A. V. Fedotova, A. F. Salnikov, M. V. Bogatov and V. O. Gorshkov

EVALUATING THE APPLICABILITY OF THE VIBROACOUSTIC METHOD TO THE DETERMINATION OF THE RESIDUAL LIFE OF PIPES MADE OF POLYMER-REINFORCED MATERIALS

Advanced methods for protection against various types of complicating factors in the oil and gas industry have always been and will remain a pressing issue. The use of pipes made of alternative materials is a definite trend in this field. Many oil companies are already using polymer-reinforced pipes of various designs to transport hydrocarbons. These pipes undoubtedly offer a number of advantages over steel field pipelines. Evaluation of the service life of steel pipes is a solved and well-known problem, whereas evaluation of the service life of pipes made of alternative materials remains a challenge for scientists. This paper discusses a vibroacoustic method for attempting to identify various types of artificial defects (notches, kinks, impacts) on the surface of flexible polymer-reinforced pipes and decoding their wave signal.

References:

1. Galeev, A.S., Birbulatova, G.I., Boltneva, Yu.A., and Shulin, V.S. Analysis of the causes of failures of deep-well pumping equipment during operation of wells with rod pumps in difficult conditions. Izvestiya TulGTU. Tekhnicheskie Nauki, 2024, 8, 36–38. (In Russian). DOI: 10.24412/2071-6168-2024-8-36-37.
2. Gureeva, E.G., Gureev, K.A., and Akhunov, Yu.A. Advanced analysis of extensive and intensive factors determining the level of field oil production in the fields. In: Fundamentalnaya i prikladnaya nauka: sostoyanie i tendentsii razvitiya [Basic and Applied Science: Current Status and Development Trends: Monograph]. MTsNP Novaya Nauka Publ., Petrozavodsk, 2023, pp. 148–159. (In Russian). DOI: 10.46916/05062023-2-978-5-00215-000-7.
3. Strelkova, K.Yu., Gilaev, G.G., Gilaev, G.G., Reshetnikova, Ya.N., and Lipatova, A.R. Causes of formation and technologies for combating asphalt-tar-paraffin deposits. In: Molodezhnaya Nauka [Youth Science, Krasnodar, 2021: Proceedings]. KubGTU Publ., Krasnodar, 2022, pp. 66–74. (In Russian).
4. Kakaeva, M.Yu. Technology for predicting salt deposits in oil production. Nauchnyi Setevoy Zhurnal Stolypinskiy Vestnik, 2022, 9. (In Russian).
5. Boyzhigitov, А.U., and Zailalova, V.R. Corrosion processes in oil and gas production. In: Vserossiyskaya nauchno-tekhnicheskaya konferentsiya molodykh uchenykh, aspirantov i studentov s mezhdunarodnym uchastiem [The 48^th All-Russian Scientific and Technical Conference, with International Participation, for Young Scientists, Postgraduates and Undergraduates, Oktyabrskiy, April 23, 2021: Proceedings]. UGNTU Publ., Ufa, 2021, 821–831. (In Russian).
6. Rogachev, M.K. and Aleksandrov, A.N. Justification of a comprehensive technology for preventing the formation of asphalt-resin-paraffin deposits during the production of highly paraffinic oil by electric submersible pumps from multiformation deposits. Journal of Mining Institute, 2021, 250, 596–605. DOI: 10.31897/PMI.2021.4.13.
7. Kravtsiv, V.V. Antoniadi, D.G., Gilaev, G.G., Grigoriev, M.V., and Reshetnikova, Ya.N. Mechanical impurities and their influence on the operation of ESP in oil production. In: Molodezhnaya Nauka [Youth Science: Collection of the Best Research Papers by Young Scientists]. KubGTU Publ., Krasnodar, pp. 28–36. (In Russian).
