Study of hydrogenation and corrosion of steel equipment and pipelines at the production facilities of H 2 S -containing hydrocarbon raw materials

R. K. Vagapov

doi:10.22349/1994-6716-2021-106-2-170-181

Study of hydrogenation and corrosion of steel equipment and pipelines at the production facilities of H₂S -containing hydrocarbon raw materials

R. K. Vagapov

https://doi.org/10.22349/1994-6716-2021-106-2-170-181

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Abstract

The impact of hydrogen sulfide raw materials on steel equipment and pipelines is associated not only with corrosion processes, but also with the hydrogenation of used carbon and low-alloy steels. This can lead to the loss of their strength properties and the subsequent destruction of equipment operated under conditions of increased operating pressures. Such corrosive-mechanical effects associated with the penetration of hydrogen into steel are the most dangerous from the point of view of the safety and reliability of the operation of facilities for the production of hydrocarbon fluids. The effect of H₂S on the main types of structural steels was investigated according to the results of autoclave tests. The formation of blistering (blistering) and cracks on the surface of steels due to the effect of hydrogen on the steel was recorded. A study of the phase composition of corrosion products and their possible effect on the processes of corrosion and hydrogenation of steel has been carried out.

Keywords

corrosive destruction of equipment, carbon dioxide and hydrogen sulfide corrosion, hydrogenation of steel, liquid condensation

About the Author

R. K. Vagapov

All-Union Scientific Research Institute of Natural Gases and Gas Technologies (VNIIGAZ)
Russian Federation

Cand Sc. (Chem)

15/1 Proektiruemyi proezd 5537, 142717 Razvilka, Moscow Region

References

1. Saakiyan, L.S., Efremov, A.P., Soboleva, I.A., Zashchita neftegazopromyslovogo oborudovaniya ot korrozii [Protection of oil and gas equipment against corrosion], Moscow: Nedra, 1982.

2. Veliyulin I.I., Kantyukov R.A., Yakupov N.M., et al., O korrozii truboprovodov [About corrosion of pipelines], Nauka i tekhnika v gazovoy promyshlennosti, 2015, No 1 (61), pp. 45–50.

3. Mustafin, F.M., Kuznetsov, M.V., Vasiliev, G.G., et al., Zashchita truboprovodov ot korrozii [Protection of pipelines against corrosion], St Petersburg: Nedra, 2005.

4. Kantyukov, R.R., Zapevalov, D.N., Vagapov, R.K., Otsenka opasnosti vnutrenney uglekislotnoy korrozii promyslovykh truboprovodov na gazovykh i gazokondensatnykh mestorozhdeniyakh [Assessment of the hazard of internal carbon dioxide corrosion of field pipelines in gas and gas condensate fields], Bezopasnost truda v promyshlennosti, 2021, No 2, pp. 56–62. DOI: 10.24000/0409-2961-2021-2-56-62.

5. Vagapov, R.K., Zapevalov, D.N., Korrozionnaya agressivnost ekspluatatsionnykh usloviy po otnosheniyu k stalnomu oborudovaniyu i truboprovodam na obiektakh dobychi gaza, soderzhashchego CO2 [Corrosiveness of operating conditions towards steel equipment and pipelines in CO2 gas production facilities], Metallurg, 2021, No 1, pp. 46–55.

6. Rozenfeld, I.L., Frolova, L.V., Brusnikina, V.M., Investigation of the corrosion and hydrogen absorption of steel and inhibition of these processes in aqueous media containing hydrogen sulfide, Soviet Scientific Reviews, Section B. Chemistry reviews, Amsterdam: OPA Ltd, 1987, V. 8, pp. 115–162.

7. Miyasaka, A., Kanamaru, T., Ogawa, H., Critical stress for stress corrosion cracking of duplex stainless steel in sour environments, Corrosion, 1996, V. 52, No. 8, pp. 592–599.

8. Vagapov, R.K., Korrozionnoe razrushenie stalnogo oborudovaniya i truboprovodov na obiektakh gazovykh mestorozhdeniy v otnoshenii agressivnykh komponentov [Corrosion destruction of steel equipment and pipelines at gas field facilities in relation to aggressive components], Tekhnologiya metallov, 2021, No 3, pp. 47–54. DOI: 10.31044/1684-2499-2021-0-3-47-54.

9. State Standard GOST 1579-93: Provoloka. Metod ispytaniya na peregib [Wire. Kink test method], Moscow: Standartinform, 2006.

