Studying the effect of the combined technology on durability of the shaft­type parts

Authors

DOI:

https://doi.org/10.15587/1729-4061.2018.132253

Keywords:

sprayed coatings, porosity, bond strength, wear resistance, electro-contact strengthening, durability, endurance, combined technology, recovery

Abstract

Restoration of shaft parts with extending their service life is an important reserve of development and growth of repair efficiency. Improvement of wear resistance and durability of parts of agricultural machinery is a priority trend in the present-day machine building. For this purpose, analysis was carried out and the process of electro-contact strengthening of sprayed wear resistant coatings on shaft parts was considered.

Experimental studies of physical and mechanical properties of wear resistant coatings obtained by the combined technology have been carried out. Dependence of the bond strength, porosity of the sprayed wear resistant coatings on current and pressure of the electro-contact strengthening process was established. With an increase in strengthening pressure up to 30‒40 MPa and current up to 14‒16 kA, there was an increase in the bond strength of the sprayed coating up to 180...220 MPa and a decrease in porosity to 2...5 %.

Wear resistance of the coatings obtained by the combined technology in the range of the studied loads and speeds was higher than that of the coatings obtained separately by classical technologies of flame and electric arc spraying. The highest wear resistance indicators were found in the coating of FMI-2 material applied by the combined technology.

Fatigue strength tests of the strengthened parts have shown that the coatings obtained by the combined technology increased the fatigue limit of the parts recovered by spraying by 20 %, and that of the parts without coatings by 50 %.

A comparative estimation of physical-mechanical and operational properties of the coatings obtained by electric arc and flame spraying and the combined technology was made. It was established that the use of electro-contact strengthening of the sprayed wear resistant coatings at a pressure of 20...40 MPa, current strength of 11...16 kA, duration of current pulses and pauses of 0.02...0.04 s significantly increased their physical and mechanical properties and performance.

Author Biographies

Natalia Miedviedieva, National University of Life and Environmental Sciences of Ukraine Heroiv Oborony str., 15, Kyiv, Ukraine, 03041

PhD, Associate Professor

Department of Standardization and certifying of agricultural products

Miсhael Levitsky, Limited Liability Company "TMS Ukraine" Vozdvyzhenska str., 44, Kyiv, Ukraine, 04071

PhD, Associate Professor, General Director

Vladislav Sukhenko, National University of Life and Environmental Sciences of Ukraine Heroiv Oborony str., 15, Kyiv, Ukraine, 03041

