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Effect of Microalloying with Ti on the Corrosion Behaviour of Low Carbon Steel in a 3.5 wt.% NaCl Solution Saturated with CO2

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Języki publikacji
EN
Abstrakty
EN
A problem is defined to investigate the effect of titanium traces on the corrosion behaviour of low carbon steel. In theory titanium effects surface properties like abrasion resistance in medium carbon steels and corrosion resistance in low as well as medium carbon steels. The present research as indicated by the topic is aimed to experimentally mark the effect of titanium traces on corrosion resistance in the available low carbon steel specimens. The effect of microalloying with titanium (i.e.0.02wt.%) on the corrosion behavior of low carbon steel in a 3.5 wt.% NaCl solution was studied by electrochemical, SEM, and Raman spectroscopy techniques. The electrochemical results showed that the corrosion of the Ti-bearing steel improved by around 30% compared with the Ti-free steel. The titanium microalloying led to the formation of a more compact corrosion product layer on the metal surface. The SEM analysis showed that the Ti-bearing sample had a smoother surface compared with the Ti-free steel.
Rocznik
Strony
5--10
Opis fizyczny
Bibliogr. 31 poz., il., tab., wykr.
Twórcy
  • AGH University of Science and Technology, Kraków, Poland
Bibliografia
  • [1] Yu, C., Wang, H., Gao, X. & Wang, H. (2020). Effect of Ti Microalloying on the Corrosion Behavior of Low-Carbon Steel in H2S/CO2 Environment. Journal of Materials Engineering and Performance. 29(9), 6118-6129. DOI:10.1007/s11665-020-05077-1.
  • [2] Liu, Z., Gao, X., Du, L., Li, J., Zheng, C. & Wang, X. (2018). Corrosion mechanism of low-alloy steel used for flexible pipe in vapor-saturated H2S/CO2 and H2S/CO2-saturated brine conditions. Materials and Corrosion 69(9), 1180-1195. DOI:10.1002/maco.201810047.
  • [3] Palumbo, G., Banaś, J., Bałkowiec, A., Mizera, J. & Lelek-Borkowska, U. (2014). Electrochemical study of the corrosion behaviour of carbon steel in fracturing fluid. J. Solid State Electrochem. 18(11), 2933-2945. DOI:10.1007/s10008-014-2430-2.
  • [4] Liu, Z.-G., Gao, X.-H., Du, L.-X., Li, J.-P., Li, P. & Misra, R.D.K. (2017). Comparison of corrosion behaviors of low-alloy steel exposed to vapor-saturated H2S/CO2 and H2S/CO2-saturated brine environments. Materials and Corrosion 68(5), 566-579. https://doi.org/10.1002/maco. 201609165.
  • [5] Rozenfeld, I.L. (1981). Corrosion Inhibitors. New York: McGraw-Hill.
  • [6] Palumbo, G., Kollbek, K., Wirecka, R., Bernasik, A. & Górny, M. (2020). Effect of CO2 partial pressure on the corrosion inhibition of N80 carbon steel by gum arabic in a CO2-water saline environment for shale oil and gas industry. Materials. 13(19), 4245, 1-24. https://doi.org/10.3390/ma13194245.
  • [7] Bai, H., Wang, Y., Ma, Y., Zhang, Q., Zhang, N. (2018). Effect of CO2 partial pressure on the corrosion behavior of J55 carbon steel in 30% crude oil/brine mixture. Materials. 11(9), 1765, 1-15. DOI:10.3390/ma11091765.
  • [8] Cui, L., Kang, W., You, H., Cheng, J., & Li, Z. (2021). Experimental study on corrosion of J55 casing steel and N80 tubing steel in high pressure and high temperature solution containing CO2 and NaCl. Journal of Bio- and Tribo-Corrosion. 7(1), 13, 1-14. DOI:10.1007/s40735-020-00449-5.
  • [9] Islam, M.A., & Farhat, Z.N. (2015). Characterization of the corrosion layer on pipeline steel in sweet environment. Journal of Materials Engineering and Performance. 24(8), 3142-3158. DOI: 10.1007/s11665-015-1564-4.
  • [10] Zhang, T., Liu, W., Yin, Z., Dong, B., Zhao, Y., Fan, Y., Wu, J., Zhang, Z. & Li, X. (2020). Effects of the addition of Cu and Ni on the corrosion behavior of weathering steels in corrosive industrial environments. Journal of Materials Engineering and Performance. 29(4), 2531-2541. DOI: 10.1007/s11665-020-04738-5.
  • [11] Weng, L., Du, L. & Wu, H. (2018). Corrosion behaviour of weathering steel with high-content titanium exposed to simulated marine environment. International Journal of Electrochemical Science. 13(6), 5888-5903. DOI: 10.20964/2018.06.61.
  • [12] Marcus, P. (1994). On some fundamental factors in the effect of alloying elements on passivation of alloys. Corrosion Science. 36(12), 2155-2158. https://doi.org/10.1016/0010-938X(94)90013-2.
  • [13] Liu, Z., Gao, X., Du, L., Li, J., Li, P. (2016). Corrosion Behaviour of Low-Alloy Steel with Titanium Addition Exposed to Seawater Environment. International Journal Electrochemical Science. 11(8), 6540-6551. DOI: 10.20964/2016.08.25.
  • [14] Banas, J., Lelek-Borkowska, U., Mazurkiewicz, B. & Solarski, W. (2007). Effect of CO2 and H2S on the composition and stability of passive film on iron alloys in geothermal water. Electrochim. Acta 52(18), 5704-5714. DOI: 10.1016/j.electacta.2007.01.086.
