Separation equipment with increased well fluids separation capacity

Separation technique and technology improving to increase well production fluids separation effect is an important issue in the field of petroleum production and treatment. Due to the change in the size of separator containers, the increase in the separation equipment productivity has reached its maximum capabilities, and subsequent work in this direction is difficult and unjustified. Studying the gas-liquid flows movement in the separator, the in-package and in-rotor flows impact, changes in package design, the process of the dispersed phase and the flotation effect destruction will allow us to create a technological and technical basis for separation equipment performance ensuring in the future. Because of the study, the design of the apparatus with the best well production fluids separation was pro-posed, the use of which ensures the separation and dense fraction removal the through the discharge opening efficiency. Based on the presented research, a prototype apparatus was developed and machined.

1. Persiyantsev, M. N. (1999). Advances in Processes of Separating the Oil from the Gas under Field Conditions. Moscow, Nedra Publ., 365 p. (In English).

2. Khabibullin, M. Ya., & Suleimanov, R. I. (2018). Selection of optimal design of a universal device for nonstationary pulse pumping of liquid in a reservoir pressure maintenance system. Chemical and Petroleum Engineering, 54(3 -4), pp. 225-232. (In Russian). DOI: 10.1007/s10556-018-0467-2

3. Sakhabutdinov, R. Z., Shatalov, A. N., Garifullin, R. M., Shipilov, D. D., & Mukhametgaleev, R. R. (2008). Technologies of an oil cleaning from hydrogen sulphide. Oil Industry, (7), pp. 82-86. (In Russian).

4. Gilaev, G. G., Manasian, A. E., Letichevskiy, A. E., Parfenov, A. N., Khamitov, I. G., & Gilaev, G. G. (2014). Hydraulic fracturing as field development instrument in Samara region. Oil Industry, (11), pp. 65-69. (In Russian).

5. Sinaiski, E. G., & Lapiga, E. J. (2007). Separation of Multiphase, Multicomponent Systems. (In English). Available at: https://doi.org/10.1002/9783527611386

6. Khabibullin, M. Ya. (2018). Research of processes in a pipe string at a wellhead pulse injection of liquid to a well. Petroleum Engineering, 16(6), pp. 34 -39. (In Russian). DOI: 10.17122/ngdelo-2018-6-34-39

7. Alfyorov, V., Bagirov, L., Dmitriev, L., Feygin, V., Imayev, S., & Lacey, J. R. (2005). Supersonic nozzle efficiently separates natural gas components. Oil & Gas Journal, 103(20), pp. 53-58. (In English). Available at: http://pascal-francis.inist.fr/vibad/index.php?action=getRecordDetail&idt=16811357

8. Ulianov, S. S., Sagyndykov, R. I., Davydov, D. S., Dolinyuk, V. Ye., Gilaev, G. G., & Totanov, A. S. (2017). A new approach to the measurement of wells yields. Oil Industry, (9), pp. 116-119. (In Russian). DOI: 10.24887/0028-2448-2017-9-116-119

9. Khoi Vu, V., Fantoft, R., Shaw, Ch. K., & Gruehagen, H. (2009). Comparison of Subsea Separation Systems. Offshore Technology Conference (May 4-7, Houston, Texas). (In English). Available at: https://doi.org/10.4043/20080-ms

10. Khabibullin, M. Ya. (2019). Systematization of methods of water injection in wells. Petroleum Engineering, 17(3), pp. 80-86. (In Russian). DOI: 10.17122/ngdelo-2019-3-80-86

11. Timerbaev, A. S., & Taranova, L. V. (2014). Numerical simulation separation oil-water emulsions in centrifugal separator. Fundamental research, (9(3)), pp. 547-551. (In Russian).

12. Khabibullin, M. Ya., Suleymanov, R. I., Sidorkin, D. I., & Zainagalina, L. Z. (2018). Stress state columns of tubing string during operation pulsed downhole device. Oil and Gas Studies, (4), pp. 94-99.(In Russian). DOI: 10.31660/0445-0108-2018-4-94-99

13. Ternovskiy, I. G., & Kutepov, A. M. (1994). Gidrotsiklonirovanie. Moscow, Nauka Publ., 350 p.(In Russian).

14. Khabibullin, M. Ya., & Suleymanov, R. I. (2019). Increasing the reliability of welded pipeline connections in reservoir pressure maintenance system.Petroleum Engineering, 17(5), pp. 93-98. (In Russian). DOI: 10.17122/ngdelo-2019-5-93-98

15. Gilaev, G. G., Gladunov, O. V., Ismagilov, A. F., Grishagin, A. V., & Gurov, A. N. (2015). Monitoring the quality of design solutions and optimization of the designed structures of capital construction objects in the oil industry. Oil Industry, (8), pp. 94-97. (In Russian).

16. Guangdong Guo, & Songsheng, Deng. (2013). Research on Dispersed Oil Droplets Breakage and Emulsification in the Dynamic Oil and Shhater Hydrocyclone. Advance Journal of Food Science and Technology, 5(8), pp. 1110-1116. (In English). DOI:10.19026/ajfst.5.3215

17. Milshtejn, L. M. (2009). Experience of application and prospect of upgrading of oil-andgas separators. Oil Industry, (3), pp. 88-91. (In Russian).

18. Saveleva, N. N. (2019). Improvement of technological equipment of the system of gathering and welding preparation. Modern high technologies, (2), pp. 138-142. (In Russian).

19. Sorokin, D. A., & Geraskin, V. I. (2011). Modern Separation Procedures of "FCM Technologies Co." CDS Gasunie™ Cyclone Separator. Neft. Gas. Novacii, 10(153), pp. 26-27. (In Russian).

20. Karanevskaya, T. N., & Popova, A. V. (2016). Avtomatizirovannyy vybor tekhnologicheskikh sistem sbora i promyslovoy podgotovki nefti na osnove modul'nogo podkhoda k ikh predstavleniyu. Neft. Gas. Novacii, (5), pp. 20-23. (In Russian).

21. Ivanov, V. A. & Sokolov, S. M. (2017). Solutions for the system reliability of field facilities of West Siberian oil fields. Oil and Gas Studies, (6), pp. 73-77. (In Russian). DOI: 10.31660/0445-0108-2017-6-73-77

22. Zibert, A. G., Zibert, G. K., & Minigulov, R. M. (2010). Sovershenstvovanie separatsionnogo oborudovaniya na osnove ucheta fazovogo sostoyaniya gazozhidkostnoy smesi. GAS Industry of Russia, (4(645)), pp. 49-52. (In Russian).