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55th anniversary of department “Technology of Materials” of Volgograd State Technical University
Название Influence of calcium carbide as a deoxidizer on the chemical composition and contamination by nonmetallic inclusions
Автор D. V. Rutskiy, N. А. Zyuban, I. V. Neklyudov, A. Yu. Agarkov
Информация об авторе

Volgograd State Technical University (Volgograd, Russia):

D. V. Rutskiy, Cand. Eng., Associate Prof.
N. A. Zyuban, Dr. Eng., Prof., Head of the Dept “Technology of Materials”, e-mail: tecmat@vstu.ru

 

Volzhsky Pipe Plant (Volzhsky, Russia):
I. V. Neklyudov, Chief Metallurgist
A. Yu. Agarkov, Leading Engineer Technologist, Steel Making and Casting Lab, Central Plant laboratory
Реферат

The paper presents the results of a study of contamination of carbon steel grade D with non-metallic inclusions in samples taken at all stages of the metallurgical processing in the conditions of the electric steelmelting shop of JSC “Volzhsky Pipe Plant”. Studies have shown that the use of aluminum as a deoxidizing agent leads to the formation in steel, mainly of refractory non-deformable inclusions of corundum (Al2O3), which have an unfavorable shape for further pressure treatment. Outof-furnace treatment helps to reduce the contamination of steel with non-metallic inclusions, as well as the modification and globularization of corundum inclusions. Moreover, the use of aluminum as a deoxidizing agent leads to an increase in nonmetallic inclusions in a continuously cast billet. The use of calcium carbide (CaC2) as a deoxidizing agent has a positive effect on the chemical composition of nonmetallic inclusions, leads to modification and globularization in the initial stages of smelting corundum and the production of calcium aluminates (xCaO·yAl2O3) based on aluminum magnesian spinel (Al2O3)·(MgO). The favorable form of inclusions obtained in the early stages of secondary treatment is maintained in subsequent redistribution, which leads to the creation of favorable conditions for the removal of inclusions. The use of CaC2 as a deoxidizing agent makes it possible to obtain a continuously cast billet having a lower contamination with non-metallic inclusions.
The study has been carried out with financial support of the Russian Foundation for Basic Research in the framework of the research project No. 18-08-00050\18.
Ключевые слова Deoxidation, aluminium, calcium carbide, non-metallic inclusions, chemical composition, mould, melting, ladle treatment, conticast billet
Библиографический список

