Structure and Properties of Ti–C–Ni–Al Wear-Resistant Coatings Obtained by HIPIMS Method

M. A. Zasypkin; Засыпкин М. А.; A. D. Sytchenko; Сытченко А. Д.; F. V. Kiryukhantsev-Korneev; Кирюханцев-Корнеев Ф. В.

doi:10.31857/S0044185622700048

Structure and Properties of Ti–C–Ni–Al Wear-Resistant Coatings Obtained by HIPIMS Method

Authors: Zasypkin M.A.¹, Sytchenko A.D.¹, Kiryukhantsev-Korneev F.V.¹
Affiliations:
1. National University of Science and Technology MISIS, 119049, Moscow, Russia
Issue: Vol 59, No 1 (2023)
Pages: 45-53
Section: НОВЫЕ ВЕЩЕСТВА, МАТЕРИАЛЫ И ПОКРЫТИЯ
URL: https://j-morphology.com/0044-1856/article/view/663827
DOI: https://doi.org/10.31857/S0044185622700048
EDN: https://elibrary.ru/PUAKGS
ID: 663827

Cite item

Full Text

Open Access
Restricted Access

Access granted
Restricted Access

Subscription Access

Abstract
About the authors
References
Supplementary files
Statistics

Abstract

Coatings obtained by high-power impulse magnetron sputtering (HIPIMS) were tested using a 64% Ti–16% C–14% Ni–6% Al target (42.5 at % Ti, 42.5 at % C, 7.5 at % Ni, 7.5 at % Al). The microstructure and composition of the coatings were studied using scanning electron microscopy, optical emission spectroscopy of a glow discharge, and X-ray phase analysis. Coatings were studied in terms of their hardness, modulus of elasticity, elastic recovery, resistance to elastic fracture strain, resistance to plastic deformation, friction coefficient and friction-slip wear resistance, resistance to shock-dynamic loading, as well as oxidation resistance. Field tests of coatings on the cutting tool were carried out. Properties of the coatings obtained by direct current and high-power pulse mode were compared. The results showed that the Ti–C–Ni–Al coatings had a dense homogeneous structure, a hardness of 12–26 GPa, an elastic modulus of 143–194 GPa, an elastic recovery of 66–90%, a low friction coefficient of 0.24–0.4, and high oxidation resistance at 800°C. The coating deposited according to the optimal regime confirmed its high practical efficiency during full-scale tests, reducing the cutting tool wear by ~25%.

References

Fukui H. // SEI technical review. 2016. V. 82. P. 39–45.
Mahboobeh A., Aghdam S.R., Ahangarani A. et al. // Advanced Materials Research. 2014. M. 829. № 476.
Chen L., Wang S.Q., Zhou S.Z. et al. // International J. Refractory Metals and Hard Materials. 2008. V. 26. P. 456–460.
Akinribide O.J., Obadele B.A., Akinwamide S.O. et al. // Ceramics International. 2019. V. 45. P. 21077–21090.
Xiao M., Zhang Y., Wu Y. et al. // International J. Refractory Metals and Hard Materials. 2021. V. 101. № 105672.
Shmorgun V.G., Bogdanov A.I., Kulevich V.P. et al. // Materials Today: Proceedings. 2021. V. 38. P. 1627–1630.
Chaliyawala H.A., Gupta G., Kumar P. et al. // Surface and Coatings Technology. 2015. V. 276. P. 431–439.
Ma M., Sun W.-C., Zhang Y.-G. et al. // Materials Research. 2019. V. 22. № e20190530.
Grandin M., Nedfors N., Sundberg J. et al. // Surface and Coatings Technology. 2015. V. 276. P. 210–218.
Kiryukhantsev-Korneev Ph.V., Sheveyko A.N., Shvindina N.V. et al. // Ceramics International. 2018. V. 44. P. 7637–7646.
Kiryukhantsev-Korneev Ph.V., Sheveyko A.N., Vorotilo S.A., Levashov E.A. // Ceramics International. 2020. V. 46. P. 1775–1783.
Bao Y., Huang L., An Q. et al. // J. European Ceramic Society. 2020. V. 40. P. 4381–4395.
Krysina O.V., Ivanov Yu.F., Koval N.N. et al. // Surface and Coatings Technology, 2021. V. 416. № 127153.
Amudha A., Nagaraja H.S., Shashikala H.D. // Physica B: Condensed Matter. 2021. V. 602. № 412409.
Bolelli G., Colella A., Lusvarghi L. et al. // Wear. 2020. V. 450–451. № 203273.
Abegunde O., Akinlabi E., Oladijo P. // Materials Today: Proceedings. 2021. V. 44. P. 1221–1226.
Chen Y., Wu G., He J. // Materials Science and Engineering: C. 2015. V. 48. P. 41–47.
Singh A., Schipmann S., Mathur A. et al. // Applied Surface Science. 2017. V. 414. P. 114–123.
Abegunde O.O., Akinlabi E.T., Oladijo O.P. // Applied Surface Science. 2020. V. 520. № 146323.
Tudose I.V., Suchea M.P. // Functional Nanostructured Interfaces for Environmental and Biomedical Applications. 2019. P. 15–26.
Baghriche O., Zertal A., Ehiasarian A.P. et al. // Thin Solid Films. 2012. V. 520. P. 3567–3573.
Sytchenko A.D., Kiryukhantsev-Korneev Ph.V. // J. Phys.: Conf. Ser. 2021. V. 2064. № 012062.
Souček P., Hnilica J., Klein P. et al. // Surface and Coatings Technology. 2021. V. 423. № 127624.
Helmersson U., Lattemann M., Bohlmark J. et al. // Thin Solid Films. 2006. V. 513. P. 1–24.
Kiryukhantsev-Korneev Ph.V., Sytchenko A.D., Sviridova T.A. et al. // Surface and Coatings Technology. 2022. № 128141.
Musil J., Zeman P. // Solid State Phenomena. 2007. V. 4. P. S6–S10.
Papa F., Gerdes H., Bandorf R. et al. // Thin Solid Films. 2011. V. 520. P. 1559–1563.
Шевцова Л.И. Дис. к-та техн. наук: 05.16.09. НГТУ. 2015. 200 с.
Shtansky D.V., Kiryukhantsev-Korneev Ph.V., Sheveyko A.N. et al. // Surface and Coatings Technology. 2009. V. 203. P. 3595–3609.
André B., Lewin E., Jansson U., Wiklund U. // Wear. 2011. V. 270. P. 555–566.
Pang X., Shi L., Wang P. et al. // Surface and Coatings Technology. 2009. V. 203. P. 1537–1543.