Source: https://vestnik.utmn.ru/eng/energy/vypuski/2016-tom-2/2/297300/
Timestamp: 2019-04-22 22:47:24+00:00

Document:
The geological materials containing hydrocarbons are under strain due to the pressure of the overlying layers. Field development processes have an impact on the reservoir stress-strain state, which leads to a change in reservoir properties of geological materials. To account for the influence of the processes occurring in the skeleton of the material on hydrocarbons production, the coupled geomechanical and hydrodynamic modeling of hydrocarbon extraction is used.
The purpose of this article is to study the influence of periodic pressures on the fluid filtration process. An example of such pressure in real reservoir systems can be seen in the gravitational tides of the earth’s crust. The paper presents the results of a one-dimensional solution of the problem of the displacement of oil by water. Harmonically changing gravitational tides of the earth’s crust were simulated by periodic lateral load on the reservoir.
Based on the calculations, it has been found that water injection mode has an impact on oil recovery under the conditions of periodic pressure. It is established that there is an optimum injection mode at which the maximum oil recovery is achieved.
Aziz K., Settari E. 1982 (1979). Matematicheskoye modelirovanie plastovykh sistem [Petroleum Reservoir Simulation]. Translated from English by A. V. Korolyov, V. P. Kestner; edited by M. M. Maksimov. Moscow: Nedra.
Basniev K. S., Kochina I. N., Maksimov V. M. 1993. Podzemnaya gidromekhanika. Uchebnik dlya vuzov [Underground Hydromechanics. University Textbook]. Moscow: Nedra.
Coussy O. 2004. Poromechanics. Chichester, England: John Wiley and Sons.
Geertsma J. 1957. “The Effect of Fluid Pressure Decline on Volumetric Change of Porous Rocks”. Transactions of the Metallurgical Society of AIME, no 210, pp. 331–340.
Kanevskaya R. D. 2003. Matematicheskoe modelirovanie gidrodinamicheskikh protsessov razrabotki mestorozhdeniy uglevodorodov [Mathematical Modeling of Hydrodynamic Processes of Hydrocarbon Field Development], p. 121. Izhevsk: IKI.
Mirzoyev K. M., Nikolayev A. V., Mirzoyev V. K., Lukk A. A., Kharlamov A. I., Deshcherevskiy A. V. 2014. “Sposoby uvelicheniya dobychi nefti s uchetom prilivnykh dvizheniy Zemli” [Ways to Increase Oil Production in View of the Tidal Movements of the Earth]. Ekspozitsiya Neft Gaz, no 2/H (34), April, pp. 93–96.
Muslimov R. Kh., Mirzoev K. M., Akhmadiev R. G., Agafonov V. A., Khuzin R. R., Timiro V. S., Mirzoev V. K., Lukk A. A., Deshcherevskiy A. V. 2006. “Vliyanie gravitatsionnykh lunno-solnechnykh prilivov zemnoy kory na dobychu nefti” [The Influence of Gravity Lunar-Solar Tides of the Earth’s Crust on Oil Production]. Neftyanoye khozyaystvo, no 8, pp. 111–115.
Patankar S. 1984. Chislennye metody resheniya zadach teploobmena i dinamiki zhidkosti [Numerical Heat Transfer and Fluid Flow]. Translated from English. Moscow: Energoatomizdat.

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