Название |
Compressed air parameters for spoil removal in casing pipe ramming in soil |
Информация об авторе |
Chinakal Institute of Mining, Siberian Branch, Russian Academy of Sciences, Novosibirsk, Russia:
A. S. Kondratenko, Researcher, Candidate of Engineering Sciences, kondratenkoas@yandex.ru A. M. Petreev, Researcher, Candidate of Engineering Sciences V. N. Karpov, Researcher, Candidate of Engineering Sciences |
Реферат |
Much drilling is performed in natural and manmade sedimentary soil of drillability category I–IV. The subsurface sedimentary soil represents a variety of rocks with widely ranged physical and mechanical properties. It is often difficult to ensure wellbore stability in such conditions. At the same time, open-ended pipe ramming under the impact momentum or vibration enables advanced installation of casings which ensure both wellbore stability and the highest hole-making efficiency. This article describes an analytical model of the required flow rate of compressed air for casing pipe ramming in various-purpose hole-making. In the technology of casing pipe ramming with spoil removal by air, compressed air is fed to the bottomhole end of the casing pipe along a separate line. When a spoil plug forms in the pipe, compressed air is fed inside the pipe to detach a portion of the plug and to displace it via an outlet. The removal cycles continue until the project wellbore length is achieved. In this technology, it is critical to choose a compressed air source that provides the required air pressure and flow rate. If these parameters are not limited, efficiency of spoil removal by air from a driven pipe raises no doubts. However, the actual limitedness of technical capabilities of compressed air sources demand determining application ranges and efficiency level for the technology. The authors present the testing bench and procedure to determine compressed air flow through rock samples. The recommendations are given to select a compressed air source subject to size of a casing pipe in the impact ramming. The study was carried out under State Contract No. 121052600390-5, Topic Code FWNZ-2021-0002. |
Библиографический список |
1. Sklyanov V. I., Figurak A. A., Emelina N. B., Eremenko A. A. Improvement of well flushing technology during drilling in permafrost. Eurasian Mining. 2020. No. 2. pp. 42–45. 2. Portola V. A., Zhdanov A. N., Bobrovnikova A. A. Analysis of the conditions facilitate to the development of the process of self-carrier-burning in coal stacks. GIAB. 2022. No. 6-1. pp. 187–197. 3. Oryngozhin E. S., Fedorov E. V., Alisheva Zh. N., Mitishova N. A. In-situ leaching technology for uranium deposits. Eurasian Mining. 2021. No. 2. pp. 31–35. 4. Mazein S. V., Potapova E. V. Features technology of modern shaft sinking machine in construction of subway vertical shafts in difficult conditions. Geotekhnika. 2022. Vol. 14, No. 2. pp. 60–74. 5. Bridges S., Robinson L. A Practical Handbook for Drilling Fluids Processing. Cambridge : Gulf Professional Publishing, 2020. 622 p. 6. Chervov V. V., Tishchenko I. V., Chervov A. V. Physical analog of shock pulse generator and high-frequency pneumatic hammer. Gornyi Zhurnal. 2022. No. 2. pp. 57–62. 7. Kondratenko A. S. Technological aspects of cased wells construction with cyclical-flow transportation of rock. Journal of Mining Institute. 2020. Vol. 246. pp. 610–616. 8. Nietiedt J. A., Randolph M. F., Gaudin Ch., Doherty J. P. Centrifuge Model Tests Investigating Initiation and Propagation of Pile Tip Damage during Driving. Journal of Geotechnical and Geoenvironmental Engineering. 2023. Vol. 149, No. 5. DOI: 10.1061/JGGEFK.GTENG-10616 9. MacGillivray A. Underwater noise from pile driving of conductor casing at a deepwater oil platform. The Journal Acoustical Society of America. 2018. Vol. 143, Iss. 1. pp. 450–459. 10. Skryabin R. M., Timofeev N. G. Technical and technological advance in placer exploration drilling in the polar zone of the North-East Russia. Gornyi Zhurnal. 2015. No. 3. pp. 14–17. 11. Meshkov A. A., Sadov A. P., Kharitonov I. L., Kondratenko A. S., Karpov V. N. Prospects for impact driving of steel hollow section pipes while drilling degasification holes from surface. Ugol. 2019. No. 10. pp. 50–55. 12. Isakov A. L., Kondratenko A. S., Petreev A. M. Simulation of Metal Pipe Driving in Soil with Batchwise Removal of Plug. Journal of Mining Science. 2019. Vol. 55, No. 4. pp. 547–555. 13. Vinda A. A. Trenchless pipeline laying by directional drilling. Hydraulic fracturing of soil and elimination of springs. Sfera. Neftegaz. 2011. No. 1. pp. 104–105. 14. Primychkin A. Yu., Kondratenko A. S., Timonin V. V. Determination of variables for air distribution system with elastic valve for down-the-hole pneumatic hammer. IOP Conference Series: Earth and Environmental Science. 2017. Vol. 53. 012025. DOI: 10.1088/1755-1315/53/1/012025 15. Gerts E. V., Kreynin G. V. Theory and design of pneumatic power plants. Moscow : Izdatelstvo AN SSSR, 1960. 178 p. 16. P 01-72. Guidelines to determine dynamic properties of soils, rocks and local building materials. Leningrad : Energiya, 1972. 36 p. 17. Ivanov P. L. Soils and waterwork foundations. Moscow : Vysshaya shkola, 1985. 352 p. |