Название |
Features of heat treatment of a new steel for the manufacture of hot deformation dies |
Информация об авторе |
Orenburg State University (Orenburg, Russia):
S. E. Krylova, Dr. Eng., Prof., Dept. of Materials Science and Technology of Materials, E-mail: krilova27@yandex.ru E. V. Romashkov, Post-graduate Student, Aerospace Institute, Dept. of Materials Science and Materials Technology |
Реферат |
The influence of heat treatment parameters on the structure and properties of the promising 70Cr3Mn2WTiB die steel, which is offered for the manufacture of mold parts for aluminum alloy injection molding machines, is revealed. A rational mode of thermal hardening is recommended for the developed steel, including spheroidizing annealing at a temperature of 780 °C with combined cooling; quenching at 1000 °C with oil cooling; high-temperature tempering at 550–600 °C with cooling in calm air. The structure formation and behavior of carbide phases in microalloyed steels at various stages of heat treatment are evaluated. The features of phase transformations and the mechanism of dispersion hardening during high-temperature tempering that provide the required set of mechanical and technological properties are determined. The influence of heat treatment modes on mechanical and operational properties under cyclic loading and heat exposure at normal and elevated temperatures is evaluated. Fractographic studies of zones of cyclic and static crack growth in fractures of samples after testing for crack resistance under cyclic and static loading were performed. The main regularities of changes in the thermal structural stability of chromium steels under cyclic temperature and force influences, depending on the nature of alloying and heat treatment modes, are substantiated, which made it possible to reasonably recommend the developed 70Cr3Mn2WTiB steel for implementation. |
Библиографический список |
1. Terčelj M., Peruš I., Kugler G. Wear Progress of Nitrided Layer at Low, Medium and High Contact Pressures During a Laboratory Simulation of Aluminium Hot Extrusion. Tribology Letters. 2014. Vol. 55, Iss. 1. pp. 69–81. 2. Gurev А. М., Garmaeva I. А., Mosorov V. I., Mizhitov А. Ts., Lygdenov B. D. Surface hardening of cast steel dies. Sovremennye naukoemkie tekhnologii. 2007. No. 6. pp. 32–33. 3. Knyazyuk T. V., Petrov S. N., Ryabov V. V., Khlusova E. I. Structure of a wear-resistant medium-carbon steel after hot deformation in hammer dies and heat treatment. Metal science and heat treatment. 2018. No. 9-10. pp. 556–563. 4. Kamantsev S. V., Sokolov S. O., Krylova S. E., Gryzunov S. E., Priymak E. Yu. et. al. Tool steel for hot deformation. Patent RF, No. 2535148. Applied: 09.01.2013. Published: 10.12.2014. Bulletin No. 34. 5. Krylova S. E. Effect of heat treatment on formation of the structure of economically alloyed steels of the instrumental class: Proceedings of the International scientific conference “Innovative activity of enterprises for research, processing and production of modern structural materials and alloys”. Moscow: Mashinostroenie, 2009. pp. 410–420. 6. Xiang-hong Cui, Jun Shan, Zi-run Yang, Min-xian Wei, Shu-qi Wang et al. Alloying design for high wear-resistant cast hot-forging die steels. Journal of Iron and Steel Research International. 2008. Vol. 15. Iss. 4. pp. 67–72. 7. Smirnov М. А., Schastlivtsev V. М., Zhuravlev L. G. Basics of heat treatment of steel. Moscow: Nauka i tekhnologii, 2002. 519 p. 8. Garmaeva I. А., Mosorov V. I., Mizhitov А. Ts., Lygdenov B. D., Gurev А. М. Surface hardening of cast steel dies. Sovremennye naukoemkie tekhnologii. 2007. No. 6. pp. 32–33. 9. Mordasov D. М., Zotov S. V. Thermocyclic treatment of hot deformation dies made of Kh12MF steel. Vestnik Tambovskogo gosudarstvennogo tekhnicheskogo universiteta. Tambov, 2016. pp. 481–490. 10. Matteis P., Scavino G., Firrao D., Quadrini E., Perucci P. Damage of repeatedly nitrocarburised steel dies for aluminium extrusion. Surface engineering. 2009. Vol. 25. pp. 507–516. 11. GOST 5950–2000. Tool alloy steel bars, strips and coils. General specifications. Introduced: 01.01.2002. 12. Krylova S. E., Antonov S. М., Akhmedyanov А. М., Gaslenko М. I., Rushits S. V. Decomposition kinetics of supercooled austenite of experimental economically alloyed steels of the tool class during continuous cooling. Vestnik Yuzhno-Uralskogo gosudarstvennogo universiteta. Seriya "Metallurgiya". 2012. Iss. 19. No. 39. pp. 79–84. 13. GOST 25.506–85. Design, calculation and strength testing. Methods of mechanical testing of metals. Determination of fracture toughness, characteristics under the static loading. Introduced: 01.01.1986. 14. Steblov А. B., Lenartovich D. V., Ponkratin Е. I. New steel for hot forming dies. Metallurg. 2006. No. 2. pp. 41–43. 15. Sekine Y., Soyama H. Surface modification of alloy tool steel for forging dies by cavitation peening. Review of automotive engineering. 2009. Vol. 30. pp. 393–399. 16. Kolokoltsev V. М., Ivanova I. V. Hot formed cast steel. Vestnik Magnitogorskogo gosudarstvennogo tekhnicheskogo universiteta imeni G. I. Nosova. 2009. No. 4. pp. 15–17. 17. Krylova S. E., Romashkov E. V., Kuznetsov A. V. Peculiarities of Thermal Hardening of Experimental Sparingly-Alloy Tool-Class Steels. Materials Science Forum. 2016. Vol. 870. pp. 392–396. |