8. Roshchin, P.V., Zinovev, A.M., Riazanov, A.A., Soboleva, E.I., Nikitin, A.V., and Murzakhanov, A.R. Improving the efficiency of heavy oil production using solvents: laboratory tests and implementation in oil production. Vestnik Evraziyskoy Nauki, 2021, 13 (2). (In Russian). Available at: https://esj.today/PDF/24SAVN221.pdf
9. Mitroshin, A.V. Determination of the minimum measures in the well to prevent the formation of asphalt-resin-paraffin deposits. Perm Journal of Petroleum and Mining Engineering, 2021, 21 (2), 94–100. DOI: 10.15593/2712-8008/2021.2.7.
10. Misyurkeeva, N.V., Buddo, I.V., Shelokhov, I.A., Smirnov, A.S., and Nezhdanov, A.A. Arctic gas hydrates: possibilities and prospects of studying by electromagnetic methods. Nauki o Zemle i Nedropolzovanie, 2024, 47 (4), 368–380. (In Russian). DOI: 10.21285/2686-9993-2024-47-4-368-380.
11. Rustamov, M.M.U. Influence of sulfate-reducing bacteria (SRB) during oil production. Universum: Tekhnicheskie Nauki: Elektronnyi Nauchnyi Zhurnal, 2024, 6 (123). (In Russian). DOI: 10.32743/UniTech.2024.123.6.17721. Available at: https://7universum.com/ru/tech/archive/item/17721
12. Kantyukov, R.R., Zapevalov, D.N., and Vagapov, R.K. Analysis of the application and impact of carbon dioxide media on the corrosion state of oil and gas facilities. Journal of Mining Institute, 2021, 250, 578–586. DOI: 10.31897/PMI.2021.4.11.
13. Shkodin, A.A. and Tlekhusezh, M.A. Corrosion and methods of struggle against it in oil industrial branches. Nauchnoe Obozrenie. Pedagogicheskie Nauki, 2019, 4–4, 97–101. (In Russian).
14. Kadyrov, Ya.A. Corrosion of equipment of oil production, gathering, and processing systems. Nauka i Mirovozzrenie, 2024, 27, 462–465. (In Russian).
15. Chudakova, M.V., Ovchinnikov, K.A., Ulyanov, D.N., Kunakova, A.M., Saifutdinova, L.R., Pimenov, A.A., and Maximov, A.L. Carbon dioxide corrosion inhibitors: current state of research and development. Journal of Mining Institute, 2025, 271, 3–21.
16. Novoselova, E.A. and Ivakhnyuk, S.G. Selection of corrosion resistant steels and iron-based alloys to reduce damage from corrosion of oil pipelines. Tekhnosfernaya Bezopasnost, 2021, 2 (31), 11–20. (In Russian).
17. Bogatov, M.V., Yudin, P.E., and Amosov, A.P. The use of internalmultifunctional coatings for pump and compressor pipes to protect against the formation of asphalt, resin and paraffin deposits. Neftegazovoe Delo, 2023, 21 (3), 149–160. (In Russian). DOI: 10.17122/ngdelo-2023-3-149-160.
18. Bikmasov, R.G. Problems of application of polymer-reinforced pipes at facilities of field oil and gas pipelines. Voprosy Razvitiya Sovremennoy Nauki i Tekhniki, 2021, 1, 5–8. (In Russian).
19. Valitov, B.R., Yunusova, A.F., and Ismagilov, I.R. Prospects for the use of polymer reinforced pipes in the oil and gas industry. Ekonomika Stroitelsva, 2022, 6, 116–118. (In Russian).
20. Gabbasov, A.I., Romanchuk, A.S., Vinogradov, P.V., Burkutbaev, A.B., Gundorova, I.G., and Valiakhmetov, R.I. Improvement of approaches to strength calculations of flexible polymer-reinforced pipes with non-metallic reinforcement. Ekspositsiya Neft Gaz, 2024, 8, 122–126. (In Russian). DOI: 10.24412/2076-6785-2024-8-122-126.
21. Shcherban, P.S. Development of quality criteria systems for polymer reinforced pipes and their connections. questions of mathematical processing of these indicators. Izvestiya Samarskogo Nauchnogo Tsentra Rossiyskoy Akademii Nauk, 2024, 26 (2), 80–95. (In Russian). DOI: 10.37313/1990-5378-2024-26-2-80-95.

Article reference