Experimental investigation of thermohydrodynamic processes during filtration of water-oil emulsions

Tyumen State University Herald. Physical and Mathematical Modeling. Oil, Gas, Energy


Release:

2022. Vol. 8. № 1 (29)

Title: 
Experimental investigation of thermohydrodynamic processes during filtration of water-oil emulsions


For citation: Asylgareev A. A., Sharafutdinov R. F., Valiullin R. A., Kosmylin D. V. 2022. “Experimental investigation of thermohydrodynamic processes during filtration of water-oil emulsions”. Tyumen State University Herald. Physical and Mathematical Modeling. Oil, Gas, Energy, vol. 8, no. 1 (29), pp. 8-22. DOI: 10.21684/2411-7978-2022-8-1-8-22

About the authors:

Albert A. Asylgareev, Postgraduate Student, Department of Geophysics, Bashkir State University (Ufa); asylgareev9696@gmail.com

Ramil F. Sharafutdinov, Dr. Sci. (Phys.-Math.), Professor, Department of Geophysics, Bashkir State University (Ufa); gframil@inbox.ru

Rim A. Valiullin, Dr. Sci. (Tech.), Professor, Head of the Department of Geophysics, Bashkir State University (Ufa); valra@geotec.ru

Denis V. Kosmilin, Senior Lecturer, Department of Geophysics, Bashkir State University (Ufa); kosmylindenis@yandex.ru

Abstract:

Temperature measurements in downhole conditions (well thermometry) are widely used in monitoring the development of oil and gas reservoirs. With the use of thermometry many oilfield tasks are solved: determination of the working intervals, behind-the-casing flows, casing leakage etc. Variation of temperature in formation is caused by thermodynamic effects: Joule-Thomson and adiabatic. One of the main effects in determining the working intervals by downhole thermometry methods is the Joule-Thomson effect, which is associated with the Joule-Thomson coefficient, characterizing the composition of the fluid flowing from the perforated formation into the well. Therefore, it is necessary to know the value of Joule-Thomson coefficient for different fluids, especially it is important for quantitative interpretation of thermometry data.

Currently, the Joule-Thomson coefficient is well studied for various pure fluids and gases, but practically not investigated for emulsions of different types. Meanwhile, the inflow of oil and water from the formation often leads to the formation of emulsion in the bottomhole zone of the formation. Therefore, experimental determination of Joule-Thomson coefficient for such systems and study of thermohydrodynamic processes during emulsion filtration is relevant.

The paper presents the results of experimental studies of thermohydrodynamic processes during filtration of emulsion through a choke cell. The description of the experimental setup and the experimental procedure are given. The main design features of the throttle cell, approaches to reduce heat transfer during the movement of fluid through the throttle cell are discussed in detail. The data of experimental studies of temperature and pressure changes during filtration of type “oil in water” — oil dispersion in water and reverse emulsions of type “water in oil” — water dispersion in oil on the throttling cell are given. The paper also obtained estimates of the Joule-Thomson effect for liquids like water, oil and oil-water emulsions.

References:

  1. Akhmetov A. T., Telin A. G., Mavletov M. V. 2005. “New principles of application of reverse water-oil emulsions in flow-deflecting technologies and well killing”. Oil and Gas Business, no. 3, pp. 119-126. [In Russian]

  2. Akhmetov A. T., Nigmatulin R. I., Fedorov K. M. 1987. “On the mechanism of oil displacement from the porous medium by micellar solutions”. Reports of the USSR Academy of Sciences, vol. 293, no. 3, pp. 558-562. [In Russian]

  3. Akhmetov A. T., Sametov S. P. 2010. “Features of dispersion flow from water microdroplets in microchannels”. Papers in the Journal of Technical Physics, vol. 36, no. 22, pp. 21-28. [In Russian]

  4. Valiullin R. A., Ramazanov A. Sh., Sharafutdinov R. F. 1994. “Barothermal effect in three-phase filtration with phase transitions”. Proceedings of the Russian Academy of Sciences. Fluid and gas mechanics, no. 6, pp.113-117. [In Russian]

  5. Valiullin R. A., Sharafutdinov R. F., Fedotov V. Ya., Kosmilin D. V., Kanafin I. V. 2017. “Studies of temperature field in wellbore during induction heating of the casing pipe with behind-the-casing fluid flow channels”. Tyumen State University Herald. Physical and Mathematical Modeling. Oil, Gas, Energy, vol. 3, no 3, pp. 17-28. DOI: 10.21684/2411-7978-2017-3-3-17-28 [In Russian]

  6. Valiullin R. A., Sharafutdinov R. F., Gafurov A. I., Fedotov V. Ya. 2017. “The study of thermohydrodynamic processes on the model of a porous medium”. Bashkir University Herald, vol. 22, no. 2, pp. 340-344. [In Russian]

  7. Valiullin R. A., Kulagin O. L., Sharafutdinov R. F. 1995. “Experimental study of thermodynamic effects in gas-liquid systems”. Physical and chemical hydrodynamics: an interuniversity collection. Ufa: Bashkirian State University. Pp. 10-15. [In Russian]

  8. Lapuk B. B. 1940. “Thermodynamic processes in the movement of carbonated oil in porous media”. Azerbaijan oil industry, no. 2, pp. 28-34. [In Russian]

  9. Trebin G. F., Kapyrin Yu. F., Limanskiy O. G. 1978. Estimation of temperature underbalance in the bottomhole zone of development wells. All-Union Oil and Gas Research Institute, iss. 64, pp. 16-22. [In Russian]

  10. Chekaluk E. B. 1965. Thermodynamics of an oil reservoir. Moscow: Nedra. 240 p. [In Russian]

  11. Davis J. A. 1968. “Displacement mechanisms of micellar solutions”. Journal of Petroleum Technology, vol. 20, no. 12, pp. 1415-1428. DOI: 10.2118/1847-2-PA

  12. Gladkov S. O. 2003. “On the connection of Joule-Thompson’s coefficient with dissipation properties of filtrating media”. European Physical Journal E., vol. 10, pp. 171‑174. DOI: 10.1140/epje/e2003-00021-2

  13. Gladkov S. O. 2002. “On the Darcy law under enthalpy conservation conditions”. Technical Physics Letters, vol. 28, no. 10, pp. 861-863. DOI: 10.1134/1.1519031

  14. Martin Lisal, William R. Smith, Karel Aim. 2003. “Direct molecular-level Monte Carlo simulation of Joule-Thomson processes”. Molecular Physics, vol. 101, no. 18, pp. 2875‑2884. DOI: 10.1080/00268970310001592755

  15. Valiullin R. A., Sharafutdinov R. F., Ramazanov A. Sh. 2004. “A research into thermal field in fluid-saturated porous media”. Powder Technology, vol. 148, iss.1, pp. 72-77. DOI: 10.1016/j.powtec.2004.09.023