Abstract
The paper presents results of comparative studies of corrosion resistance and corrosion-mechanical strength for low-magnetic shipbuilding steels of alloying systems Mn–C, C–Mn–Ni, Cr–Ni, Cr–Ni–Mo, and Cr–Ni–Mn–N, produced using various hardening mechanisms. It is shown that nitrogen-containing steels developed by CRISM Prometey constitute new constructional material superior in resistance to corrosion cracking in seawater compared with low-magnetic steels used in shipbuilding nowadays.
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Sagaradze, V.V. and Uvarov, A.I., Uprochnenie i svoistva austenitnykh stalei (Hardening and Properties of Austenitic Steels), Yekaterinburg: UrO, Ross. Akad. Nauk, 2013.
Bannykh, O.A. and Blinov, V.M., Dispersionno-tverdeyushchie nemagnitnye vanadiisoderzhashchie stali (Age-Hardenable Non-Magnetic Vanadium-Containing Steels), Moscow: Nauka, 1980.
Pridantsev, M.V., Talov, N.P., and Levin, D.L., Vysokoprochnye austenitnye stali (High-Strength Austenitic Steel), Moscow: Metallurgiya, 1969.
Kostina, M.V., Bannykh, O.A., and Blinov, V.M., Special features of steels alloyed with nitrogen, Met. Sci. Heat Treat., 2000, vol. 42, nos. 11–12, pp. 459–462.
Malyshevsky, V.A., Kalinin, G.Yu., and Kharkov, A.A., Development of high-strength structural steels: from the first experiments until present, Vopr. Materialoved., 2011, no. 1, pp. 17–27.
Oryshchenko, A.S., Mushnikova, S.Yu., Kharkov, A.A., and Kalinin, G.Yu., Study of stress corrosion cracking of austenitic steels in seawater, Proc. Eur. Corrosion Congr. EUROCORR’2010, September 13–17, 2010, Moscow, 2010.
Zhang, Y.S. and Zxu, X.M., Electrochemical polarization and passive film analysis of austenitic FeMn–Al steels in aqueous solutions, Corros. Sci., 1999, vol. 41, no. 9, pp. 1817–1833.
Barakhtin, B.K., Mushnikova, S.Yu., Rybin, V.V., and Kharkov, A.A., Detection of the conversion of translational energy into internal surface of elastic compressed steel in aggressive media, Vopr. Materialoved., 2002, no. 1 (29), pp. 360–363.
Wang, Z.F., Li, J.Z., Zhu, Y., and Ke, W., A joint action mechanism of anodic dissolution and hydrogen entrance during environment cracking, Scr. Metall. Mater., 1994, vol. 31, no. 5, pp. 625–629.
Mushnikova, S.Yu., Kalinin, G.Yu., Kharkov, A.A., and Zvorygin, R.V., Experimental studies of corrosionmechanical strength of 45G17YU3 steel in static loading conditions, Tr. XIV Peterburgskikh chtenii po problemam prochnosti posvyashchennykh 300-letiyu Sankt-Peterburga, 12–14 marta 2003 (Proc. XIV St. Petersburg Conf. on the Strength Problems Dedicated to the 300 Anniversary of St. Petersburg City, March 12–14, 2003), St. Petersburg, 2004, pp. 183–184.
Mushnikova, S.Yu., Kharkov, A.A., and Kalinin, G.Yu., Analysis of cracking corrosion of austenitic steel of Fe–Mn system, Tr. XIX Ural’skoi shkoly metallovedovtermistov “Aktual’nye problemy fizicheskogo metallovedeniya stalei i splavov” posvyashchennoi 100-letiyu so dnya rozhdeniya akademika V.D. Sadovskogo, Ekaterinburg, 4–8 fevralya 2008 g. (Proc. XIX Ural School of Metallurgists–Thermists Dedicated to the 100th Anniversary of Academician V.D. Sadovskiy “Urgent Problems of Physical Metal Science of Steels and Alloys,” Yekaterinburg, February 4–8, 2008), Yekaterinburg, 2008, p. 216.
Kositsyna, I.I., Filippov, Yu.I., and Sagaradze, V.V., Effect of molybdenum alloying on manganese steel G20F2 for resistance against corrosion cracking, Zashch. Met., 2000, vol. 36, no. 5, pp. 506–510.
