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Increasing of the Service Life of Consumable Parts of Mining and Metallurgical Machines with the Use of Technologies of Magnetic-Pulse Hardening

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Metallurgist Aims and scope

We consider specific features of variations of the properties of steels depending on the mode of their thermal treatment. We describe specific features of the influence of impulsive magnetic fields on the metals. We also present the results of testing of important operating characteristics of steels for different conditions of thermal treatment and combined processing with the application of impulsive magnetic fields. The aim of magnetic-pulse treatment is to shorten the idle time of commercial mining machines by increasing the service life of their consumable parts.

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References

  1. N. Yu. Yazev, Problems of the Use of Subsurface Resources [in Russian], RITs St. Petersburg Mining Univ., St. Petersburg, Russia (2018).

  2. S. M. Gorbatyuk and A. V. Kochanov, “Method and equipment for mechanically hardening the surface of rolling-mill rolls,” Metallurgist, 56, No. 3-4, 279–283 (2012); https://doi.org/10.1007/s11015-012-9571-2.

  3. O. N. Chicheneva and Y. L. Zarapin, “Strain resistance of metals in electroplastic forming,” Steel in Translation, 25, No. 3, 36–38 (1995).

  4. O. N. Chicheneva, V. S. Savchenko, and Y. L. Zarapin, “Mathematical model of the electroplastic rolling process,” Steel in Translation, 25, No. 5, 53–55 (1995).

  5. O. A. Kobelev, A. V. Zinov’ev, and M. A. Tsepin, “Effective production of large pipe blanks,” Steel in Translation, 39, No. 6, 501–505 (2009); https://doi.org/10.3103/S0967091209060163.

  6. A. Y. Albagachiev, A. M. Keropyan, A. A. Gerasimova, and O. A. Kobelev, “Determination of rational friction temperature in lengthwise rolling,” CIS Iron Steel Rev., 19, 33–36 (2020); https://doi.org/10.17580/cisisr.2020.01.07.

  7. M. G. Naumova, I. G. Morozova, and P. V. Borisov, “Study of metal surface with color image obtained with laser marking,” Solid State Phenom., 299 SSP, 943–948 (2020).

  8. M. G. Naumova, I. G. Morozova, A. Y. Zarapin, and P. V. Borisov, “Copper alloy marking by altering its surface topology using laser heat treatment,” Metallurgist, 62, No. 5-6, 464–469 (2018); https://doi.org/10.1007/s11015-018-0682-2.

  9. N. A. Chichenev, “Reengineering of the slab-centering unit of a roughing mill stand,” Metallurgist, 62, No. 7-8, 701–706 (2018); https://doi.org/10.1007/s11015-018-0711-1.

  10. A. Keropyan, S. Albul, and A. Zarapin, “Problem of increasing tractive effort of railway locomotives in conditions of Arctic and continental shelf regions,” Lect. Notes Mech. Eng., 651–658 (2020); https://doi.org/10.1007/978-3-030-22063-1-69.

  11. L. Jiawen, S. Timushev, D. Klimenko, and A. Krivenko, “Modeling pressure pulsation fields in a screw centrifugal pump,” in: Proc. 26th Internat. Congr. Sound Vibrat. ICSV, Vol. 2 (1–8) (2019), pp. 804–811.

  12. Zh. A. Popova, “Specific features of changes in the physicomechanical properties of structural steels subjected to magnetic-pulse treatment,” Vestn. Brest Gos. Tekh. Univ., Mashinostr., No. 4, 43–46 (2012).

  13. V. Glushchenkov and I. Belyaeva, “Technological schemes of hybrid and combined technologies using static and dynamic loads,” Key Eng. Mater., 746 KEM, 246–254 (2017).

  14. I. O. Vakulenko, D. M. Bolotova, and M. A. Hryshchenko, “Influence of the shock wave of electric discharge on the fatigue characteristics of thermally hardened steel,” Mater. Sci., 54, No. 1, 78–81 (2018).

    Article  CAS  Google Scholar 

  15. G. V. Sedel’nikova, G. S. Krylova, and P. P. Anan’ev, “Experience of application of the magnetic-pulse technology for the intensification of the processes of gold extraction from ores and concentrates,” Ruda Metally, No. 1, 71–73 (2005).

