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Статья
2019

Formation of Wear- and Corrosion-Resistant Ceramic Coatings by Combined Technologies of Spraying and Micro-Arc Oxidation


Yu. A. KuznetsovYu. A. Kuznetsov, M. A. MarkovM. A. Markov, A. V. KrasikovA. V. Krasikov, R. Yu. BystrovR. Yu. Bystrov, A. N. BelyakovA. N. Belyakov, A. D. BykovaA. D. Bykova, A. M. MakarovA. M. Makarov, Yu. A. FadinYu. A. Fadin
Российский журнал прикладной химии
https://doi.org/10.1134/S1070427219070012
Abstract / Full Text

Technological aspects of the formation of wear- and corrosion-resistant coatings on aluminum alloys and steel via an integrated use of methods of the low-temperature heterophase transfer, microarc oxidation, and magnetron sputtering. The tribological and anticorrosion properties of the coatings developed were estimated.

Author information
  • Orel State Agricultural University named after N.V. Parakhin, Orel, 302019, RussiaYu. A. Kuznetsov, M. A. Markov & A. D. Bykova
  • Kurchatovskii Institute Research Center-Prometei Central Research Institute of Structural Materials, St. Petersburg, 191015, RussiaA. V. Krasikov, R. Yu. Bystrov, A. N. Belyakov & A. M. Makarov
  • Institute of Problems of Mechanical Engineering, Russian Academy of Sciences, St. Petersburg, 199178, RussiaA. D. Bykova & Yu. A. Fadin
References
  1. Garshin, A.P., Gropyanov, V.M., Zaitsev, G.P., and Semenov, S.S., Keramika dlya mashinostroeniya (Ceramics for Machine Building), Moscow: Nauchtekhlitizdat, 2003.
  2. Golovnin, V.A., Kaplunov, I.A., Malyshkina, O.V., Ped’ko, B.B., and Movchikova, A.A., Fizicheskie osnovy, metody issledovaniya i prakticheskoe primenenie p’ezomaterialov (Physical Foundations, Methods of Study, and Practical Application of Piezomaterials), Moscow: Tekhnosfera, 2013.
  3. Alkhimov, A.P., Klinkov, S.V., Kosarev, V.F., and Fomin, V.M., Kholodnoe gazodinamicheskoe napylenie. Teoriya i praktika (Cold Gas-Dynamic Spraying: Theory and Practice), Novosibirsk: Fizmatlit, 2010, pp. 20–22.
  4. Avvakumov, M.E. and Rufitskii, M.V., Proc. Int. Symp. “Reliability and Property,” Perm. Gos. Univ., 2013, vol. 2, pp. 112–113.
  5. Gerashchenkov, D.A., Vasil’ev, A.F., Farmakovskii, B.V., and Mashek, A.Ch., Vopr. Materialoved., 2014, no. 1(77), pp. 87–97.
  6. Novikov, A.N., Batishchev, A.N., Kuznetsov, Yu.A., and Kolomeichenko, A.V., Vosstanovlenie i uprochnenie detalei iz alyuminievykh splavov mikrodugovym oksidirovaniem (Restoration and Strengthening of Aluminum Alloy Articles by Microarc Oxidation), Orel: Orel Gos. Agrarn. Univ., 2001.
  7. Kuznetsov, Yu.A., Kravchenko, I.N., Goncharenko, VV., and Glinskii, M.A., Tekhnol. Met., 2017, no. 10, pp. 18–24.
  8. Kuznetsov, Yu.A., Goncharenko, V.V., and Feryabkov, A.V., Tekhn. Oborud. Sela, 2015, no. 9, pp. 40–44.
  9. Kuznetsov, Yu.A., Weld. Int., 2005, vol. 19, no. 11, pp. 894–896.
  10. Kuznetsov, Yu.A., Mekh. Elektrif. Sel’sk. Khoz., 2005, no. 6, pp. 27–28.
  11. Kuznetsov, Yu.A., Mekh. Elektrif. Sel’sk. Khoz., 2005, no. 7, pp. 32–33.
  12. Kuznetsov, Yu.A., Kravchenko, I.N., and Shamarin, Yu.A., Tekhn. Oborud. Sela, 2018, no. 4, pp. 37–41.
  13. Grytsenko, K.P., Kolomzarov, Yu.V., and Belyaev, O.E., Schrader Semicond. Phys., Quantum Electronics & Optoelectronics, 2016, vol. 19, no. 2, pp. 139–148.
  14. Markov, M.A., Krasikov, A.V., Makarov, A.M., Gerashchenkov, D.A., Bykova, A.D., and Ordan’yan, S.S., Ogneupory Tekh. Keram., 2016, no. 10, pp. 30–36.
  15. Krasikov, A.V., Markov, M.A., and Bykova, A.D., Izv. SPb Gos. Tekh. Inst., 2016, no. 36 (62), pp. 36–41.
  16. Markov, M.A., Krasikov, A.V., Ulin, I.V., Gerashchenkov, D.A., Bykova, A.D., Yakovleva, N.V., Shishkova, M.L., and Fedoseev, M.L., Russ. J. Appl. Chem, 2017, vol. 90, no. 9, pp. 1417–1424.