Название |
Device for two-way
cooling of rolls of multi-roll mills during laser hardening |
Информация об авторе |
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 M. V. Vasilyev, Senior Lecturer, Dept. of Engineering Technology Equipment, e-mail: mv@karfidovlab.com 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 |
Реферат |
Development of the automotive industry, electronics, aviation and other modern branches of science and technology has led to the need to produce thin (up to 0.01 mm thick) and the thinnest (up to 0.001 mm) high-quality band from high-alloy steels, non-ferrous and noble metals, obtained on multi-roll cold rolling mills. One of the main requirements for work rolls is a high and uniform hardness of the surface of the barrel after hardening, which should increase the wear resistance of the working layer, reduce the degree of its damage and, thereby, ensure the high quality of the rolled strip. An effective way to improve the quality of rolls with a diameter of up to 20 mm is surface laser hardening. In laser hardening of rolling rolls, a technological scheme was used, according to which the roll made a screw movement at preset speed relative to a fixed laser beam, which led to formation of a continuous screw track (spiral) of the hardened material on the surface of the roll. The minimal rotational frequency, at which uniformity of the active layer is observed, has been experimentally established, while laser hardening of samples with doublesided water jet cooling turned out to be the most effective. The design of a sprayer device for cooling of rolls during laser processing is proposed, which provides a uniform active layer along the entire barrel length and significantly reduces buckling of rolls. The technology for the manufacture of rolls has been developed, which makes it possible to obtain work rolls for multi-roll mills with high operational resistance, and to improve the technical and economic indicators of production of precision band. Tests of the rolls made of Kh9VMFSh steel after laser hardening on the mill 300 showed reduction in wear by 1.5-2.0 times compared to the standard volume-hardened rolls and reduction in roll consumption from 0.22 to 0.11 kg / t. |
Библиографический список |
1. Jiang Z. Y., Wei D., Tieu A. K. Analysis of cold rolling of ultrathin strip. Journal of Materials Processing Technology. 2009. Vol. 209. No. 9. pp. 4584–4589. 2. Sheikhi Sh., Angerbauer A., Wuppermann C. D. Developments in flat strip production. Chernye metally. 2010. No. 1. pp. 30-37. 3. Ritterbach B. Trends in steel research. Chernye metally. 2014. No. 9. pp. 75-78. 4. Rumyantsev M. I. Some approaches to improve the resource efficiency of production of flat rolled steel. CIS Iron and Steel Review. 2016. Vol. 12. pp. 32-36. 5. Sudakov N. V., Pellenen A. P. Reserves in cold sheet rolling. Metallurg. 2018. No. 11. pp. 47-51. 6. Tibar H., Jiang Z. Improving Thin Strip Profile Using Work Roll Cross and Work Roll Shifting Methods in Cold Strip Rolling. International Journal of Metals. 2017. Article ID 6489769., 10 p. DOI: 10.1155/2017/6489769 7. Mazur V. L., Nogovitsyn O. V. Theory and Technology of Sheet Rolling: Numerical Analysis and Applications. CRC Press: Boca Raton, FL, USA, 2019. 494 p. DOI: 10.1201/9781351173964 8. Parshin S. V. Innovating solutions in constructions of 20-roll mills. A manual. Ekaterinburg: Izdatelstvo Uralskogo universiteta. 2016. 76 p. 9. On the results of conduction of anti-dumping investigation in relation to steel forged rolls for metal rolling mills, manufactured in Ukraine and imported to the common customs area of the Customs Union. Moscow: Evraziyskaya ekonomicheskaya komissiya. 2014. 82 p. 10. Bashnin Yu. A., Dzyuba V. A., Blokhin I. E. et al. Study of Kh-9VMFSh steel for contact and fatigue strength. Izvestiya vuzov. Chernaya metallurgiya. 1986. No. 7. pp. 105-106. 11. Polukhin V. P., Nikolaev V. A., Tylkin M. A. etc. Reliability and durability of cold rolling rolls. Moscow: Metallurgiya. 1976. 448 p. 12. Smirnov A. E. Management on phase composition of complexalloyed heat-resistant steels during vacuum cementation and quenching. Metallovedenie i termicheskaya obrabotka metallov. 2020. No. 9 (783). pp. 45–52. 13. 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. Edited by Rakhshtadt A. G., Kaputkina L. M., Prokoshkin S. D., Supov A. V. Moscow: Intermet Inzhiniring. 2007. 919 p. 14. Maharjan N., Zhou W., Zhou Y., Wu N. Underwater laser hardening of bearing steels. Journal of Manufacturing Processes. 2019. Vol. 47. pp. 52-61. DOI: 10.1016/j.jmapro.2019.08.020 15. 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 16. Bahrami Balajaddeh M., Naffakh Moosavy H. Pulsed Nd:YAG laser welding of 17-4 PH stainless steel: Microstructure, mechanical properties, and weldability investigation. Optics and Laser Technology. 2019. Vol. 119. Article No. 105651, DOI: 10.1016/j.optlastec.2019.105651 17. 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. 18. 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. 19. Laser technologies of materials treatment: modern problems of fundamental and applied researches. Edited by Panchenko V. Ya. Moscow: FIZMATLIT. 2009. 664 p. 20. Polukhin V. P., Beletskiy V. V., Ivanov S. A. et al. Prospects of laser heat treatment application for hardening of working surface of rolls in multi-roll mills. Metallurgicheskaya i gornorudnaya promeshlennost. 1986. No. 6. pp. 33-34. 21. Veremeevich A. N., Beletskiy V. V., Ivanov S. A. On the problem of heat treatment of rolls in multi-roll mills. Izvestiya vuzov. Chernaya metallurgiya. 1986. No. 11. pp. 157-158. 22. Chichenev N. A., Chicheneva O. N., Karfidov A. O., Pashkov A. N. Selection of laser processing parameters for hot stamping tools based on mathematical planning of the experiment. CIS Iron and Steel Review. 2021. Vol. 22. pp. 37-40. 23. Bardovskiy A. D., Gerasimova A. A., Bibikov P. Ya. Principles of improvement of milling equipment. Gornyi zhurnal. 2020. No. 3. pp. 56-59. 24. Pinakhin I. A., Chernigovskiy V.A. Grounds of volumetric impulse laser strengthening of tool and structural materials. Stavropol: Izdatelstvo SKFU. 2014. 160 p. Available at: https://rucont.ru/efd/304170 25. Aborkin A. V., Vaganov V. E., Shlegel A. N., Bukarev I. M. Effect of laser hardening on die steel micro hardness and surface quality. Metallurgist. 2015. Vol. 59. No. 7-8. pp. 619-625. |