Doctor of Technical Sciences, Professor, Head of Department

Department of Standardization and certifying of agricultural products

References

  1. Volovik, E. L. (1983). Spravochnik po vosstanovleniyu detaley. Moscow: Kolos, 51.
  2. Troshchenko, V. T. (Ed.) (2006). Pokrytiya i ih ispol'zovanie v tekhnike. Prochnost' materialov i konstrukciy. Kyiv: Akademperiodika, 981–1074.
  3. Takadoum, J., Miner, J. (2000). Wear-corrosion behaviour of some metals. JOM: Metals and Mater. Soc., 52 (11), 131.
  4. Taratuta, A. I., Sverchkov, A. A. (1986). Progressivnye metody remonta mashin. Minsk: Uradzhay, 376.
  5. Medvedeva, N., Radko, О. (2014). Management and control of quality parameters of wear-resistant coatings. Problems of friction and wear, 1 (62), 100–103.
  6. Sukhenko, Y., Miedviedieva, N., Sukhenko, V. (2017). Analysis and choice of coatings for increasing the durability of parts of diffusion units of sugar plants. Eastern-European Journal of Enterprise Technologies, 6 (12 (90)), 27–34. doi: 10.15587/1729-4061.2017.119296
  7. Solncev, St. S. Rozenenkova, V. A., Mironova, N. A. (2012). Polifunkcional'nye zashchitnye tekhnologicheskie pokrytiya dlya metallov i splavov. Vse materialy. Enciklopedicheskiy spravochnik, 6, 28–30.
  8. Sukhenko, Yu. H., Lytvynenko, O. A., Sukhenko, V. Yu. (2010). Nadiynist i dovhovichnist ustatkuvannia kharchovykh i pererobnykh vyrobnytstv. Kyiv, 547.
  9. Medvedeva, N. A., Lopata, L. A., Korzh, V. N. (2001). Perspektivy razvitiya inzhenerii poverhnosti detaley mashin. Tekhnika v silsko-hospodarskomu vyrobnytstvi, haluzeve mashynobuduvannia, avtomatyzatsiya, 10, 3–5.
  10. Michio, T., Nobuyuki, A., Junij, M., Akio, Ya., Yoshiaki, A. (1992). Improvement of sprayed coatings with ultra high voltage EB melting. Trans. JWRI, 21 (2), 229–300.
  11. Kadyrmetov, A. M. (2012). Issledovanie processov plazmennogo naneseniya i uprochneniya pokrytiy i puti upravleniya ih kachestvom. Nauchniy zhurnal KubGAU, 81 (07), 1–18.
  12. Podchernyaeva, I. A. (2012). Lazernoe oplavlenie gazotermicheskih pokrytiy na osnove kortinita. Tekhnologiya i organizaciya proizvodstva, 3, 43–50.
  13. Zvyaginceva, A. V. (20005). Modificirovanie poverhnostnogo sloya detaley splavami Ni–B dlya mashinostroitel'nogo oborudovaniya. Mir tekhniki i tekhnologiy, 11, 42–45.
  14. Beliy, L. V. (2017). Inzheneriya poverhnostey konstrukcionnyh materialov s ispol'zovaniem plazmennyh i puchkovyh tekhnologiy. Minsk, 457.
  15. Mahdavinejad, R. A., Mahdavinejad, A. (2005). ED machining of WC–Co. Journal of Materials Processing Technology, 162-163, 637–643. doi: 10.1016/j.jmatprotec.2005.02.211
  16. Saushkin, B. P. (Ed.) (2013). Naukoemkie tekhnologii mashinostroitel'nogo proizvodstva: Fiziko-himicheskie metody i tekhnologi. Moscow, 928.
  17. Selvan, C. P., Rammohan, N., Hk, S. (2015). Laser Beam Machining: A Literature Review on Heat affected Zones, Cut Quality and Comparative Study. European Journal of Advances in Engineering and Technology, 2 (10), 70–76.
  18. Belocerkovskiy, M. A. (2014). Racional'noe aktivirovanie processov gazoplamennogo napyleniya metallov i polimerov. Vestnik Polockogo gosudarstvennogo universiteta. Seriya V: Promyshlennost', prikladnye nauk, 3, 22–28.
  19. Li, W., Yang, K., Yin, S., Yang, X., Xu, Y., Lupoi, R. (2018). Solid-state additive manufacturing and repairing by cold spraying: A review. Journal of Materials Science & Technology, 34 (3), 440–457. doi: 10.1016/j.jmst.2017.09.015
  20. Harlamov, Yu. A., Polonskiy, L. G. (2016). Gazotermicheskoe napylenie. Sovremennoe sostoyanie i perspektivy razvitiya, 2 (226), 5–19.
  21. Lopata, L. A., Savchenko, N. A. (2001). Povyshenie kachestva metallizacionnyh pokrytiy. Vysoki tekhnolohiyi v mashynobuduvanni, 1 (4), 175–179.
  22. Pohmurskiy, V. I., Student, M. M., Dovgunyk, V. M. et. al. (2002). Poroshkovye provoloki sistem FeCrB+Al i FeCrB+Al+C dlya elektrodugovoy metallizacii. Avtomaticheskaya svarka, 3, 32–35.
  23. Liashenko, B. A., Trapezon, O. H., Bondar, A. V., Mirnenko, V. I., Rutkovskyi, A. V. (2003). Pat. No. 2489 UA. Ustanovka dlia doslidzhennia zrazkiv materialiv na termomekhanichnu vtomu. MPK: G01N 3/00. No. 2003076427; declareted: 09.07.2003; published: 17.05.2004, Bul. No. 5.

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Published

2018-05-25

How to Cite

Miedviedieva, N., Levitsky, M., & Sukhenko, V. (2018). Studying the effect of the combined technology on durability of the shaft­type parts. Eastern-European Journal of Enterprise Technologies, 3(12 (93), 14–22. https://doi.org/10.15587/1729-4061.2018.132253

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Section

Materials Science