Bannykh, O.A., Blinov, V.M., Derkach, G.G., et al., Nauchnye osnovy sozdaniya novogo pokoleniya stalei i splavov dlya ekspluotatsii v ekstremal’nykh usloviyakh i tekhnologii ikh obrabotki (Scientific Basis for Development of a New Generation of Steels and Alloys for use in Extreme Conditions and Their Treatment Technology), Moscow: Inst. Metall. Materialoved. Im. A.A. Bikova, Ross. Akad. Nauk, 2000.
Mushnikova, S.Yu., Kharkov, A.A., and Kalinin, G.Yu., Corrosion resistance of stainless steel for ship building industry, Morsk. Intell. Tekhnol., 2009, no. 2 (4), pp. 63–67.
ASM Specialty Handbook Stainless Steels, Davis, J.R., Ed., Materials Park, OH: ASM Int., 1994.
Corrosion Test and Standards: Application and Interpretation, Baboian, R., Ed., Philadelphia: ASTM Int., 1995.
Seawater Corrosion Handbook, Schumacher, M., Ed., Park Ridge, NJ: Noyes Data, 1979.
Bogorad, I.Ya., Iskra, E.V., Klimova, V.A., and Kuzmin, Yu.L., Korroziya i zashchita morskikh sudov (Corrosion and Protection of Marine Ships), Leningrad: Sudostroenie, 1973.
Číhal, V., Mezikrystalové Koroze Korozivzdorných Ocelí, Praha: Stát. Naklad. Tech. Lit., 1967.
Makarova, N.L. and Nazarov, A.A., Tendency of lowsensitized 08Kh18N10T steel to corrosion cracking at temperatures close to room, Vopr. Materialoved., 1998, no. 4 (17), pp. 56–60.
Kalinin, G.Yu., Legostaev, Yu.L., Malyshevsky, V.A., Kharkov, A.A., and Mushnikova, S.Yu., The new corrosion-resistant nitrogen-containing austenitic steel NS-5T, Vopr. Materialoved., 1996, no. 3 (6), pp. 5–15.
Gorynin, I.V., Rybin, V.V., Malyshevsky, V.A., Kalinin, G.Yu., Mushnikova, S.Yu., Malakhov, N.V., and Yampol’skiy, V.D., Development of prospective fundamentally new corrosion-resistant hull plate, alloyed by nitrogen, Vopr. Materialoved., 2005, no. 2 (42), pp. 40–54.
Gorynin, I.V., Malyshevsky, V.A., Kalinin, G.Yu., Mushnikova, S.Yu., Bannykh, O.A., Blinov, V.M., and Kostin, M.V., Corrosion-resistant high-strength nitrogenous steels, Vopr. Materialoved., 2009, no. 3 (59), pp. 7–16.
Speidel, M.O., Proc. Second Int. Conf. on Advanced Structural Steels (ICASS 2004), Shanghai, pp. 761–767.
Katada, Y., Washizu, N., and Baba, H., Development of high-nitrogen steels in the National Institute for Materials Science, Met. Sci. Heat Treat., 2005, vol. 47, no. 11, pp. 494–496.
Mushnikova, S.Yu., Legostaev, Yu.L., Har’kov, A.A., Petrov, S.N., and Kalinin, G.Yu., An analysis of the influence of nitrogen on austenitic steel resistance to pitting corrosion, Vopr. Materialoved., 2004, no. 2 (38), pp. 126–135.
Sagaradze, V.V., Uvarov, A.I., Pecherkina, N.L., Kalinin, G.Yu., and Mushnikova, S.Yu., Effect of strengthening treatment on the structure and mechanical properties of hardened nitrogen-bearing austenitic steel 04Kh20N6G11AM2BF, Met. Sci. Heat Treat., 2008, vol. 50, no. 9, pp. 489–494.
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Original Russian Text © S.Yu. Mushnikova, G.Yu. Kalinin, A.A. Kharkov, 2015, published in Voprosy Materialovedeniya, 2015, No. 2(82), pp. 151–160.
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Mushnikova, S.Y., Kalinin, G.Y. & Kharkov, A.A. Corrosion resistance problems of low-magnetic shipbuilding steels. Inorg. Mater. Appl. Res. 7, 892–898 (2016). https://doi.org/10.1134/S2075113316060113
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DOI: https://doi.org/10.1134/S2075113316060113