MODELING THE TRIBOLOGICAL PROPERTIES OF POLYMER COATINGS BASED ON PHENYLONE WITH COPPER (II) COMPLEX MODIFIERS USING MATLAB

Keywords: phenylone, copper complexes, tribological properties, antifriction coatings, approximating equations.

Abstract

DOI: https://doi.org/10.26565/2079-1747-2025-35-09

Purpose. This study is dedicated to designing and evaluating antifriction polymer coatings based on phenylone C2, an aromatic polyamide with high thermal stability, modified with copper (II) complexes of the composition [Cu(HL)X₂]₂, where HL represents derivatives of benzimidazole-2-thiocarboxylic acid arylamides. The research aims to model the tribological behavior of these coatings, focusing on the effects of sliding speed, specific load, and modifier concentration, to improve the performance and durability of friction units in mechanical engineering applications under high-load conditions typical of industrial machinery.

Methods. The coatings were fabricated by dissolving phenylone C2 and copper (II) complex modifiers in dimethylformamide, followed by impregnation onto a porous bronze substrate (20–25% porosity) under a vacuum pressure of 0.00001 MPa for 30 minutes. The coated samples were cured at 420 K for 1.5 hours and then at 723 K for 2 hours to ensure complete hardening. Tribological testing was conducted using an SMT-2010 friction machine in a block-on-disk configuration, lubricated with I-40A industrial oil (GOST 20799-88). Tests spanned sliding speeds of 0.15 to 1.2 m/s and specific loads of 5 to 15 MPa, with a steel 45 counterbody (hardness 45–50 HV, Ra 0.4–0.63 μm). Friction coefficients were measured with an accuracy of ±0.001, and wear rates were determined gravimetrically with a precision of ±0.01 mg/m after 10-hour test cycles. Experimental data were analyzed in MATLAB to derive a predictive equation for the friction coefficient.

Results. Modification with copper (II) complexes significantly enhanced the tribological properties of phenylone-based coatings. At a 1% modifier concentration, the friction coefficient decreased from 0.080 to 0.045, and wear resistance improved by 60%, with coating No. 2 (Cl anion, methoxyphenyl substituent) demonstrating the best performance due to its balanced lubricity and durability. MATLAB processing yielded the equation f(V,P)=0.0335+0.0095⋅V+0.0005⋅P, accurately describing the friction coefficient’s dependence on sliding speed (V, m/s) and specific load (P, MPa) with a maximum deviation of less than 5%. Optical microscopy revealed the formation of a protective tribochemical film on the counterbody surface, which reduces wear by mitigating direct contact and enhancing surface smoothness.

Conclusions. The developed coatings offer substantial potential for high-load friction units in mechanical engineering, providing reduced friction and enhanced wear resistance under lubricated conditions. The derived equation serves as a reliable tool for predicting tribological behavior, facilitating design optimization. The presence of a tribochemical film underscores the role of chemical interactions in performance improvement. Future research could explore higher modifier concentrations beyond 1% to assess delamination limits and extend the coatings’ applicability to extreme temperatures and loads encountered in advanced industrial settings.

In cites: Stovpnyk O. V. & Sytar V. I. (2025). Modeling the tribological properties of polymer coatings based on phenylone with copper (II) complex modifiers using matlab. Engineering, (35), 85-94. https://doi.org/10.26565/2079-1747-2025-35-09

Downloads

Download data is not yet available.

References

Chernets, M., Shil’ko, S., Kornienko, A., & Pashechko, M. (2023). Triboanalysis of antifrictional materials based on polyamides for metal-polymer sliding bearings. Journal of Friction and Wear, 44(2), 63–70. https://doi.org/10.3103/s1068366623020034.

Xu, F., Ding, N., Li, N., Liu, L., Hou, N., Xu, N., Guo, W., Tian, L., Xu, H., Lawrence Wu, C.-M., Wu, X., & Chen, X. (2023). A review of bearing failure Modes, mechanisms and causes. Engineering Failure Analysis, 152, 107518. https://doi.org/10.1016/j.engfailanal.2023.107518.

Ivanochkin, P. G., Danilchenko, S. A., & Novikov, E. S. (2016). Antifriction composites based on Phenylone C2 for work under conditions of dry friction. Procedia Engineering, 150, 520–526. https://doi.org/10.1016/j.proeng.2016.07.033.

