Название |
A new look at the iron-carbon diagram of D. K. Chernov |
Информация об авторе |
Empress Catherine II Saint Petersburg Mining University, St. Petersburg, Russia
K. Yu. Shakhnazarov, Dr. Eng., Prof., Dept. of Materials Science and Technology of Art Products, e-mail: karen812@yandex.ru S. A. Vologzhanina, Dr. Eng., Prof., Dept. of Materials Science and Technology of Art Products, e-mail: vologzhanina_sa@pers.spmi.ru R. M. Khuznakhmetov, Postgraduate Student, Dept. of Materials Science and Technology of Art Products |
Реферат |
It is difficult to overestimate the significance of the Fe–C phase diagram, the construction of which was initiated by D. K. Chernov, which allowed to open new boundaries in understanding the properties of iron-based alloys. At the same time, anomalies in properties and the lack of connection between them and the structure of alloy mixtures and the phase diagram have been known for about a century, but have not been explained. A. A. Bochvar, studying the properties of alloy mixtures consisting of obviously pure components, concluded: “As it turned out, there is no unambiguous relationship between composition and properties at all.” I. I. Kornilov came to the same conclusion: “But it is difficult to establish any strict connection between hardness and the phase diagram.” N. I. Belyaev and N. T. Gudtsov noted much more sharply: “The apparent elastic limit has no connection with the structure of steel.” E. Gudremon, hiding an obvious anomaly (the maximum yield strength), drew a curve past the experimental point at ~0.5 % C. The maximum yield strength of annealed steels at ~0.5 % C was shown by P. Obergoffer in 1915, but left without comment. The analysis of the Fe – C phase diagram is performed taking into account three verticals plotted by D. K. Chernov in 1916, which were not taken into account in subsequent editions of the diagram. N.S. Kurnakov’s rule connects changes in the properties of alloys with the type of phase diagram, but does not explain numerous anomalies in the physical and mechanical properties of alloys. In this regard, a new approach to the analysis of the phase diagram is proposed, taking into account the three verticals of D.K. Chernov and the lines of the phase diagram taking into account concentration dependencies and qualitative intervals of crystallization (recrystallization). Based on the established numerous anomalies in the physical and mechanical properties of melts, austenite, martensite and ferrite-cementite mixture, intermediate phases (~Fe42C, ~Fe24C, ~Fe10C) are declared, allowing a new look at the diagram discovered more than 100 years ago. The intermediate phases declared in the article can be used to explain the anomalies of the physical and mechanical properties of industrially used steels |
Библиографический список |
1. Chernov D. K. Letter to the editor of the “Journal of the Russian Metallurgical Society”. Zhurnal Russkogo Metallurgicheskogo obshchestva. 1916. Part 1. No. 3-4. pp. 189–200. 2. Kornilov I. I. Physicochemical bases of heat resistance of alloys. Moscow : Izdatelstvo AN SSSR, 1961. 516 p. 3. Tyrkel E. History of the development of the iron-carbon diagram. Moscow : Mashinostroenie, 1968. 280 p. 4. Leontiev L. I., Tsukanov V. V., Smirnova D. L. The role of D. K. Chernov in the creation and development of the doctrine of modern metallurgy and metal science. Part 1. The main theoretical and industrial discoveries of D. K. Chernov. Izvestiya vuzov. Chernaya Metallurgiya. 2020. Vol. 63. No. 10. pp. 796–801. DOI: 10.17073/0368-0797-2020-10-796-801 5. Leontiev L. I., Tsukanov V. V., Smirnova D. L. The role of D. K. Chernov in the creation and development of the doctrine of modern metallurgy and metal science. Part 2. Scientific and practical confirmation of the D. K. Chernov`s ideas. Izvestiya vuzov. Chernaya Metallurgiya. 2020. Vol. 63. No. 11-12. pp. 873–877. DOI: DOI: 10.17073/0368-0797-2020-11-12-873-877 6. Bazhin V. Yu. Modern view on anomalies in metal groups of the D. I. Mendeleyev`s Periodic table. Zapiski Gornogo instituta. 2020. Vol. 239. pp. 520–527. 7. Meskin V. S. Ferromagnetic alloys and their properties. Leningrad, Moscow : ONTI NKTP, 1937. 791 p. 8. Ershov G. S., Poznyak L. A. Microheterogeneity of metals and alloys. Moscow : Mashinostroenie, 1985. 214 p.
