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The method of model triboexperimental studies to determine the basic mathematical model parameters of materials wear resistance at sliding friction is considered. The quantitative relative experimental characteristics of wear resistance of glass fibre and carbon fibre reinforced polyamide used in metal-polymer gear couple have been determined. Wear resistance functions of these functional polymeric composites have been established as the basic ones in the tribokinetic mathematical model of material wear for sliding friction conditions. Also, according to the conducted researches, wear resistance diagrams were constructed. They may be used as graphical indicators of wear resistance in the required range of specific friction forces. The dependences that connect the characteristic functions of wear resistance of these materials (obtained by the developed mathematical tribokinetic wear model) with linear wear and gearing service life are presented.
Czasopismo
Rocznik
Tom
Strony
206--210
Opis fizyczny
Bibliogr. 46 poz., rys., wykr.
Twórcy
autor
- Aerospace Faculty, Department of engineering, standardization and certification, National Aviation University, 1, Liubomyra Huzara ave., Kyiv, Ukraine, 03058
autor
- Aerospace Faculty, Department of engineering, standardization and certification, National Aviation University, 1, Liubomyra Huzara ave., Kyiv, Ukraine, 03058
autor
- Aerospace Faculty, Department of engineering, standardization and certification, National Aviation University, 1, Liubomyra Huzara ave., Kyiv, Ukraine, 03058
autor
- Aerospace Faculty, Department of computerized electrotechnical systems and technologies, National Aviation University, 1, Liubomyra Huzara ave., Kyiv, Ukraine, 03058
Bibliografia
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- 6. Bravo A., Koffi D., Toubal L., Erchiqui F. (2015), Life and damage mode modeling applied to plastic gears, Engineering Failure Analy-sis, 58, 1, 113–133.
- 7. Brethee K, Zhenc D., Gua F., Ball A (2017), Helical gear wear monitoring: Modelling and experimental validation, Mechanism and Machine Theory, 117, 210–229.
- 8. Cherepova T., Dmitrieva G., Tisov O., Dukhota O., Kindrachuk M. (2018), Research on the properties of Co-Tic and Ni-TiC hip-sintered alloys, Acta mechanica et automatica, 13, 1, 57–67.
- 9. Chernets M. (2019a), A method for predicting contact strength and life of archimedes and involute worm gears, considering the effect of wear and teeth correction, Tribology in Industry, 41, 1, 134–141.
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- 31. Kindrachuk M.V., Volchenko O.I., Volchenko D.O., Volchenko N.O., Polyakov P.A., Kornienko A.O., Yurchuk A.O. (2019a), Pol-ymeric Materials Modified by Semiconductor Substances in Friction Units of Braking Devices, Journal on nano- and electronic physics, 11, 3, 03014. 32. Kindrachuk V., Galanov B. (2014), An efficient approach for numer-ical treatment of some inequalities in solid mechanics on examples of Kuhn–Tucker and Signorini–Fichera conditions, Journal of the Me-chanics and Physics of Solids, 63, 432–450.
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- 37. Mao K. (2007), Gear tooth contact analysis and its application in the redaction of fatigue wear, Wear, 262, 11/12, 1281–1288.
- 38. Pashechko M., Krzysztof Dziedzic K., Mendyk E., Jerzy Jozwik J. (2018), Chemical and phase composition of the friction surfaces Fe–Mn–C–B–Si–Ni–Cr hardfacing coatings, Journal of tribology, 140(2), 021302.
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- 41. Raadnui S. (2019) Spur gear wear analysis as applied for tribological based predictive maintenance diagnostics, Wear, 268, 316–324.
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Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-39c3a30b-3a11-4973-9a66-55573655cb53