10. Filippov, A.G., Tokman, A.K., Potapov, A.G., et al., Ekspluatatsiya skvazhin Astrakhanskogo gazokondensatnogo mestorozhdeniya [Operation of wells in the Astrakhan gas condensate field], Moscow: Gazprom ekspo Ltd, 2010.

11. Mokshaev, A.N., Sorokin, N.I., Baryshev, S.N., Obespechenie nadezhnosti i effektivnosti ekspluatatsii oborudovaniya opasnykh proizvodstvennykh obektov Orenburgskogo NGKM pri sverkhproektnom sroke sluzhby [Ensuring the reliability and efficiency of operation of equipment at hazardous production facilities of the Orenburg oil and gas condensate field with an over-design service life], Gazovaya promyshlennost, 2018, No 3 (765), pp. 39–41.

12. Shaposhnikov, P.A., Bespalova, E.V., Issledovanie vliyaniya vodoroda na skorost korrozii stali v serovodorodsoderzhashchey srede Astrakhanskogo gazokondensatnogo mestorozhdeniya [Investigation of the effect of hydrogen on the corrosion rate of steel in the hydrogen sulfide-containing environment of the Astrakhan gas condensate field], Zashchita okruzhayushchey sredy v neftegazovom komplekse, 2012, No 8, pp. 28–31.

13. Vagapov, R.K., Kuznetsov, Yu.I., Frolova, L.V., Vozmozhnosti ispolzovaniya letuchikh ingibitorov dlya zashchity ot serovodorodnoy korrozii stali v neftegazovoy otrasli [Possibilities of using volatile inhibitors for the protection against hydrogen sulfide corrosion of steel in the oil and gas industry], Gazovaya promyshlennost, 2009, No 4 (630), pp. 68–72.

14. Kuznetsov, Yu.I., Vagapov, R.K., Getmansky, M.D., Vozmozhnosti ingibirovaniya koprrozii oborudovaniya i truboprovodov v neftegazovoy promyshlennosti [Opportunities for corrosion inhibition of equipment and pipelines in the oil and gas industry], Korroziya: materialy, zashchita, 2009, No 3, pp. 20–25.

15. Reformatskaya, I.I., Vliyanie strukturoobrazuyushchikh faktorov na korrozionnoelektrokhimicheskoe povedenie zheleza i nerzhaveyushchikh staley [Influence of structure-forming factors on the corrosion-electrochemical behavior of iron and stainless steels], Rossiyskiy khimicheskiy zhurnal, 2008, V. 52, No 5, pp. 16–24.

16. Amezhnov, A.V., Rodionova, I.G., Vliyanie khimicheskogo i fazovogo sostava nemetallicheskikh vklyucheniy na korrozionnuyu stoykost uglerodistykh i nizkolegirovannykh staley v vodnykh sredakh, kharakternykh dlya usloviy ekspluatatsii neftepromyslovykh truboprovodov [Influence of the chemical and phase composition of non-metallic inclusions on the corrosion resistance of carbon and low-alloy steels in aqueous media typical for the operating conditions of oil-field pipelines], Metallurg, 2019, No 7, pp. 45–52

17. Vagapov, R.K., Zapevalov, D.N., Ibatullin, K.A., Otsenka korrozionnoy stoykosti materialov v usloviyakh kondensatsii vlagi i nalichiya dioksida ugleroda [Evaluation of the corrosion resistance of materials under conditions of moisture condensation and the presence of carbon dioxide], Voprosy Materialovedeniya, 2020, No 1 (101), pp. 163–175. DOI: 10.22349/1994-6716-2020-101-1-163-175.

18. Vagapov, R.K., Zapevalov, D.N., Prakticheskie aspekty ispolzovaniya diagnosticheskikh metodov sovmestno s drugimi dannymi kontrolya korrozii i imitatsionnymi ispytaniyami pri ekspluatatsii obektov dobychi gaza v korrozionno-agressivnykh usloviyakh [Practical aspects of the use of diagnostic methods in conjunction with other data on corrosion control and simulation tests during the operation of gas production facilities in corrosive conditions], Defektoskopiya, 2020, No 7, pp. 61–76. DOI: 10.31857/S0130308220070076

19. Golubtsov, V.A., Ryabchikov, I.V., Mizin, V.G., Vliyanie khimicheski aktivnykh elementov na vodorodnoe rastreskivanie stali dlya trub [Influence of reactive elements on hydrogen cracking of steel for pipes], Stal, 2016, No 3, pp. 50–53

20. Rodionova, I.G., Baklanova, O.N., Amezhnov, A.V., Knyazev, A.V., Zaytsev, A.I., Feoktistova M.V., Vliyanie nemetallicheskikh vklyucheniy na korrozionnuyu stoykost uglerodistykh i nizkolegirovannykh staley dlya neftepromyslovykh truboprovodov [Influence of non-metallic inclusions on the corrosion resistance of carbon and low-alloy steels for oilfield pipelines], Stal, 2017, No 10, pp. 41–48.