9. Anikeev V. V., Zonnenberg N. N., Nikitin V. I. Heredity of the influence of the composition of charge materials on the quality of steel castings. Sovremennaya nauka: aktualnye problemy i puti ikh resheniya. 2015. No. 7 (20). pp. 14–19. 10. Hansen M. Structures of binary alloys. In 2 volumes. Vol. 1. Leningrad, Moscow : Metallurgizdat, 1941. 640 p. 11. Litvinenko V. S., Dvoinikov M. V. Methodology for determining the parameters of drilling mode for directional straight sections of well using screw downhole motors. Journal of Mining Institute. 2020. Vol. 241. pp. 105–112. DOI: 10.31897/pmi.2020.1.105 12. Milyuts V. G., Tsukanov V. V., Pryakhin E. I., Nikitina L. B. Development of manufacturing technology for high-strength hull steel reducing production cycle and providing high-quality sheets. Journal of Mining Institute. 2019. Vol. 239, Iss. 5. pp. 536–543. DOI: 10.31897/pmi.2019.5.536 13. Bazhin V. Yu., Issa B. Influence of heat treatment on the microstructure of steel coils of a heating tube furnace. Journal of Mining Institute. 2021. Vol. 249. pp. 393–400. 14. Gudremon E. Special steels. In 2 volumes. Vol. 1. Moscow : Metallurgizdat, 1959. 952 p. 15. Moroz L. S. Fine structure and strength of steel. Moscow : Metallurgizdat, 1957. 159 p. 16. Oberhoffer P. Technical iron. Moscow, Leningrad : Metallurgizdat, 1940. 535 p. 17. Yuryev A. A., Gromov V. E., Grishunin V. A., Peregudov O. A. et al. Mechanisms of destruction of lamellar pearlite of differentially hardened rails during long-term operation. Fundamentalnye problemy sovremennogo materialovedeniya. 2017. Vol. 14. No. 4. pp. 438–444. 18. Schipachev А. M., Aljadly M., Ganzulenko O. Y., Chernikov D. G. et al. Evaluating the effectiveness of magnetic-pulse treatment for healing continuity defects in the metal of oil and gas pipelines. Metals. 2023. Vol. 13, Iss. 11. 1875. 19. Elansky G. N., Kudrin V. A. Structure and properties of liquid metal — smelting technology — quality of steel. Moscow : Metallurgiya, 1984. 239 p. 20. Vasilyev A. A., Sokolov D. M., Sokolov S. S. Investigation and modeling of the effect of predeformation of austenite on the kinetics of ferritic transformation. Letters on Materials. 2021. Vol. 11, Iss. 1. pp. 90–94. DOI: 10.22226/2410-3535-2021-1-90-94 21. Samarin A. M., Fedotov S. G., Fedotov I. P., Sinodova E. P. Structure and properties of iron-carbon alloys. Collection “Metal Science”. Proceedings of the Symposium on metallurgy and metal science dedicated to the 100th anniversary of the discovery of iron polymorphism by D. K. Chernov. Moscow : Nauka, 1971. pp. 231–235. 22. Baum B. A., Khasin G. A., Tyagunov G. V., Klimenkov E. A. et al. Liquid steel. Moscow : Metallurgiya, 1984. 208 p. 23. Tkachenko S. S., Emelianov V. O. Modern investment casting technology for production of artistic castings. Lityo i metallurgiya. 2021. No. 1. pp. 49–52. 24. Vertman A. A., Samarin A. M. Properties of iron melts. Moscow : Nauka, 1969. 280 p. 25. Pustovoyt V. N., Dolgachev Yu. V., Karavaev V. P. Decomposition of residual austenite in U12 steel during processing in a magnetic field. Tendentsii razvitiya nauki i obrazovaniya. 2021. Vol. 70-2. pp. 71–73. DOI: 10.18411/lj-02-2021-57 26. Elansky G. N. Structure and properties of metallic melts. Moscow : Metallurgiya, 1991. 