THE STATE OF THE PROBLEM OF THE JOINT MOVEMENT OF FLUID IN THE PORE SPACE
DOI:
https://doi.org/10.26577/JMMCS.2022.v114.i2.011Keywords:
Stefan problem, difference scheme, numerical methods, phase boundary, sorption, adsorption, surfactant, relaxation time, averaged model, microscopic model, macroscopic model, joint motion of liquidsAbstract
This article discusses the problems of studying the issue of joint motion of liquids in the porous space. The article provides the construction of a mathematical model of the theory of ltration, which describes phase transitions. The main diculty in constructing this model is associated with the fact that free interphase boundaries create regions that change over time, and it is required to nd the temperature or concentration elds of substances in them. In this case, the coordinates of the considered phase boundaries are not initially specied and must be calculated already in the process of solving. For this, a derivation of the averaged equation for the problem of nding the rupture surface during the movement of two incompressible viscous liquids in the pores of the soil skeleton was proposed. The article deals with the case when the skeleton is an absolutely rigid body. The rationale was given for the choice of an averaged ltration model instead of a microscopic one. The main research methods are classical methods of mathematical physics, functional analysis and computation methods of the theory of partial dierential equations, as well as dierence methods. The formulation of the problem is given, and the denition of a generalized solution for solving the problem is provided. Next, an averaged model is derived and the existence of at least one generalized solution to the problem is proved.
References
[2] Ahmed-Zaki D.Zh., Mukhambetzhanov S.T., Imankulov T.S. Design of i-elds system component: Computer model of oil-recovery by polymer ooding // Informatics in Control, Automation and Robotics (ICINCO), 12th International Conference, Colmar, France, -2015. -P. 510-516.
[3] Meirmanov A.M., Mukhambetzhanov S.T., Nurtas, M. Seismic in composite media: Elastic and poroelastic components// Siberian Electronic Mathematical Reports. - 2016. https://doi.org/10.17377/semi.2016.13.006
38 JOINT MOTION OF FLUID . . .
[4] Kenzhebayev T.S., Mukhambetzhanov S.T. Numerical Solution of the inverse problem of ltration theory by modulating functions// Far East Journal of Mathematical Sciences. - 2016. -V. 99 (12). -P. 1779
[5] Smagulov S. H., Mukhambetzhanov S. T., Baymirov K. M. Dierence schemes for modeling two-dimensional MusketLeverett equations on an irregular grid// Reports of the 3rd Kazakhstan-Russian scientic-practical conference. -2016. -P. 43-48.
[6] Zhumagulov B. T., Mukhambetzhanov S. T., Shyganakov N. A. Modeling oil displacement taking into account mass transfer processes. -2016. -P.416
[7] Kaliev I.A.½ Sabitova G.S. ?The third boundary value problem for the system of equations of non-equilibrium sorption?// Sib. elektron. matem. izv.. -2018. -V. 15. -P. 1857-1864
[8] Kaliev I.A.½ Sabitova G.S. Neumann boundary value problem for system of equations of non-equilibrium sorption// Ufa Math. J.. -2019. -V. 11(4). -P. 33-39
[9] Choi J. H., Edwards P., Ko K., Kim Y. S. Denition and classication of fault damage zones: a review and a new
methodological approach.// Earth-Science Rev. -2019. -V.152. -P.70-87 https://doi.org/10.1016/j.earscirev.2015.11.006
[10] Feng J., Ren Q., Xu K. Quantitative prediction of fracture distribution using geomechanical method.//- 2018. -V.162. -P.22-34. https://doi: 10.1016/j.petrol.2017.12.006