  16. S. A. Goncharov, P. P. Anan’ev, V. P. Bruev, T. N. Gzogyan, V. A. Boldyrev, and S. M. Ryakhovskii, “Magnetic-pulse treatment (MPT) of ferruginous quartzites aimed at their softening prior to grinding in mills,” Gorn. Inf.-Analit. Byull., No. 1, 12–17 (2004)

  17. I. Belyaeva, R. Jusupov , and V. Glushchenkov, “Problems of realization of static-dynamic technologies and ways of their solutions,” Key Eng. Mater., 684, 515–522 (2016).

    Article  Google Scholar 

  18. D. Chernikov and V. Glushchenkov, “Changing of mechanical and technological properties of cast metal as a result of pulse-magnetic processing of melts,” Key Eng. Mater., 746, 255–261 (2017).

    Article  Google Scholar 

  19. M. U. Rustamova, “Application of magnetic-pulse treatment for the stabilization of machine parts,” Molod. Uchen., No. 11, 423–425 (2015).

  20. A. M. Keropyan, D. A. Kuziev, and A. E. Krivenko, “Process research of wheel-rail mining machines traction,” Lect. Notes Mech. Eng., 703–709 (2020); https://doi.org/10.1007/978-3-030-22063-1-75.

  21. D. Kouziyev, A. Krivenko, D. Chezganova, and B. Valeriy, “Sensing of dynamic loads in the open-cast mine combine,” E3S Web Conf., 105, No. 03014 (2019); https://doi.org/10.1051/e3sconf/201910503014.

  22. A. V. Alifanov, et al., “Specific features of the magnetic-pulse hardening treatment of steel cylindrical products of variable section,” Lit’e Metal., No. 2, 88–96 (2017).

  23. E. A. Rybkin, “Magnetic-pulse hardening of cutting tools,” Tr. FGUP RFYaTs-VNIIEF, Issue 7, 503–506 (2012).

  24. I. V. Belyi, S. M. Fertik, and L. T. Khimenko, A Handbook on the Magnetic-Pulse Treatment of Metals [in Russian], Vyshcha Shkola, Kharkiv (1977).

  25. A. S. Sobolev and V. I. Pudov, “Improvement of the wear resistance of products made of tool steel,” Vestn. TGU, 18, No. 4, 1794–1795 (2013).

    Google Scholar 

  26. GOST 1497–84, Metals. Methods for Tensile Testing [in Russian], Introduced on 01.01.1986, Minchermet USSR (1986).

  27. A. V. Bondar’, Quality and Reliability [in Russian], Mashinostroenie, Moscow (2007).

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Authors and Affiliations

  1. “Innovation Mining Technologies,” Association of Subjects of Innovation Activity in the Mining Industry, Moscow, Russia

    P. P. Anan’ev

  2. “GAN,” LLC, Moscow, Russia

    A. V. Plotnikova

  3. “Chernogorsk Repair and Engineering Works,” JSC, Chernogorsk, Khakasiya, Russia

    V. V. Prishchepov & S. G. Fuks

  4. “Siberian Coal Energy Company,” JSC, Moscow, Russia

    S. I. Kontsevoy

Authors
  1. P. P. Anan’ev
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  2. A. V. Plotnikova
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  3. V. V. Prishchepov
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  4. S. G. Fuks
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  5. S. I. Kontsevoy
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Correspondence to P. P. Anan’ev.

Additional information

Translated from Metallurg, Vol. 65, No. 5, pp. 88–93, May, 2021. Russian DOI: 10.52351/00260827_2021_05_88.

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Anan’ev, P.P., Plotnikova, A.V., Prishchepov, V.V. et al. Increasing of the Service Life of Consumable Parts of Mining and Metallurgical Machines with the Use of Technologies of Magnetic-Pulse Hardening. Metallurgist 65, 586–592 (2021). https://doi.org/10.1007/s11015-021-01194-x

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  • DOI: https://doi.org/10.1007/s11015-021-01194-x

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