160 p. 27. Yurchenko A. N., Marieva M. A., Grebenkin R. D., Simonov Yu. N. Determination of critical temperature values Aс1 and Aс3 in steels of the alloying system Kh2G2S2MF using the dilatometric method and the test hardening method. Vestnik Permskogo natsionalnogo issledovatelskogo politekhnicheskogo universiteta. Mashinostroenie, materialovedenie. 2019. Vol. 21. No. 3. pp. 85–92. DOI: 10.15593/2224-9877/2019.3.10 28. Pryakhin E. I., Sharapova D. M. Repair ability of low-alloyed steel strength of K70 (X90) class. Key Engineering Materials. 2020. Vol. 836. pp. 131–135. 29. Alekseev V. I., Barakhtin B. K., Zhukov A. S. Chemical heterogeneity as a factor in increasing the strength of steels manufactured using selective laser melting technology. Zapiski Gornogo instituta. 2020. Vol. 242. pp. 191–196. DOI: 10.31897/PMI.2020.2.191 30. Piiraynen V. Yu., Nikitina T. Yu. New in the production of cast armor plates for ball mills. Liteynoe proizvodstvo. 2020. No. 3. pp. 36–41. 31. Tsukanov V. V., Smirnova D. L., Efimov S. V., Titova T. I. et al. Computer modeling of the modes of the main heat treatment of a forged billet made of 20Kh3MVFA steel. Tyazheloe mashinostroenie. 2020. No. 9. pp. 2–9. 32. Davydov S. V., Filippov R. A., Moroz A. A. Low-temperature decomposition of pearlite in ironcarbon alloys by the reaction of peritectoid transformation. Naukoemkie tekhnologii v mashinostroenii. 2021. No. 2 (116). pp. 3–13. DOI: 10.30987/2223- 4608-2021-2-3-13 33. Ivanova V. S., Terentyev V. F. Physical nature and patterns of destruction. Collection “Metal Science”. Proceedings of the Symposium on metallurgy and metal science dedicated to the 100th anniversary of the discovery of iron polymorphism by D. K. Chernov. Moscow : Nauka, 1971. pp. 100–107. 34. Okishev K. Yu. Calculation of diagrams of isothermal decomposition of austenite in structural steels. Vestnik Permskogo natsionalnogo issledovatelskogo politekhnicheskogo universiteta. Mashinostroenie, materialovedenie. 2020. Vol. 22. No. 2. pp. 82–89. DOI: 10.15593/2224-9877/2020.2.10 35. Gorynin V. I., Olenin M. I., Mikhailov M. S., Kondratyev S. Y. Effect of medium-temperature additional tempering on the carbide phase and cold resistance of heat-hardenable steel 09G2SA-A. Metal Science and Heat Treatment. 2019. Vol. 60, Iss. 11-12. pp. 722–727. 36. Syrkov A. G., Prokopchuk N. R., Vorobiev A. G., Brichkin V. N. Academician N. S. Kurnakov as the founder of physico-chemical analysis – the scientific base for the development of new metal alloys and materials. Tsvetnye Metally. 2021. No. 1. pp. 77–83. 37. Davydov S. V. Carbide transformation of peritectoid type in Fe-C alloys. Metallurgiya mashinostroeniya. 2020. No. 4. pp. 17–26. 38. Kurganov Yu. A., Shcherbakov S. P. Effect of discrete addition of aluminum oxide on the structure and properties of aluminum alloy. Zapiski Gornogo instituta. 2020. Vol. 228. pp. 717–721. 39. Kornilov I. I. Status and prospects of research in the field of metallides. Collection “Metal Science”. Proceedings of the Symposium on metallurgy and metal science dedicated to the 100th anniversary of the discovery of iron polymorphism by D. K. Chernov. Moscow : Nauka, 1971. pp. 246–257. |