Evaluation of corrosion resistance of materials under conditions of moisture condensation in the presence of carbon dioxide

The paper investigates aspects of the development of corrosion processes under conditions of moisture condensation in the gas phase in the presence of carbon dioxide, which lead to the formation of local damage. The authors developed and tested a methodology for conducting steels corrosion testing The causes of the formation and the corrosive effect of moisture condensation on steel under conditions of carbon dioxide corrosion at gas production facilities are analyzed. It was found that at elevated temperatures, when the temperature difference is higher, more moisture condenses on the surface of the steel, which leads to an increase in the rate of both general and local corrosion by 2–3 times, compared to room temperature. The increased localization of corrosion processes under conditions of moisture condensation and the presence of CO2 makes the depth index of steel corrosion much higher than the general corrosion rate. When assessing the corrosiveness of environments with condensation of the aqueous phase, the rate of corrosion associated with the depth of the observed corrosion damage should be taken into account. According to the test results, it was determined that samples from the weld compared with the sample from the main body of the pipe differ in the degree of localization of corrosion in conditions of moisture condensation.

corrosion resistance, moisture condensation, corrosion rate, local corrosion, carbon dioxide, local corrosion defects

1. S a a k i y an , L . S ., E f r e mo v , A . P . , S o b o l ev a , I . A ., Zashchita neftegazopromyslovogo oborudovaniya ot korrozii [Protection of oil and gas equipment against corrosion], Moscow: Nedra, 1982.

2. M u s t af i n , F . M. , K u zn e t s o v , M . V . , V a s i l iev , G . G . , e t al . Zashchita truboprovodov ot korrozii [Protection of pipelines against corrosion], St Petersburg: Nedra, 2005.

3. Z a p ev a lo v , D .N . , V a ga pov , R . K . , Ib a tu l lin , K . A ., Otsenka faktora vnutrenney korrozii ob"yektov dobychi PAO “Gazprom” s povyshennym soderzhaniyem uglekislogo gaza [Assessment of the internal corrosion factor of Gazprom’s production facilities with a high carbon dioxide content], Nauka i tekhnika v gazovoy promyshlennosti, 2018, No 3 (75), pp. 59–71.

4. V a g ap ov , R . K. , F e d ot ov a , A . I . , Z a p e v alo v , D . N . , S t re l n iko va , K . O ., Korrozionnaya agressivnost razlichnykh ekspluatatsionnykh faktorov na uglevodorodnykh mestorozhdeniyakh, soderzhashchikh dioksid ugleroda [Corrosive aggressiveness of various operational factors in hydrocarbon fields containing carbon dioxide], Vesti gazovoy nauki, 2019, No 2 (39), pp. 130–137.

5. S l ug in , P . P . , P o l yan sk y, A .V ., Optimalny metod borby s uglekislotnoy korroziey truboprovodov na Bovanenkovskom NGKM [The optimal method of combating carbon dioxide corrosion of pipelines at the Bovanenkovo oil and gas condensate field], Nauka i tekhnika v gazovoy promyshlennosti, 2018, No 2 (74), pp. 104–109.

6. M o i s ee v , V . V. , I s ma g i l ov , I . I . , T k e sh e li a d z e , B . T ., Obespechenie bezopasnoy ekspluatatsii Bovanenkovskogo NGKM v usloviyakh agressivnogo vozdeystviya CO2 [Ensuring the safe operation of the Bovanenkovo oil and gas condensate field under the aggressive effects of CO2], Proceedings of the 11th International Scientific and Technical Conference “Diagnostics of equipment and pipelines exposed to hydrogen sulfide-containing media”, Moscow: State University of Oil and Gas named after I. Gubkin, 2017.

7. K o r y a k in , A .Y u . , D ik a mo v , D . V . , K o linchenko, I.V., Yusupov, A.D., Zapev a lo v , D . N . , Va g ap ov , R . K ., Opyt podbora ingibitorov korrozii dlya zashchity ot uglekislotnoy korrozii obyektov vtorogo uchastka achimovskikh otlozheniy Urengoyskogo neftegazokondensatnogo mestorozhdeniya [The experience of selection of corrosion inhibitors for protection against carbon dioxide corrosion of objects of the second section of the Achimov deposits of the Urengoy oil and gas condensate field], Oborudovanie i tekhnologii dlya neftegazovogo kompleksa, 2018, No 6, pp. 48–55.

