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Steel Making and Continuous Casting
Название Introduction of innovations in steel smelting for critical castings of freight wagon bogies in order to increase their operational reliability
DOI 10.17580/chm.2021.09.01
Автор A. V. Chaikin, V. A. Chaikin, V. V. Kolpakov, +K. N. Vdovin
Информация об авторе

Smolensk regional branch of the Russian Association of Founders (Safonovo, Russia):

A. V. Chaikin, Technical Director, Cand. Eng., e-mail: chaika1983@inbox.ru

 

Nosov Magnitogorsk State Technical University (Magnitogorsk, Russia):

V. A. Chaikin, Dr. Eng., Prof., Dept of Technologies of Foundry Processes and Materials Science, e-mail: sro_ral@mail.ru
K. N. Vdovin, Dr. Eng., Prof., Dept of Technologies of Foundry Processes and Materials Science

 

Rubtsovsky Branch of JSC Altaivagon (Rubtsovsk, Russia):

V. V. Kolpakov, Chief Metallurgist, e-mail: metal@rfav.ru

Реферат

This work is devoted to improving the technological process of the recovery period for melting steel 20GFL with the purpose of increasing the efficiency of metal refining, KCV–60, operational reliability of critical railway castings, and reducing the cost of steel. The advantages of the steel diffusive deoxidation technological process using a dispersed aluminum-containing deoxidizer (RDA) in the production of critical railroad castings have been investigated and revealed. The benefits of steel smelting in an electric arc furnace (EAF 6) were applied to the process. This made it possible to achieve higher steel quality, and improve energy and resource consumption during the technological processes of smelting and casting. The use of the RDA made it possible to effectively deoxidize the metal, increase and stabilize the impact toughness of steel with a sharp notch at negative temperatures, and also reduced the cost of castings. The treatment of steel with the invented deoxidizing mixture made it possible to dramatically increase the efficiency of steel deoxidation compared to other traditional mixtures. The increase is explained by a significantly higher number of reacting particles’ active centers and an increased interphase in the system. The increase in the systems’ interface was caused by the process of stirring slags, which, in turn, was created by the dissociation of carbonates included in the RDA. The average sulfur content during deoxidation with RDA decreased by 23 %, i.e., to 0.0110 % versus 0.0143 % when a regular factory mixture was used. After the treatment of steel with the RDA, the produced casting’s microstructure became more beneficial as well. The pollution index decreased, on average, from 1.853 to 1.472·10–3. The KCV–60 increased by 3 % on average and significantly stabilized, which is vital for the technological process. The uniformity of the KCV–60 has also increased. The coefficient of variation was 32% before the process implementation, whereas it was 14 % after the implementation. The new technological process was introduced at the Rubtsovsk branch of Altayvagon JSC with the economic effect of over 6 million rubles.

Ключевые слова Critical castings, mechanical properties, steel, slag, diffusion deoxidation
Библиографический список

1. Muravyev D. V. Improvement of the technology of repairing bolster and side frames of freight wagon bogies: thesis of inauguration of Dissertation … of Candidate of Engineering Sciences. Omsk, 2009. 197 p.
2. Dorantes M., Noradino p., Maximiliano M. G. Type-2 fuzzy logic systems for temperature evaluation in ladle furnace. IEEE Latin America Transactions. 2016. Vol. 14. Iss. 8. pp. 3914–3920.

3. Attila G. C. Refining steel in an induction ladle furnace. Annals of the faculty of engineering Hunedoara. 2015. Vol. 13. Iss. 3. pp. 197–200.
4. GOST 32400–2013. Molded side frame and bolster beam of bogies for railway fright wagons. Specifications. Introduced: 01.07.2014. Мoscow: Standartinform, 2013.
5. Kozlov L. Ya., Kolokoltsev V. М., Vdovin К. N. et. al. Production of steel castings: tutorial for universities. Moscow: MISIS, 2003. 351 p.
6. Golubtsov V. А., Ryabchikov I. V., Usmanov R. G. Microcrystalline complex modifiers in steel production. Chelyabinsk: YuUrGU, 2017. 137 p.
7. Chaikin А. V., Chaikin V. А., Kasimgazinov А. D., Bykov p. О. The new material for steel diffusive deoxidizing in the unit for complex steel treatment. Chernye Metally. 2018. No. 9. pp. 6–11.
8. Chaikin А. V., Chaikin V. А., Feoktistov N. А. Improvement of the efficiency of diffusion deoxidation during steel smelting in acidic and basic electric arc furnaces. Liteyshchik Rossii. 2012. No. 8. pp. 40–42.
9. Hepuţ T., Ardelean E., Socalici A., Osaci M., Ardelean M. Steel deoxidation with synthetic slag. Metalurgia International. 2010. Vol. 15. Iss. 7. Р. 22–28.
10. Chaikin А. V., Yakunina S. А., Kisilev V. М., Kolpakov V. V., Vdovin К. N. Improvement of mechanical properties of heavy-duty castings of 110G13L steel by improving the remelting method. Liteyshchik Rossii. 2020. No. 10. pp. 7–15.
11. Kozhukhov A. A. Role of prereduced pellets in the slag foaming in modern EAFs. Russian Metallurgy. 2013. No. 6. pp. 406–409.
12. Kozhukhov A. A., Tkachev A. S., Ryabinin I. V. System for controlling the temperature regime of an arc steelmaking furnace operated with the continuous charging of metallized pellets and foaming of the furnace slag. Metallurgist. 2012. Vol. 56. No. 1-2. pp. 17–22.
13. Technical specification 0826-003-47647304–2001. Complex modifiers. Introduced: 2001.
14. GOST 977–88. Steel castings. General specifications. Introduced: 01-01-1990. Moscow: Izdatelstvo standartov, 1988.
15. GOST 1778–70. Steel. Metallographic methods for the determination of nonmetallic inclusions. Introduced: 01-01-1972. Moscow: Izdatelstvo standartov.
16. Sidnyaev N. I. Probability theory and mathematical statistics: textbook for bachelors. Moscow: Yurayt, 2015. 219 p.
17. Vdovin К. N., Feoktistov N. А., Pivovarova К. G. et. al. Fluxes for electroslag remelting of structural steels. Elektrometallurgiya. 2017. No. 4. pp. 13–19.
18. Jing Guo, Shu-sen Cheng, Zi-jian Cheng. Characteristics of deoxidation and desulfurization during LF refining Al-killed steel by highly basic and low oxidizing slag. Journal of Iron and Steel Research International. 2014. Vol. 21. Iss. 2. pp. 166–173.
19. Putan V., Putan A., Ardelean E. Influence of the addition of a reducing mixture slag and duration of treatment on the desulphurization and deoxidation efficiency. Solid State Phenomena. 2016. Vol. 254. pp. 144–148.
20. Vdovin К. N., Feoktistov N. А., Sinitskiy Е. V., Gorlenko D. А., Durov N. А. Smelting of high manganese steel in an arc steelmaking furnace. Technology. Message 1. Izvestiya vysshikh uchebnykh zavedeniy. Chernaya metallurgiya. 2015. Vol. 58. No. 10. pp. 735–739.

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