  • [15] Palumbo, G., Dunikowski, D., Wirecka, R., Mazur, T., Lelek-Borkowska, U., Wawer, K. & Banaś, J. (2021). Effect of Grain Size on the Corrosion Behavior of Fe-3wt.%Si-1wt.%Al Electrical Steels in Pure Water Saturated with CO2. Materials. 14(17), 5084, 1-19. https://doi.org/10.3390/ma14175084.
  • [16] Święch, D., Palumbo, G., Piergies, N., Pięta, E., Szkudlarek, A. & Paluszkiewicz, C. (2021). Spectroscopic investigations of 316L stainless steel under simulated inflammatory conditions for implant applications: the effect of tryptophan as corrosion inhibitor/hydrophobicity marker. Coatings. 11(9), 1097. https://doi.org/10.3390/coatings11091097.
  • [17] Święch, D., Paluszkiewicz, C., Piergies, N., Pięta, E., Kollbek, K. & Kwiatek, W.M. (2020). Micro- and nanoscale spectroscopic investigations of threonine influence on the corrosion process of the modified Fe surface by Cu nanoparticles. Materials. 13(20), 4482, 1-16. https://doi.org/10.3390/ma13204482.
  • [18] Chen, Z. & Yan, K. (2020). Grain refinement of commercially pure aluminum with addition of Ti and Zr elements based on crystallography orientation. Scientific Reports. 10(1), 16591, 1-8. https://doi.org/10.1038/s41598-020-73799-2.
  • [19] Kalisz, D. & Żak, P.L. (2015). Modeling of solute segregation and the formation of non-metallic inclusions during solidification of a titanium-containing steel. Kovove Materialy. 53(1), 35-41. DOI:10.4149/km_2015_1_35.
  • [20] Podorska, D., Drozdz, P., Falkus, J. & Wypartowicz, J. (2006). Calculations of oxide inclusions composition in the steel deoxidized with Mn, Si and Ti. Archives of Metallurgy and Materials. 51(4), 581-586. ISSN: 1733-3490.
  • [21] Zhang, M., Li, M., Wang, S., Chi, J., Ren, L., Fang, M. & Zhou, C. (2020). Enhanced wear resistance and new insight into microstructure evolution of in-situ (Ti,Nb)C reinforced 316 L stainless steel matrix prepared via laser cladding. Optics and Lasers in Engineering. 128, 106043, 1-10. DOI:10.1016/j.optlaseng.2020.106043.
  • [22] Sadeghpour, S., Kermanpur, A. & Najafizadeh, A. (2013). Influence of Ti microalloying on the formation of nanocrystalline structure in the 201L austenitic stainless steel during martensite thermomechanical treatment. Materials Science and Engineering: A. 584, 177-183. DOI:10.1016/j.msea.2013.07.014.
  • [23] Zhang, L.M., Ma, A.L., Hu, H.X.; Zheng, Y.G., Yang, B.J. & Wang, J.Q. (2017). Effect of microalloying with Ti or Cr on the corrosion behavior of Al-Ni-Y amorphous alloys. Corrosion. 74(1), 66-74. https://doi.org/10.5006/2451.
  • [24] Mustafa, A.H., Ari-Wahjoedi, B. & Ismail, M.C. (2013). Inhibition of CO2 corrosion of X52 steel by imidazoline-based inhibitor in high pressure CO2-water environment. Journal of Materials Engineering and Performance. 22(6), 1748-1755. DOI: 10.1007/s11665-012-0443-5.
  • [25] Nie, X.P., Yang, X.H. & Jiang, J.Z. (2009) Ti microalloying effect on corrosion resistance and thermal stability of CuZr-based bulk metallic glasses. Journal of Alloys Compounds. 481(1), 498-502. DOI: 10.1016/j.jallcom.2009.03.022.
  • [26] Palumbo, G., Górny, M. & Banaś, J. (2019). Corrosion inhibition of pipeline carbon steel (N80) in CO2-saturated chloride (0.5 M of KCl) solution using gum arabic as a possible environmentally friendly corrosion inhibitor for shale gas industry. Journal of Materials Engineering and Performance. 28(10), 6458-6470. https://doi.org/10.1007/ s11665-019-04379-3.
  • [27] Heuer, J.K. & Stubbins, J.F. (1999). An XPS characterization of FeCO3 films from CO2 corrosion. Corros. Sci. 41(7), 1231-1243. https://doi.org/10.1016/S0010-938X(98)00180-2.
  • [28] Mora-Mendoza, J.L., Turgoose, S. (2002) Fe3C influence on the corrosion rate of mild steel in aqueous CO2 systems under turbulent flow conditions. Corrosion Science. 44(6), 1223-1246. DOI:10.1016/S0010-938X(01)00141-X.
  • [29] Criado, M., Martínez-Ramirez, S. & Bastidas, J.M. (2015). A Raman spectroscopy study of steel corrosion products in activated fly ash mortar containing chlorides. Construction and Building Materials. 96, 383-390. http://dx.doi.org/10.1016/j.conbuildmat.2015.08.034.
  • [30] Zhang, X., Xiao, K., Dong, C., Wu, J., Li, X. & Huang, Y. (2011). In situ Raman spectroscopy study of corrosion products on the surface of carbon steel in solution containing Cl− and SO42. Engineering Failure Analysis. 18(8), 1981-1989. DOI:10.1016/j.engfailanal.2011.03.007.
  • [31] Święch, D., Paluszkiewicz, C., Piergies, N., Lelek-Borkowska, U. & Kwiatek, W.M. (2018). Identification of corrosion products on Fe and Cu metals using spectroscopic methods. Acta Physica Polonica Series A. 133(4), 286-288. DOI: 10.12693/APhysPolA.133.286.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023)
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-4fd8c0f8-33f9-41a1-ba4d-d26885fa2c11
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