Gupta, B. R. (2023). Friction and wear mechanism of polymers, their composites and nanocomposites. У Tribology of polymers, polymer composites, and polymer nanocomposites (с. 51–117). Elsevier. https://doi.org/10.1016/b978-0-323-90748-4.00012-1

Panasiuk, A.G., & Ranskyi, A.P. (2005). Chemistry of thioamides: Copper (II) complexes as additives to lubricants. Issues of Chemistry and Chemical Technology, (5), 42–45.

Stovpnyk, O. V., & Sytar, V. I. (2008). Development of a methodology for obtaining and investigating the properties of phenylone-based coatings. Issues of Chemistry and Chemical Technology, (4), 84–89.

Rudnytskyj, A. (2018). Simulations of contact mechanics and wear of linearly reciprocating block-on-flat sliding test [Thesis, Luleå tekniska universitet, Institutionen för teknikvetenskap och matematik]. http://urn.kb.se/resolve?urn=urn:nbn:se:ltu:diva-68881. viewed June 23, 2025

Xu, S., Zhang, Y., Zhou, J., Chen, Z., Fu, H., Liu, B., & Ji, J. (2025). Tribology of polymer gears: Friction coefficient and wear. V Polymer gears (с. 495–514). Elsevier. https://doi.org/10.1016/b978-0-443-21457-8.00022-4.

Belyak, O. A., & Suvorova, T. V. (2021). Predicting the mechanical properties of antifriction composite materials. Mechanics of Composite Materials, 57(4), 647–656. doi:10.1007/s11029-021-09986-7

Yadav, R., Singh, M., Shekhawat, D., Lee, S.-Y., & Park, S.-J. (2023). The role of fillers to enhance the mechanical, thermal, and wear characteristics of polymer composite materials: A review. Composites Part A: Applied Science and Manufacturing, 175, 107775. https://doi.org/10.1016/j.compositesa.2023.107775.

Chaudhary, V. (2023). Tribology of polymer films and coatings. Tribology of polymers, polymer composites, and polymer nanocomposites (с. 335–355). Elsevier. https://doi.org/10.1016/b978-0-323-90748-4.00004-2.

Deleanu, L., Botan, M., & Georgescu, C. (2020). Tribological behavior of polymers and polymer composites. Tribology [working title]. IntechOpen. https://doi.org/10.5772/intechopen.94264.

Dudka, A. M., Kuzyaev, I. M., & Nachovnyi, I. I. (2017). Application of computer programs for analyzing tribological properties of fluoropolymer composites. Problems of Tribology, (4), 27–32. URL: https://tribology.khnu.km.ua/index.php/ProbTrib/article/download/635/1119. viewed June 23, 2025

Nanoth, R., Jayanarayanan, K., Sarath Kumar, P., Balachandran, M., & Pegoretti, A. (2023). Static and dynamic mechanical properties of hybrid polymer composites: A comprehensive review of experimental, micromechanical and simulation approaches. Composites Part A: Applied Science and Manufacturing, 107741. https://doi.org/10.1016/j.compositesa.2023.107741.

Lambiase, F., Balle, F., Blaga, L.-A., Liu, F., & Amancio-Filho, S. T. (2021). Friction-based processes for hybrid multi-material joining. Composite Structures, 266, 113828. https://doi.org/10.1016/j.compstruct.2021.113828.

Kabat, O., Sytar, V., Derkach, O., & Sukhyy, K. (2021). Polymeric composite materials of tribotechnical purpose with a high level of physical, mechanical and thermal properties. Chemistry & Chemical Technology, 15(4), 543–550. https://doi.org/10.23939/chcht15.04.543.

Klymenko, A., Anisimov, V., & Sytar, V. (2021). Development of thin-layer coatings based on phenylon for protecting surfaces from gas and hydroabrasive wear. Technical Sciences and Technology, (4(22), 28–34. https://doi.org/10.25140/2411-5363-2020-4(22)-28-34. (in Ukraine)

Kabat, O., Sytar, V., & Sukhyy, K. (2018). Antifrictional polymer composites based on aromatic polyamide and carbon black. Chemistry & Chemical Technology, 12(3), 326–330. https://doi.org/10.23939/chcht12.03.326.

Published
2025-07-03
Issue
No. 35 (2025): Engineering
Section
Статті