com

студент специальности «Нефтегазовое дело», практикант

Казахстан, Алматы; Нур-Султан

Асар Габдыганиулы Кучиков

Satbayev University; ТОО «КМГ Инжиниринг»

Email: assarkuchikov@gmail.com

студент специальности «Нефтегазовое дело», практикант

Казахстан, Алматы; Нур-Султан

Список литературы

  1. Abriola L.M., Pinder G.F. A multiphase approach to the modeling of porous media contamination by organic compounds: 2. Numerical Simulation. - Water Resources Res., 1985, 21 (1), р. 19-26.
  2. Abriola L.M., Pinder G.F. Two-dimensional numerical simulation of subsurface contamination by organic compounds. - A Multiphase Approach. - Proceedings of Specialty Conference on Computer Applications in Water Resources, Buffalo, NY, USA, 1985.
  3. Baehr A.L., Corapcioglu MY. A compositional multiphase model for groundwater contamination by petroleum products: 2. Numerical Solution. - Water Resources Res., 1987, 23(10), р. 201-213.
  4. Faust J.C., Guswa J.H., Mercer J.W. Simulation of Three-Dimensional Flow of Immiscible Fluids within and Below the Saturated Zone. - Water Resources Res., 1989, 25(12), 2449-2464.
  5. Letniowski F.W., Forsyth P.A. A control volume finite element approach for threedimensional NAPL groundwater contamination. - University of Waterloo, Ontario, Canada, Dept. of Computer Science, Report No. CS90-21, 1990.
  6. Sleep B.E., Sykes J.F. Numerical simulation of three-phase multidimensional flow in porous media. - Computational Methods in Subsurface Hydrology, 1990, 211-216.
  7. Mayer A.S., Miller C.T. A Compositional Model for Simulating Multiphase Flow, Transport and Mass Transfer in Groundwater Systems. - Materials of Eighth Int. Conference on Computational Methods in Water Resources, Venice, Italy, June 11-15, 1990.
  8. Kalurachchi J.J., Parker J.C. Modeling Multicomponent Organic Chemical Transport in Three-Phase Porous Media. - J. of Contaminant Hydrology, 1990, № 5, 349-374.
  9. Sleep B.E., Sykes J.F. Compositional Simulation of Groundwater Contamination by Organic Compounds: 1. Model Development and Verification. - Water Resources Res., 1993, 29(6), p. 1697-1708.
  10. Pope G.A., Nelson R.C. A Chemical Flooding Compositional Simulator. - Soc. Pet. Eng. J., , 1978, 18, p. 339-354.
  11. Saad N. Field Scale Studies With a 3-D Chemical Flooding Simulator. - Ph.D. dissertation, The University of Texas at Austin, 1989.
  12. Delshad M., Pope G.A., Sepehrnoori K. UTCHEM Version-9.0, Technical Documentation. - Center for Petroleum and Geosystems Engineering. The University of Texas at Austin, Texas, 2000.
  13. Acs G., Doleschall S., Farkas, E. General Purpose Compositional Model. - Paper SPE 10515, SPE Journal, 1985, 25(4), p. 543-553.
  14. Branco C., Rodriguez, F. A Semi-Implicit Formulation for Compositional Reservoir Simulation. - Paper SPE 27053, SPE Advanced Technology Series, 1996, 4(1), p. 171-177.
  15. Cao H. Development of Techniques for General Purpose Simulators, - Ph.D. Dissertation, Department of Petroleum Engineering, Stanford University, 2002.
  16. Chang Y., Pope G.A. and Sepehrnoori K. A higher-order finite-difference compositional simulator. - Journal of Petroleum Science and Engineering, 1990a, 5(1), p. 35-50.
  17. Chien M., Lee S., Chen, W. A New Fully Implicit Compositional Simulator. - Paper SPE 13385, 8th SPE Symposium on Reservoir Simulation, Dallas, TX, 1985.
  18. Coats K.H. An Equation of State Compositional Model. - SPE Paper 8284, SPE Journal, 1980, 20(5), p. 363-376.
  19. Collins D., Nghiem L., Li Y. and Grabonstotter J. An Efficient Approach to Adaptive- Implicit Compositional Simulation with an Equation-of-State. - Paper SPE 15133, SPE Reservoir Engineering, 1992, 7(2), p. 259-264.
  20. Fussell L., Fussell D. An Iterative Technique for Compositional Reservoir Models. - Paper SPE 6891, SPE Journal, 1979, 19(4), p. 211-220,
  21. Kazemi H., Vestal C. and Shank D. An Efficient Multicomponent Numerical Simulator. - Paper SPE 6890, SPE Journal, 1978, 18(5), p. 355-368.
  22. Kendall R., Morrell G., Peaceman D., Silliman W., Watts J. Development of a Multiple Application Reservoir Simulator for Use on a Vector Computer. - Paper SPE 11483, 1983, Middle East Oil Technical Conference, Manama, Bahrain.
  23. Lins A.G. Advanced Compositional Simulation of CO2 Processes. - Ph.D. Dissertation, University of Calgary, Calgary, 2010.
  24. Nghiem L.X., Fong D., Aziz K. Compositional Modeling with an Equation-of-State. - Paper SPE 9306, SPE Journal, 1981, 21(6), 687-698.
  25. Quandalle P., Savary D. An Implicit in Pressure and Saturations Approach to Fully Compositional Simulation. - Paper SPE 18423, SPE Symposium on Reservoir Simulation, Houston, TX, 1989.
  26. Wang P., Wheeler M., Parashar M., Sepehrnoori K. A New Generation EOS Compositional Reservoir Simulator: Part I - Formulation and Discretization. - Paper SPE 37979, SPE Reservoir Simulation Symposium, Dallas - TX, 1997.
  27. Watts J. A Compositional Formulation of the Pressure and Saturation Equations. - Paper SPE 12244, SPE Reservoir Engineering, 1986, 1(3), 243-252.
  28. Wei Y., Michelsen M., Stenby E., Berenblyum R., Shapiro A. Three-phase Compositional Streamline Simulation and Its Application to WAG. - SPE Paper 89440, SPE/DOE Symposium on Improved Oil Recovery, 2004.
  29. Young, L. and Stephenson, R. A Generalized Compositional Approach for Reservoir Simulation. - Paper SPE 10516, SPE Journal, 1983, 23(5): 727-742.
  30. Wong, T.W., Aziz, K. Considerations in the Development of Multipurpose Reservoir Simulation Models. - First and Second International Forum on Reservoir Simulation, Alpbach, Austria, 1988, p. 12-16.
  31. Bekbauov B.E., Kaltayev A., Berdyshev A. A New Mathematical Formulation of the Governing Equations for the Chemical Compositional Simulation. - arXiv:1512.08170 [physics.flu-dyn], 2015.
  32. Goudarzi, M.D. A Critical Assessment of Several Reservoir Simulators for Modeling Chemical Enhanced Oil Recovery Processes. - SPE International, 2013.
  33. Bekbauov B., Berdyshev A. and Baishemirov Zh. Numerical Simulation of Chemical Enhanced Oil Recovery Processes. In: A. Kononov et al. (eds.) -: DOOR 2016, published online on the CEUR web site http://ceur-ws.org with ISSN 1613-0073. Vol-1623, p. 28-34.
  34. Bekbauov B., Berdyshev A., Baishemirov Zh., and Bau D. Numerical Validation of Chemical Compositional Model for Wettability Alteration Processes. - Open Engineering, Volume 7, Issue 1, 2017, p. 416-427.

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