Research of the influence of biological lubricants on the tribological properties of the steel - titanium alloy friction pair

The paper presents the results of a study of the influence of biological lubricants on the tribological properties of the friction pair "steel - titanium alloy". Tribological tests were carried out with indentation (scratching) on a friction path of 2 mm with an increase in load from 0.030 to 10 N on a Micro Indentation Tester CSM. The studies were carried out under various conditions: dry rubbing, with hyaluronic acid and with biological oil. It was found that lubricating media of biological origin create boundary lubricating layers on friction surfaces and are able to reduce wear due to microcutting. The development and experimental verification of a mathematical model expressing the dependence of the penetration depth on the friction path and other parameters has been implemented.

1. Tomoyuki Kaya. 2007, “Recent developments in Research, production and application of titanium in Japan”, Ti-2007. Science and technology. Proceedings of the 11th World conference on titanium, Kyoto, Japan. pp. 49–56.

2. Wang Hao. 2011, “Overview and prospect of the world titanium emerging applications market”, Ti-2011. Science and technology. Proceedings of the 12th World conference on titanium, Beijing. China. pp. 2227–2231.

3. Niinomi Mitsuo 2011, “Recent trends in titanium research and development in Japan”, Ti-2011. Science and technology. Proceedings of the 12th World conference on titanium, Beijing. China. pp. 30–37.

4. Niinomi Mitsuo, Kazuo Kagami. 2016, “Recent topics of titanium research and development in Japan”, Ti-2015. Science and technology. Proceedings of the 13th World conference on titanium, San Diego. USA. pp. 27–40.

5. Jing Li, Jianzhong Zhou, Aixin Feng, Shu Huang, XiankaiMeng, Yunhui Sun, Yunjie Sun, Xuliang Tian and Yu Huang, 2018, “Investigation on mechanical properties and microstructural evolution of TC6 titanium alloy subjected to laser peening at cryogenic temperature”, Materials Science & Engineering A, 734, pp. 291–298.

6. L.C. Zhou, Y.H. Li, W.F. He, G.Y. He, X.F. Nie, D.L. Chen, Z.L. Lai, Z.B. An, 2013, “Deforming TC6 titanium alloys at ultrahigh strain rates during multiple laser shock peening”, Materials Science & Engineering A. 578. pp. 181–186.

7. R. Shi, Z.H. Nie, Q.B. Fan, F.C.Wang, Y. Zhou, X. Liu, 2018, “Correlation between dislocationdensity- based strain hardening and microstructural evolution in dual phase TC6 titanium alloy”, Materials Science & Engineering A. 715. pp. 101–107.

8. Nochovnaya N.A., Shiryaev A.A. 2018, “Influence of heat treatment modes on mechanical properties and structure of experimental composition of high-strength pseudo-𝛽-titanium alloy”, Trudy VIAM. No. 6 (66). pp. 22–29.

9. Sokolov S.A., Plotnikov D.G., Grachev A.A., Lebedev V.A. 2020, “Evaluation of loads applied on engineering structures based on structural health monitoring data”, International Review of Mechanical Engineering, 14 (2). pp. 146–150.

10. Skotnikova М.А., Krylov N.A., Ivanova G.V., Tsvetkova A.A. 2015, “Structural and phase transformation in material of blades of steam turbines from titanium alloy after technological treatment”, Lecture Notes in Control and Information Sciences. pp. 93–101.

11. Shaboldo O.P., Vitorskii Y.M., Skotnikova M.A. 2017, “Formation of the structure and properties of 𝛽-type titanium alloy upon thermomechanical treatment”, Physics of Metals and Metallography, pp. 75–80.

12. Skotnikova M.A., Ivanova G.V., Popov A.A., Paitova O.V. 2017, Localization of plastic deformation in hcp crystals upon indentation and scratching. Modern mechanical engineering: Science and education: materials of the 6th international scientific and practical conference, Ed. A.N. Evgrafova and A.A. Popovich. SPb.: Publishing house of Polytechnic. University. 402–412.

13. Skotnikova M.A., Ivanova G.V., Strelnikova A.A. 2019, “Macromechanism destruction of structurally and crystallographically textured titanium billets”, International Conference on Industrial Engineering. Springer, Cham. pp. 1097–1105.

14. Skotnikova M.A., Strelnikova A.A., Ivanova G.V., Popov A.A. Syundyukov I.S. 2020, “Localization of plastic deformation in austenitic steel at low-temperature cycling loading”, Lecture Notes in Mechanical Engineering. pp. 175–182.

15. Skotnikova M.A., Krylov N.A. 2017, “About the Nature of Dissipative Processes in Cutting Treatments of Titanium Vanes», Advances in Mechanical Engineering. Selected Contributions from the Conference “Modern Engineering: Science and Education”, Saint Petersburg, Russia, June 2016. Springer - Verlag. Berlin-Heidelberg. pp. 115–124.

16. Cong Li, Like Qin, Ming Li, Hui Xiao, Qi Wang, Jian Chen. 2020, “Influence of deformation strain rate on the mechanical response in a metastable b titanium alloy with various microstructures”, Journal of Alloys and Compounds. V.815.

17. Bely A.V., Kukareko V.A., Kononov A.G .and etc. 2008, “Friction and wear”. T.29. No.6. pp. 571–577.

18. Chertovskikh S.V. 2008, “Tribotechnical characteristics of ultrafine-grained titanium and its alloys”: Author. dis. ... Cand. tech. sciences.

19. Savostikov V.M., Potekaev A.I., Tabachenko A.N., Dudarev E.F., Shulepov I.A. 2012, “Physicomechanical and tribological properties of titanium alloys with gradient antifriction coating Ti – C – Mo – S”, Bulletin of higher educational institutions. Physics, Vol. 55, No.9. pp. 71–77.

20. Breki A.D., Chulkin S.G., Gvozdev A.E., Kuzovleva O.V. 2020, “On the evolution of mathematical models of friction sliding of solids”, Chebyshevskii Sbornik, 21 (4). pp. 327–332.

21. Breki A.D., Gvozdev A.E., Kuzovleva O.V., Kuzovlev V.Yu. 2020, “Empirical mathematical models of plasticity, strength and wear resistance of materials on the example of P18 steel”, Chebyshevskii Sbornik, 21 (3), pp. 272–291.

22. Breki A.D., Chulkin S.G., Gvozdev A.E., Kolmakov A.G. 2021, “Mathematical Simulation of the Sliding Friction of Silicon Carbide in an Aqueous Medium”, Russian Metallurgy (Metally), 4, pp. 507–511.

23. Breki A.D., Chulkin S.G., Gvozdev A.E., Kolmakov A.G., Kuzovleva O.V. 2021, “Empirical Mathematical Model for the Wear Kinetics of Porous Gas-Thermal Coatings”, Russian Metallurgy (Metally), 4, pp. 496–500.