ArticleName |
Experimental
study of the process of laser treatment of steel Kh12M |
ArticleAuthorData |
National University of Science and Technology “MISIS” (Moscow, Russia)
N. A. Chichenev, Dr. Eng., Prof., Dept. of Engineering Technology Equipment, e-mail: chich38@mail.ru S. M. Gorbatyuk, Dr. Eng., Prof., Dept. of Engineering Technology Equipment, e-mail: sgor02@mail.ru A. O. Karfidov, Head of Dept. of Engineering Technology Equipment, e-mail: a.korf@mail.ru O. N. Chicheneva, Cand. Eng., Associate Prof., Dept. of Engineering Technology Equipment, e-mail: ch-grafika@mail.ru |
Abstract |
One of the promising methods for improving the performance of technological tools is laser surface hardening, when metal is heated from the surface, while laser processing processes are characterized by a short exposure time and provide almost complete absence of deformations of the processed products. Tool steel Kh12M was chosen as the material for the study. Thermal hardening of samples, which were made in the form of a rectangular parallelepiped, was carried out on laser technological installations equipped with a continuous CO2 laser with a power of 1.5 kW. The depth of the laser exposure zone is chosen as the target function, which is an important operational characteristic of a technological tool that affects wear of its working surfaces. Based on the analysis of the results of a preliminary experiment with samples made of steel Kh12M, the values of the technological parameters of laser processing and the thermophysical characteristics of the processed material were determined. An experimental plan was developed, at each point of the matrix of which 3 experiments were carried out, while 72 experiments were conducted to find dependence of the depth of the laser exposure zone. Analysis of the experimental results shows that the maximum hardening depth of samples made of steel Kh12M without melting the surface was 0.75–0.80 mm; greater depth is achieved under conditions that cause melting of the surface. To obtain generalized statistical dependencies, the obtained data were transformed, taking into account the definite dimensionless (generalized) parameters. As a result of mathematical processing of experimental data, the formula was obtained for determining the relative depth of the hardened zone at the specified parameters of laser processing without melting the surface. |
References |
1. Konstantinov I. L., Sidelnikov S. B. Forging and stamping production: a manual. Moscow : NITs INFRA-M. 2021. 464 p. 2. Burdulovskiy V. G. Sheet stamping technology: a manual. Ekaterinburg : Izdattlstvo UrFU. 2019. 224 p. 3. Benson S. Bending Basics. Cincinnati : Fabricators & Manufacturers Association. 2017. 581 p. 4. Banabic D. (Ed.). Multiscale modeling in sheet metal forming. Heidelberg : Springer. 2016. 405 p. 5. Yakovlev S. S. Forging and stamping (in 4 volumes). Vol. 4. Sheet stamping. Moscow : Mashinostroenie. 2010. 732 p. 6. Efremov D. B., Stepanov V. M., Chicheneva O. N. Modernization of the mechanism for quick backward pressure of rolls in the duo rolling stand of 2800 rolling mill at JSC Ural Steel. Stal. 2020. No. 8. pp. 44–47. 7. Nefedov A. V., Svichkar V. V., Chicheneva O. N. Re-engineering of Equipment to Feed the Melting Furnace with Aluminum Charge. Lecture Notes in Mechanical Engineering. 2021. pp. 1198–1204. DOI: 10.1007/978-3-030-54817-9_139 8. Nefedov A. V., Kitanov A. A., Chichenev N. A. Reengineering of the roller hardening machine of the sheet-rolling shop of JSC Ural Steel. Chernye metally. 2022. No. 5. pp. 22–26. 9. Nefedov A. V., Tanchuk A. V., Chichenev N. A. Modification of car tippler drive at Donskoy Ore Mining and Processing Plant. Gornyi zhurnal. 2022. No. 8. pp. 52–56. 10. Samusev S. V., Fadeev V. A., Didorova T. Yu. Development of efficient roll pass designs for forming of a sheet billet in production of longitudinal welded tubes of small and average diameters. Metallurg. 2020. No. 7. pp. 55–57. 11. Gorbatyuk S. M., Morozova I. V., Naumova M. G. Development of the operating model for re-industrialization process of heat treatment of stamping steels. Izvestiya vuzov. Chernaya metallurgiya. 2017. Vol. 60. No. 5. pp. 410–415. 12. Rakhshtadt A. G., Kaputkina L. M., Prokoshkin S. D., Supov A. V. (eds.). Metal science and heat treatment of steel and iron: a reference book (in 3 volumes). Vol. 3. Heat and thermomechanical treatment of steel and iron. Moscow : Intermet Inzhiniring. 2007. 919 p. 13. Steniko A., Tami W. Experience of improvement of direct quenching technology at the plant in the USA. Chernye metally. 2018. No. 12. pp. 41–43. 14. Khorram A., Davoodi Jamaloei A., Jafari A., Moradi M. Nd:YAG laser surface hardening of AISI 431 stainless steel; mechanical and metallurgical investigation. Optics and Laser Technology. 2019. Vol. 119. Article No. 105617. DOI: 10.1016/j.optlastec.2019.105617 15. Grigoryants A. G., Shiganov I. N., Misyurov A. I. Technological processes of laser treatment: a manual. Moscow : Izdatelstvo MGTU im N. E. Baumana. 2006. 663 p. 16. Panchenko V. Ya. (ed.). Laser technologies for materials processing: the current problems of fundamental researches and applied developments. Moscow : FIZMATLIT. 2009. 664 p. 17. Characteristics of 12KhM material: Reference book of grades of steels and alloys. Available at: http://splav-kharkov.com/mat_start.php?name_id=52 (Access date: 08.08.2023). 18. Sedov L. I. The methods of similarity and dimensions in mechanics. Moscow : Nauka. 1965. 388 p. 19. Chizhikov Yu. M. Theory of similarity and simulation of metal forming processes. Moscow : Metallurgiya. 1970. 296 p. 20. Longo S. G. Principles and Applications of Dimensional Analysis and Similarity. Parma : University of Parma. 2022. 428 p. 21. Makarichev Yu. A., Ivannikov Yu. N. The methods of experiment planning and data processing: a manual. Samara : Samarskiy gosudarstvennyi tekhnicheskiy universitet. 2016. 131 p. 22. Chichenev N. A., Gorbatyuk S. M., Naumova M. G.; Morozova I.G. Using the similarity theory to describe laser hardening processes. CIS Iron and Steel Review. 2020. Vol. 19. pp. 44–47. |