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  3. Volume 15, Number 4, 2021
  4. Polymeric Composite Materials of Tribotechnical Purpose with a High Level of Physical, Mechanical and Thermal Properties

Polymeric Composite Materials of Tribotechnical Purpose with a High Level of Physical, Mechanical and Thermal Properties

JCCT.
2021;
Volume 15, Number 4
: pp. 543–550
https://doi.org/10.23939/chcht15.04.543
Authors:
  1. Oleh Kabat
  2. Volodymyr Sytar
  3. Oleksii Derkach
  4. Kostyantyn Sukhyy
1
Ukrainian State University of Chemical Technology, Dnipro State Agrarian and Economic University
2
Ukrainian State University of Chemical Technology
3
Dnipro State Agrarian and Economic University
4
Ukrainian State University of Chemical Technology

Polymeric composites (PC) of tribological applications with a high level of physical, mechanical and thermal properties based on aromatic polyamide and silica gel have been developed. Regularities have been obtained that describe the effect of the filler content in PC on the friction coefficient, temperature on the friction surface and the intensity of linear wear rate of the studied PC-steel friction pair. It was found that the optimal silica gel content in the polymer matrix is 10 wt %. The morphology of the steel surface of friction after friction interaction with PC based on aromatic polyamide and silica gel was studied. The formation of an antifriction film on the steel surface of friction was discovered, which contributes to a decrease in the friction coefficient, temperature on the friction surface, and the linear wear intensity of the studied PC. The influence of the load and sliding speed on the main tribotechnical characteristics of the PC-steel friction pair has been studied. Mathematical laws were derived that describe the influence of the main external factors (load and sliding speed) on the friction coefficient and intensity of linear wear rate of the studied friction pair. Physical, mechanical and thermal investigations of the developed PC were carried out and it was found that the introduction of 10 wt % silica gel contributes to their 5–10 % increase.

friction unit
aromatic polyamide
silica gel
polymer composite
tribological properties
physical and mechanical properties
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