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INVESTIGATION OF FRICTIONAL WEAR OF STRUCTURAL CARBON PLASTICS

https://doi.org/10.31143/2221-7789-2025-4-05-09

EDN: DYOSKC

Abstract

The article is devoted to the study of frictional wear of structural carbon plastics based on phenylene and ultrahigh molecular weight polyethylene. A monotonous increase in the intensity of frictional wear was found with an increase in the parameter characterizing the level of shear stability of polymer composites. It is shown that the resistance of the polymer matrix to shear deformation is a universal characteristic used to describe the process of frictional wear of polymer materials. The results obtained in the work will allow us to develop a methodology for predicting the intensity of frictional wear as a function of pressure and sliding velocity.

About the Authors

V. Z. Aloev
Kabardino-Balkarian State Agricultural University
Russian Federation


Zhirikova Z. M.
Kabardino-Balkarian State Agricultural University
Russian Federation


References

1. Fatkhullin A. On the possibility of using polymer composite materials in agricultural engineering // Agricultural machinery: maintenance and repair. 2016.

2. № 2. pp. 21-32.

3. Borisov G.A., Kolodyazhnaya I.N. Promising polymer-based structural materials for use in agricultural machinery // Bulletin of RGATU. 2010. No. 4. P. 67.

4. Pratt J. Antifriction properties of polymer composite materials // Industrial polymer composite materials / ed. N. Richardson. M.: Khimiya. 1980. P. 215–240.

5. Sokolov L.B., Kuznetsov G.A., Gerasimov V.D. Phenylon – a heat-resistant aromatic polyamide // Plastic masses. 1967. No. 9. P. 21–23.

6. Mikhailin Yu.A. Superhigh-molecular-weight polyethylene // Polymer materials. 2003. No. 4. Pp. 24–27.

7. Kozlov G.V., Bura A.I., Aloev V.Z., Yanovsky Yu.G. The structural aspect of interphase adhesion in carbon plastics // Physical mezomechanics. 2005. Vol. 8, No. 2. Pp. 35–38.

8. Blumen A.V., Semenova M.V., Sheivekhman A.O., and Efros D.G. Methods of Calculating the Wear Resistance of Machine Parts Friction Surfaces. Moscow: Standards Publishing House, 1979. 100 p.

9. Bura A.I., Kozlov G.V., Kholodilov O.V. Wear and Shear Resistance of Carbon Fibers Based on Superhigh-Molecular-Weight Polyethylene // Friction and Wear. 2005. Vol. 26, No. 4. Pp. 407–411.

10. Bura A.I., Kozlov G.V. Structural Aspects of Friction and Wear of Phenyl Carbon Fibers // Friction and Wear. 2003. V. 24, No. 3. Pp. 279–283.

11. Balankin A.S. Synergetics of a Deformable Body. Moscow: Ministry of Defense of the USSR, 1991. 404 p.

12. Sanditov D.S., Bartenev G.M. Physical Properties of Disordered Structures. Novosibirsk: Nauka, 1982. 259 p.


Review

For citations:


Aloev V.Z., M. Zh.Z. INVESTIGATION OF FRICTIONAL WEAR OF STRUCTURAL CARBON PLASTICS. Proceedings of the Kabardino-Balkarian State University. 2025;15(4):05-09. (In Russ.) https://doi.org/10.31143/2221-7789-2025-4-05-09. EDN: DYOSKC

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ISSN 2221-7789 (Print)