Funct. Mater. 2024; 31 (4): 557-560.

doi:https://doi.org/10.15407/fm31.04.557

Effect of binary Al-Ni alloy on the rate of abrasive wear of ultra-high molecular weight polyethylene

V.F. Bashev1, S.V. Tomin1, T.V. Kalinina1, O.I. Kushnerov2, N.P. Bondar1

1Dniprovsk State Technical University, Kamyanske
2Oles Honchar Dnipro National University, Dnipro

Abstract: 

The paper investigates the influence of the content of Al-Ni alloy quenched from the molten state on the abrasive wear rate of ultra-high-molecular-weight polyethylene on rigidly attached abrasive particles. Studies have shown that the addition of 5–30 mass% of the quenched aluminum alloy to ultra-high-molecular-weight polyethylene reduces the rate of abrasive wear by ~50%. The improvement of this indicator is due to the high values of microhardness, dislocations density, and microstresses of rapidly quenched Al-Ni alloys.

Keywords: 
ultra-high-molecular-weight polyethylene, lattice period, microhardness, microstress, binary alloy, abrasive wear rate, abrasive particles.
References: 
1. Patent 17852A Ukraine, MPK (2006.01) F16C 33/04.
 
2. Patent 101050 Ukraine, MPK (2006.01) C08L 75/04.
 
3. Patent 92212 Ukraine MPK (2014.01) C08L 77/00
https://doi.org/10.17360/UHPPD.2014019259
 
4. O. Burya, Ye. Yeriomina, O. Lysenko, A. Konchits, A. Morozov, Polymer composites based on thermoplastic binders, Srednyak T. K. Press (2019).
 
5. K.A. Yeriomina, O.B. Lysenko, V.K. Nosenko, Ya. E. Yarovyi. J. Physics and Electronics, 29, 1 (2021).
https://doi.org/10.15421/332105
 
6. K.S. Kanaga Karuppiah, A.L. Bruck, S. Sundararajan, J. Wang, Z. Lin, Z.-H. Xu, X. Li. Acta Biomater, 4 (2008).
https://doi.org/10.1016/j.actbio.2008.02.022
 
7. Muzamil Hussain, Rizwan Ali Naqvi, Naseem Abbas, Shahzad Masood Khan, Saad Nawaz, Arif Hussain, Nida Zahra, Muhammad Waqas Khalid. Polymers (Basel), 12, 2 (2020).
https://doi.org/10.3390/polym12020323
 
8. A.I. Burya, Ye.A. Yeriomina, J. Friction and Wear, 37, 2 (2016).
https://doi.org/10.3103/S1068366616020033
 
9. A.-M.V. Tomina, O.V. Yeromenko, Functional Materials, 30, 403 (2023).
  https://doi.org/10.15407/fm30.03.403
 
10. S.I. Mudryi, Y.O. Kulik, A.S. Yakymovych, X-ray structural analysis in materials science. teaching method manual. LNU named after I. Frank., Lviv (2017).
 
11. A. Dobrovolsky, V. Kosenko, Mining, constructional road and melioration machines, 87 (2016).
 
12. M.V. Kindrachuk, V.I. Dvoruk. J. Problems of Tribology, 2 (2011).

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