KnE Materials Science

ISSN: 2519-1438

The latest conference proceedings on physical materials, energy materials, electrical materials.

Study of the Process of Alloying Steel By Nitrated Chromium

Published date: Mar 17 2019

Journal Title: KnE Materials Science

Issue title: Theoretical and practical conference with international participation and School for young scientists

Pages: 246–253

DOI: 10.18502/kms.v5i1.3974

Authors:
Abstract:

Experimental investigation of process of steel alloying by nitrated chromium was carried out. As raw material for metal-melt treatment, the steel containing 20.3% Cr; 11.2% Mn; 7.1% Ni; 1.46% Mo; 0.33% Si; and 0.05% C was used. As-cast samples of nitrated chromium (ФХH10 and ФХH20 grades) were used as alloying additives. The compositions of grades are 85.7% Cr; 8.0% N, and 73.9% Cr; 16.1% N, respectively. Experiments were carried out in high-temperature laboratory unit at 1500C. It was found that the degree of nitrogen transfer into steel reaches up to 84% at the application of as-cast specimen of nitrated chromium containing 8% of nitrogen and 1 min exposure time after addition to ferroalloy. Further high-temperature soaking of nitrated steel causes a dropdown of nitrogen concentration due to thermal dissociation of existed nitrogen-containing compounds in the melt and exhalation in gas phase. This prevents nitrogen transfer into the steel. It was demonstrated a possibility in principle of obtaining of chrome-manganese steel containing about 0.4–0.6% of nitrogen at melt alloying by nitrated chromium in air atmosphere at exposure time up to 15 min.

Keywords: metallurgy, nitrogen, chromium, steel, digestion degree, physicochemical characteristics

References:

[1] Savray, R.A. Makarov A.V., Gorkunov E.S., et al. (2015) Mechanical characteristics of nitrous austenite steel (04Х20H6Г11M2AФБ grade) at static extension within the temperature range from -70 to +140 ∘C. Vector nauki TGU, Vol.34, no. 4, pp. 100–107


[2] Bannykh, O.A. (2005). Cost-saving nitrous stainless steels as promising substitutor of light-weight alloys. Metal Science and Heat Treatment, no. 7. pp. 9–13.


[3] Gavriljuk, V.G. and Berns H. (1999). High nitrogen steel: structure, properties, manufacture, Berlin: Springer.


[4] Kostina, M.V. (2003). Development of Cr-N steel alloying principles and corrosionresistant steels of new generation having structure of nitrous martensite and austenite for heavy loaded units in modern machines. Doctor Thesis. IMET RAS.


[5] Gorynin, I.V., Rybin, V.V, Malyshevskiy, V.A. et al. (2005). Development of a brand new promising corrosion-resistant hull plates alloyed by nitrogen. Material science problems, no. 2. pp. 40–54.


[6] Kalinin, G.Y., Mushnikova, S.Yu., Nesterova, E.V., el at., (2006) Study of structure and properties of high-strength corrosion-resistant nitrous steel of 04Х20H6Г11M2AФБ grade. Material science problems. no. 1. pp. 45–53.


[7] Baeva, L.A., Ilyichev, M.V., Tyuftyaev, A.S., et al. (2017). Nitrogen influence at plasma-arc remelting on structure, mechanical properties and corrosion-resistance of stainless steels. Steel, no. 12., pp. 54–56.


[8] Rashev, C.V. (1995). Highly nitrated steels Metallurgy under pressure. Sofia: Publishing house of Bulgarian Science Academy “Prof. Marin Drinov”.


[10] Nakamura, N., Tsuchiyma, T. and Takaki, S. (1998). Effect of structural factors of the mechanical properties of the high nitrogen austenitic steels, in Book of Abstracts of 5-th Int. Conf. High Nitrogen Steels. HNS-98. Espoo Finland – Stockholm Sweden.


[11] Odesskii, P.D., Smirnov, L.A., Parshin, V.A. et al. (2015). Nitrogen as a microalloying element in steel for metallic structures. Steel in Translation, vol. 45, no. 5, pp. 378– 379.


[12] Panfilova, L.M. and Smirnov, L.A. (2015). Microalloying of manufacturing steel with vanadium and nitrogen. Steel in Translation, vol. 45, no. 11, pp. 887–893.


[13] Panfilova, L.M. and Smirnov, L.A. (2015). Effect of structural factors and nitride strengthening phases on new generafion steel rolled product structural strength. Metallurgist. 2015. vol. 58. no. 5. pp. 396–400.


[14] Zhuchkov, V.I., Leontiev, L.I., Selivanov, E.N., et al. (2014). Prospects of stainless steel production with application of domestic chromium and nickel ferroalloys, in Proceedings of Conference Modern trends in the field of theory and practice of extraction and recycling of mineral and technogenic raw. Ekaterinburg: USTU-UPI.


[15] Khalezov B.D., Zayakin, O.V., Gavrilov, A.C., et al. (2017). Hydro- pyrometallurgical method of Fe-Ni-Cr-Mn-Si system alloys obtaining. Butlerov communications, vol. 52, no. 10, pp. 111–117.


[16] Shatokhin, I.M., Zaitdinov, M.Kh., Bigeev V.A., et al. (2012). Application of SHS technology in metallurgy. Magnitogorsk: Magnitogorsk State Technical University named after G.I. Nosov.


[17] Zhuchkov, V.I., Zayakin, O.V. and Malcev, Y.B. (2001). Melting temperatures and density of nickel–containing ferroalloys. Melts, no. 1, pp. 7–9.


[18] Zhuchkov, V.I., Andreev, N.A., Zayakin, O.V., et al. (2013). Composition and performance of chromium-bearing ferroalloys. Steel in Translation, vol. 43, no. 5, pp. 306– 308.


[19] Andreev, N.A., Zhuchkov, V.I., Zayakin, O.V. (2013). Density of chromium-containing ferroalloys. Russian Metallurgy (Metally), no. 6, pp. 418–419.


[20] Zayakin, O.V., Zhuchkov, V.I., and Lozovaya, E.Yu. (2007). Melting Time of Nickel- Bearing Ferroalloys in Steel. Steel in Translation, vol. 37, no. 5, pp. 416–418.




[21] Zhuchkov, V.I., Zayakin, O.V, Lozovaya, E.Yu., et al. (2016). Study of melting process of Fe-Ni-Cr alloys in iron-carbon melt. Butlerov communications, vol. 47, no. 8, pp. 56–62.


[22] Lyakishev, N.P. and Gasik, M.I. (1999). Theory and technology of ferroalloys electrometallurgy. Moscow: Eliz.

HTML
Download
Cite
Share
statistics

317 Abstract Views

338 PDF Downloads