Some Results of Corrosion Monitoring at Offshore Gas Processing and Transportation Facilities
DOI:
https://doi.org/10.52171/herald.382Keywords:
marine work, OOGPFP, corrosion, ecology, product properties, corrosion protectionAbstract
The long-term operation of fixed platforms used for offshore oil and gas production fixed platforms (OOGPFP), and the technological equipment installed on them, in extreme marine climatic conditions has led to significant wear and tear. It is well known that the metal structures of OOGPFP s and their associated equipment are affected by a wide range of corrosion factors in offshore oil and gas production conditions. Clearly, production will continue until the productive formations are completely depleted. During this period, it is essential to ensure safe working conditions while maintaining high product quality. One important task in protecting structures from corrosion is the annual monitoring of pipelines and equipment that pose the greatest risk in the event of an accident, as well as production facilities, centralized collection units (CCU) and centralized compressor unit (CComU). This process involves taking corrosion samples and measuring corrosion using an electrical resistance sensor, as well as measuring the residual wall thickness of the equipment. This article presents the results of scientific and applied research and testing to improve current anti-corrosion protection systems.
References
1. Zavyalov V.V. Problemy ekspluatacionnoj nadyozhnosti truboprovodov na pozdnej stadii razrabotki mestorozhdenij. – M.: OAO VNIIOENG, 205–332 s.
2. Ismailov G.G., Iskenderov E.H., Fataliev V.M., Gurbanov A., Ismajilova F.B. Nekotorye aspekty povysheniya effektivnosti osvoeniya gazokondensatnyh resursov v morskih usloviyah // SOCAR Proceedings, №1 (2023), s. 122–125.
3. Medvedeva M.L. Korroziya i zashchita ot korrozii oborudovaniya pri pererabotke nefti i gaza. – M., Izd-vo Nefti Gaz RGUNG, 2005. – 312 s.
4. Adygezalova M.B. Investigation of the efficiency of multifunctional compositions against corrosion and salt precipitation // Nafta-Gaz 2025, no. 1, pp. 478–483.
5. Gurbanov H.R., Pashayeva S.M. The inhibitory effect of selected reagents on carbon steel corrosion
Azərbaycan Mühəndislik Akademiyasının Xəbərləri
2026, cild 18 (1), s. 67-76
R.Y. Qəniyeva, M.B. Adıgözəlova, S.R.Rəsulov
Herald of the Azerbaijan Engineering Academy
2026, vol. 18 (1), pp. 67-76
R.Y. Ganiyeva, M.B. Adıgozelova, S.R. Rasulov
in formation water containing hydrogen sulfide// Nafta-Gaz 2024, no. 1, pp. 55-56.
6. Razrabotka, vnedrenie i sovershenstvovanie tekhnologij zashchity ot korrozii oborudovaniya, truboprovodov i metallokonstrukcij na mestorozhdeniyah SP Vetsovpetro. Otchet NIPImorneftegaz po teme NIR V-1 / A.L. Bushkovskij, L.K. Tui, T.N. Gallyamov i dr. Vungtau, 2010. – 144 s.
7. Otchet Centra razvitiya i peredachi tekhnologij (STAT) po kontraktu №1280/09/T-NS/VSP-5-NNUDCN.VPI «Monitoring vnutrennej korrozii tekhnologicheskogo oborudovaniya i truboprovodov sistem sbora, podgotovki, transporta nefti i gaza na MSP» / F.K. Than, N.N. An, i dr. – g. Hanoj, 2011. – 188 s.
8. Fomin G.G. Korroziya i zashchita ot korrozii. Enciklopediya mezhdunarodnyh standartov. – m.: ıpk, ızd-vo standartov, 1999. – 520 s.
9. Peabody A.W. Peabody’s control of pipeline corrosion. Second edition. – NACE Press. Houston, USA, 2001. – 347 р.
10. Melchers R.E. Transient early and longer-term influence of bacteria on marine corrosion of steel pH. – Corrosion Engineering, Science and Technology, 2010, Vol. 45 No. 4, pp. 257–261.
11. Bushkovskij A.L., Hismatulin R.Ya. i dr. Tekhniko-ekonomicheskoe obosnovanie vybora tolshchiny stenki i materiala trub dlya stroitelstva, remonta i rekonstrukcii promyslovyh truboprovodov // Neftyanoe Hozyajstvo, №9, 2006. – s. 23–28.
12. Otchet Po NİR V-2 Firmy Weatherford Asia Pacific. Kontrakt №1234/09/N-5/Vsp5-Weathas «Razrabotka tekhnologii predotvrashcheniya obrazovaniya sulfatvosstanavlivayushchih bakterij v sistemah podgotovki poputnoj vody na obektah SP «Vetsovpetro» g. Vungtau, 2011. – 163 s.
13. Fiziko-Himicheskie issledovaniya poputnodobyvaemyh vod na mestorozhdeniyah «SP Vetsovpetro» za 2010. Otchet NİPİmorneftegaz po teme NİR P-7 / F.S. Shon, N.N. Zung, H.Ch. Tyu i dr. – G. Vungtau, 2010. – 92 s.
14. Sitenkov V.T., Perevozchenko V.I. Raschet skorosti korrozii truboprovodov, transportiruyushchih neftegazovuyu smes // Neft. Hoz-Vo, 2004, №11, s. 104–107, 4 il., Tabl. 2 il. – Bibl. 2. Rus.; rez. angl. – Ru. ISSN 0028-2448
15. ASM Handbook, Volume 13B, Corrosion: Materials, USA, 2005.
16. Ismayilov G.G., Iskenderov E.Kh., Ismayilova F.B. Problems of hydrodynamic corrosion in multiphase pipelines. Phusicochemical problems of materials protection of metals and physical chemistry surfaces, Vol. 57, №1, 2023, Pp. 147–152.
17. Rzayev A.G., Rasulov S.R., Orujev V.V., Mustafayeva G.R. Mathematical modeling of the process of oil structure formation in the reservoir of oil fields. Herald of the Azerbaijan Engineering Academy, 2016, №3, pp. 98-101
18. Aykan N.F., Malikova I.H., Efendi A.C., Babayev E.M., Rustamova C.T., Aliyeva N.R., Yunusova F.A. Neutralization of Wastewater Obtained from the Production of Alkyd Resins. Azərbaycan Mühəndislik Akademiyasının Xəbərləri, 2023, Vol.15, №1, pp.
19. Israfilova Z.T. Study of some Heterocyclic Compounds Containing Rhodanide Group as Antioxidant Additives. Azərbaycan Mühəndislik Akademiyasının Xəbərləri, 2022,Vol. 14, №4. pp.
Downloads
Published
How to Cite
Issue
Section
License
Copyright (c) 2026 R.Y. Ganiyeva, M.B. Adigozalova, S.R. Rasulov
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.