21. Ghosha, G., Rostron, P., Garg, R., Panday, A., Hydrogen induced cracking of pipeline and pressure vessel steels: A review, Engineering Fracture Mechanics, 2018, V. 199, pp. 609–618. https://doi.org/10.1016/j.engfracmech.2018.06.018.

22. Ivanov, E.S., Guzenkova, A.S., Ivanov, S.S., Navodorozhivanie trubnoy stali pri ekspluatatsii [Hydrogenation of pipe steel during exploitation], Tekhnologiya metallov, 2016, No 1, pp. 46–48.

23. Ivanov, E.S., Brodsky, M.L., Ryabov, Yu.V., Timonin, A.V., Issledovanie korrozionnoy stoykosti i sklonnosti k korrozionno-mekhanicheskomu razrusheniyu novoy trubnoy stali 08KhMFCHA v serovodorodsoderzhashchikh sredakh neftepromyslov [Investigation of corrosion resistance and tendency to corrosion-mechanical destruction of new pipe steel 08KhMFCHA in hydrogen sulfidecontaining environments of oil fields], Praktika protivokorrozionnoy zashchity, 2009, No 3 (53), pp. 8–19.

24. Tsygankova, L.E., Fedorov, V.A., Fomenkov, O.A., Pluzhnikova, T.N., Esina, M.N., Kopylova, E.Yu., Ingibirovanie korrozii stali i diffuzii vodoroda v metall v serovodorodnouglevodorodnykh sredakh [Inhibition of corrosion of steel and diffusion of hydrogen into metal in hydrogen sulfide-hydrocarbon media], Praktika protivokorrozionnoy zashchity, 2009, No 3 (53), pp. 66–71.

25. Tetyueva, T.V., Rykhlevskaya, M.S., Efimova, G.A., Altukhova, N.N., Vliyanie temperatury i ingibirovaniya na protsess sulfidnoy korrozii i intensivnost navodorozhivaniya nizkolegirovannykh trubnykh staley [Influence of temperature and inhibition on the process of sulfide corrosion and the intensity of hydrogenation of low-alloy pipe steels], Zashchita ot korrozii i okhrana okruzhayushchey sredy, Moscow: VNIIOENG, 1992, No 1, pp. 5–12

26. Silva, S.C., Silva, A.B., Ponciano Gomes J.A.C., Hydrogen embrittlement of API 5L X65 pipeline steel in CO2 containing low H2S concentration environment, Engineering Failure Analysis, 2021, V. 120, Article 105081. URL: https://doi.org/10.1016/j.engfailanal.2020.105081.

27. Tetyueva, T.V., Rykhlevskaya, M.S., Shmelev, P.S., Zakonomernosti sulfidnoy korrozii nizkolegirovannykh trubnykh staley [Regularities of sulfide corrosion of low-alloy pipe steels], Neftyanoe khozyaystvo, 1993, No 6, pp. 32–34.

28. Sun, W., Neљiж, S., Papavinasam, S., Kinetics of Corrosion Layer Formation. Part 2 – Iron Sulfide and Mixed Iron Sulfide/Carbonate Layers in Carbon Dioxide/Hydrogen Sulfide Corrosion, Corrosion, 2008, No 7, pp. 586–599. URL: https://doi.org/10.5006/1.3278494.

29. Zhou, C., Fang, B., Wang, J., et al., Effect of interaction between corrosion film and H2S / CO2 partial pressure ratio on the hydrogen permeation in X80 pipeline steel, Corrosion Engineering, Science and Technology, 2020, V. 55, No 5, pp. 392–399. URL: https://doi.org/10.1080/1478422X.2020.1737384.

Review

For citations:

Vagapov R.K. Study of hydrogenation and corrosion of steel equipment and pipelines at the production facilities of H₂S -containing hydrocarbon raw materials. Voprosy Materialovedeniya. 2021;(2(106)):170-181. (In Russ.) https://doi.org/10.22349/1994-6716-2021-106-2-170-181

ISSN 1994-6716 (Print)

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Study of hydrogenation and corrosion of steel equipment and pipelines at the production facilities of H2S -containing hydrocarbon raw materials