DOI: 10.5937/jaes18-25998
This is an open access article distributed under the CC BY-NC-ND 4.0 terms and conditions.
Volume 18 article 687 pages: 267 - 272
A new scientific approach to gas compression using jet pump-compressor units has been developed. The new patented
technical solution offers an opportunity for the effective application of jet pump-compressor units for the compression
of various gases up to pressures of 10...40 MPa. The purpose of the ongoing research work is to develop
new scientific principles for gas compression using jet pump-compressor units. The new scientific approach is associated
with the improvement of the pump-compressor unit, with the provision of conditions for the periodic connection
of the ejector during the implementation of a cyclic low-frequency working process. The results of the research findings
can be used to create energy-efficient technologies for the compression and pumping of various gases; it can be
methane, associated petroleum gas, nitrogen, carbon dioxide, air, hydrogen or other gases. The creation of cheaper
and more economical pump-compressor units will allow for the solution of urgent production problems in hydrocarbon
production, including those in remote Arctic oil and gas fields.
The work was performed with the financial support of the
Ministry of Education and Science of the Russian Federation
within the framework of the state contract in the
sphere of scientific activities, topic number FSZE-2020-
0006.
1. Sazonov, Yu.A., Mokhov, M.A., Tumanyan, H.A., Frankov, M.A., Azarin, K.I. (2018). Development of compressor technologies with high-pressure ejectors for oil and gas production. Oil industry, 5, 78-82.
2. Drozdov, A.N., Egorov, Yu.A., Telkov, V.P., Verbitsky, V.S., Dengaev, A.V. (2006). Technology and technique of water-alternated-gas injection on oil formations. Oil and Gas Territory, 2, 54-59.
3. Drozdov, A.N. (2011). Research of the pump characteristics in the process of gas-liquid mixtures pumping and application of the results obtained for the development of water-alternated-gas injection technologies. Oil industry, 9, 108-111.
4. Drozdov, A.N., Terikov, B.A. (2009). Application of the downhole hydro-jet pumps with the double-row lift for the operation of the difficult wells. Oil Industry, 6, 68-72.
5. Lea, J.F., Winkler, H.W. (2010). What’s new in artificial lift. Part 1. Introducing developments in natural gas well dewatering. World Oil, March, 51-59.
6. Brink, M. (2014). Jet pump technology for artificial lift in oil and gas production. The Elomatic Magazine, 1, 40-43.
7. Singh, M.K., Prasad, D., Singh, A.K., Jha, M., Tandon, R. (2013). SPE 166077-MS. Large Scale Jet Pump Performance Optimization in a Viscous Oil Field. SPE, Cairn India Ltd. Copyright 2013, Society of Petroleum Engineers. Technical Conference and Exhibition held in New Orleans, Louisiana, USA, 30 September – 2 October 2013.
8. Morishima, S. (2008). US Patent No. 7,438,535. Structure of ejector pump Date of Patent: Oct. 21, 2008.
9. Castel, Y. (1996). US Patent No. 5,575,625. Multiphase pump with sequential jets. Date of Patent: Nov. 19, 1996.
10. Castel, Y. (1997). US Patent No. 5,616,006. Pumping method and device with sequential jets. Date of Patent: Apr. 1, 1997.
11. Castel, Y. (1998). US Patent No. 5,716,196. Pumping method and device with sequential jets. Date of Patent: Feb. 10, 1998.
12. Podvidz, L.G. (1980). Pulse-action pumping plants. Proceedings of the Higher Educational Institutions (Izvestiya VUZOV). Machine Building, 9, 51-56.
13. Sazonov, Yu.A., Mokhov, M.A., Tumanyan, Kh.A., Frankov, M.A., Voronova, V.V. (2019). Designing a compressor unit for gas compression at sequential work of an ejector and a power pump. Journal of Computational and Theoretical Nanoscience, 16(7), 2851-2857(7).
14. Sazonov, Yu.A., Mokhov, M.A., Tumanyan, Kh.A., Frankov, M.A., Mun, V.A., Osicheva, L.V. (2019). Development of technologies for increase the ejector units’ efficiency. Journal of Computational and Theoretical Nanoscience, 16(7), 3087-3093(7).
15. Sazonov, I.A., Mokhov, M.A., Tumanyan, Kh.A., Frankov, M.A., Markelov, S.I. (2019). Development of an automated compressor unit for gas compression at the periodic connection of an ejector. Journal of Computational and Theoretical Nanoscience, 16(12), 5378–5383(6).
16. Sazonov, Yu.A. (2012). Basis of calculation and design of the pump-ejector installations. Moscow: Federal State Unitary Enterprise Publishing House "Oil and Gas" of Gubkin Russian State University of Oil and Gas.
17. Zheng, S., Yang, L. (2017). Numerical Experiments of Dynamic Response of Buried Gas Pipeline under the Action of Seismic Waves Induced by Tunnel Blasting. Journal of Southwest Jiaotong University, 52(2).
18. Liu, Z., Li, L., Han, Z., Pan, J., Ding, Y. (2016). Current Following Segmented PID Control of Air Supply System in Heavy-Duty PEMFC System. Journal of Southwest Jiaotong University, 51(3).
19. Taras’yants, S.A., Pashkov, P.V., Efi mov, D.S. (2018). Laboratory Tests of a Jet Device to Increase the Centrifugal and Axial Pump Suction Head. Periodico Tche Quimica, 15 (Special Issue - 1), 55-66.
20. Konesev, S.G., Khlyupin, P.A., Greb, A.V., Kondratiev, E.Y. (2018). Induction Technology in High-Viscosity Oil Production at Tazovskoye Field. Periodico Tche Quimica, 15(30), 520-526.