1. Kuznetsov А. А., Sumin S. N., Kozlov G. S. Changes in oxygen activity during secondary treatment of steel when it is deoxidized by aluminum or calcium carbide. Scientific and technical progress in metallurgy — 2013: proceedings of the international scientific workshop. Cherepovets: ChGU, 2014. pp. 30–33.
2. Gamanyuk S. B., Zyuban N. A., Rutskiy D. V., Ananeva А. N. Study of effect of deoxidation modes on formation and location of sulphides in medium carbon structural steels. Stal. 2017. No. 2. pp. 15–19.
3. Shevtsova О. А., Zyuban N. А., Pegisheva S. А. et. al. Features of formation of sulfide inclusions and their location inside a grain, depending on the conditions of 20 grade steel deoxidation. Metallurg. 2014. No. 5. pp. 60–63.
4. Shevtsova О. А., Zyuban N. А., Rutskiy D. V. Features of formation of sulfide inclusions and their impact on the quality of low-alloy structural steels. Metallurg. 2010. No. 12. pp. 54–57.
5. Grigorovich К. V. Study of the structure and metallurgical quality of rail steels of various manufacturers. Metally. 2006. No. 5. pp. 1–16.
6. Gamanyuk S. B., Zyuban N. A., Rutskiy D. V., Babin G. V. Understanding the effect of deoxidation regime on the formation and arrangement of sulphide inclusions and on mechanical properties in steel. CIS Iron and Steel Review. 2018. Vol. 16. pp. 44–48.
7. Agbola О. F., Morozova T. V., Dub А. V. Non-metallic inclusions in low-alloy pipe steel. Metallurg. 2005. No. 4. pp. 67–73.
8. Grigorovich К. V., Krasovsky P. V., Trushnikova А. S. Analysis of nonmetallic inclusions — the basis of quality control of steel and alloys. Analitika i kontrol. 2002. Vol. 6. No. 2. pp. 133–142.
9. Kisling R., Lange N. Nonmetallic inclusions in steel. Translation from English; edited by Rozenberg V. M. Moscow: Metallurgiya, 1968. 124 p.
10. Grigorovich К. V., Garber А. К. Analysis of processes of carbon steels secondary treatment. Perspektivnye materialy. 2011. No. 13. pp. 13–25.
11. Shakhpazov Е. Kh., Zaytsev А. I., Shaposhnikov N. G., Rodionova I. G., Rybkin N. А. To the issue of physico-chemical prediction of the type of non-metallic inclusions. Complex deoxidation of steel by aluminum and calcium. Metally. 2006. No. 2. pp. 3–13.
12. Takashi Kimura, Hideaki Suito. Calcium Deoxidation Equilibrium in liquid iron. MMTB. 1994. Vol. 25B. pp. 33–42.
13. Kotelnikov G. I., Zubarev К. А., Movenko D. А. et. al. Plotting iron deoxidation with calcium. Elektrometallurgiya. 2016. No. 6. pp. 10–18.
14. Fujiwara H., Tano M., Yamamoto K., Ichise E. Solubility and activity of calcium in molten iron in equilibrium with lime and thermodynamics of calcium containing iron melts. ISIJ Int. 1996. Vol. 35, No. 9. pp. 1063–1071.
15. Kudrin V. A. Theory and technology of steel production: tutorial for institutions of higher education. Moscow: Mir, Izdatelstvo AST Ltd., 2003. 528 p.
16. Laptev D. M. Tasks and exercises on thermodynamics of solutions. Moscow: Metallurgiya, 1965.
17. Shin J. H., Park J. H. Formation Mechanism of Oxide-Sulfide Complex Inclusions in High-Sulfur-Containing Steel melts. Metallurgical and Materials Transactions B. 2018. Vol. 49B. pp. 311–324.
18. Eroshkin S. B., Prudkov K. E., Popov О. V. et. al. Increasing the purity of metal during secondary treatment by calcium carbide. Stal. 2007. No. 12. pp. 26–28.
19. Chaikin V. А., Chaikin А. V., Kasimgazinov А. D. et. al. New material for steel diffusive deoxidizing in the unit for complex steel treatment. Chernye Metally. 2018. No. 9. pp. 10–15.
20. Kotelnikov G. I., Zubarev К. А., Movenko D. А. et. al. Plotting iron deoxidation with calcium. Elektrometallurgiya. 2016. No. 6. pp. 10–18.
21. Svyazhin А. А., Krushke E., Svyazhin А. G. The use of calcium carbide in the smelting of low carbon steel. Metallurg. 2004. No. 11. pp. 43–45.
22. GOST 1778-70 (ISО 4967). Steel. Metallographic methods for the determination of nonmetallic inclusions. Introduced: 29.07.2011.
23. Lis T. Modification of oxygen and sulphur inclusions in steel by calcium treatment. Metalurgija. 2009. Vol. 2, No. 48. pp. 95–98.
24. Huemer K., Wolf G., Sormann A., Frank G. Auswirkungen einer Kalziumbehandlung auf die Entstehung und Zusammensetzung von nichtmetallischen Einschluessen bei der Erzeugung von aluminiumberuhigten Stahlen fur Langprodukte. BHM. 2005. 150. Heft 7. S. 237–242.
25. Pozhivanov М. А., Shakhpazov Е. Kh., Svyazhin А. G. Smelting of automotive steel. Moscow: Interkontakt Nauka, 2006. 166 p.
26. Voskoboynikov V. G., Kudrin V. А., Yakushev A. M. General metallurgy. Moscow: Akademkniga, 2002. 168 p.
27. Shakhpazov Е. Kh., Zaytsev А. I., Shaposhnikov N. G., Rodionova I. G., Rybkin N. А. To the issue of physico-chemical prediction of the type of non-metallic inclusions. Complex deoxidation of steel by aluminum and calcium. Metally. 2006. No. 2. pp. 3–13.
28. Bigeev А. М. Metallurgy of steel. Theory and technology of smelting steel: tutorial for institutions of higher education. Bigeev А. М., Bigeev V. А. 3rd edition revised and enlarged. Magnitogorsk: MGTU, 2000. 544 p.
29. Aizatulov R. S., Kharlashin P. S., Protopopov Е. V., Nazyuta L. Yu. Theoretical foundations of steelmaking processes: tutorial for institutions of higher education. Moscow: MISiS, 2004. 320 p.
30. Pires J. C. S., Garcia A. Study of the Nature of Non-Metallic Inclusions in Samples of Aluminum and Silicon Killed Low Carbon Steels, Collected in the Refining Treatment and Continuous Casting Stages. Materials Research. 2004. Vol. 7. No. 4. pp. 517–521.
Language of full-text русский
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