8. B a y d in , I . I . , K h a r i to n o v , A . N . , Velichkin, A.V., Ilyin, A.V., Podol ya n sk y, E . S .,Vliyanie uglekisloty v prirodnom gaze gazokondensatnoy zalezhi nizhnemelovykh otlozheniy Yubileynogo neftegazokondensatnogo mestorozhdeniya na ekspluatatsiyu UKPG-NTS [The effect of carbon dioxide in natural gas from a gas condensate deposit of the Lower Cretaceous deposits of the Yubileynoye oil and gas condensate field on the operation of the UKPG-NTS], Nauka i tekhnika v gazovoy promyshlennosti, 2018, No 2,pp. 23–35.

9. P r o k o p o v , A .V . , K u b an o v , A . N . , I stomin, V.A., Snezhko, D.N., Chepurn ov , A . N . , A ko p yan , A . K . ,Spetsifika promyslovoy podgotovki gazov achimovskikh zalezhey [The specifics of field gas preparation of the Achimov deposits], Vesti gazovoy nauki, 2018, No 1, pp. 226–234.

10. A r t e me n k o v , V . Y u . , K o r y aki n , A . Y u . , Shustov, I.N., Dikamov, D.V., Shishk ov , E . O . , Yus up ov , A . D .,Organizatsiya korrozionnogo monitoringa na obyektakh vtorogo uchastka achimovskikh otlozheniy Urengoyskogo neftegazokondensatnogo mestorozhdeniya [Organization of corrosion monitoring at the objects of the second section of the Achimov deposits of the Urengoy oil and gas condensate field], Gazovaya promyshlennost, 2017, Special Issue, No 2, pp. 74–78.

11. CO2 Corrosion Control in Oil and Gas Production, Kermani, M.V., Smith, L.M., (Eds.), Publ. for EFC by The Institute of Materials, London, 1997.

12. C r o l et , J . - L . , B on i s , M .R . , pH-Measurements in Aqueous CO2 Solutions under High Pressure and Temperature, Corrosion, 1983, V. 39, No 2, pp. 39–46.

13. Gazprom Standards 9.3-007–2010: Protection against corrosion. Laboratory Testing Methods of Corrosion Inhibitors for Equipment for the Production, Transportation and Processing of Corrosive Gas.

14. R o s e n f el d , I . L. , Z h ig a lo v a K . A . , Uskorennye metody korrozionnykh ispytaniy metallov (teoriya i praktika) [Accelerated Methods of Corrosion Testing of Metals (Theory and Practice)], Moscow: Metallurgiya, 1966.

15. State Standards GOST R 9.905–2007: Methods of corrosion tests. General requirements.

16. State Standards GOST 9.908–85: Metals and alloys. Methods for determining the indicators of corrosion and corrosion resistance.

17. Gazprom Standards9.0-001–2018: Protection against corrosion. Key Points.

18. State Standards GOST 9.502–82: Unified system of protection against corrosion and aging. Metal corrosion inhibitors for water systems. Corrosion Test Methods.

19. Gazprom Standards 9.3-011–2011: Protection against corrosion. Inhibitory corrosion protection of fishing facilities and pipelines. Primary requirements.

20. K u zn e t sov , Y u. I . , A n d r e ev , N . N . , I b a t ul l in , K . A . , O regulirovanii pH nizshimi aminami pri uglekislotnoy korrozii stali [On pH regulation by lower amines in carbon dioxide corrosion of steel], Zashchita metallov, 1999, No 6 (35), pp. 586–591.

21. Engineering Reference Data. URL: https://dpva.ru/Guide/GuidePhysics/Humidity/MaximumMoisture ContentAir (reference date 28/01/2020).

22. A s h e r , S . A . , S u n , W . , Oj if i n n i , R . , Pa c h e co , J . , Li , C h . , N el s o n , J . , L i ng , S h . , C-2012-0001303 Top of the Line Corrosion Prediction in Wet Gas Pipelines, NACE Conference CORROSION 2012.

23. G u n a l tu n , Y .M . , L a r r e y , D ., Water-condensation rate critical in predicting, preventing TLC in wet-gas lines, Oil & Gas Journal, 2000, V. 98, Issue 28, pp. 58–63.

24. Chen, Y., Zhang, L., Qin, H., Xu, L., Lu, M., Effects of Temperature on CO2 Top of Line Corrosion of Pipeline Steel, NACE Conference CORROSION 2011, NACE-11327.

25. S i ng e r , M ., Study of the Localized Nature of Top of the Line Corrosion in Sweet Environment, Corrosion, 2017, V. 73, Is. 8, p. 201.