Sensitivity of an acoustic emission to wearing of surfaces of a composite material

Authors

  • Сергей Федорович Филоненко National Aviation University Komarova 1, Kyiv, Ukraine, 03680, Ukraine
  • Татьяна Васильевна Нимченко National Aviation University Komarova 1, Kyiv, Ukraine, 03680, Ukraine

DOI:

https://doi.org/10.15587/1729-4061.2014.23971

Keywords:

acoustic emission, parameters, signal, composite, wear, friction, analysis, increase, surface

Abstract

The results of studying friction and wear of the surfaces of the composite material are considered. The analysis of the parameters of recorded resulting acoustic emission signal at the normal and extremely gross wear stages, as well as friction temperature and coefficient, is carried out. Temporal parameters of transition of the friction unit to the extremely gross wear stage are defined by the analyzed parameters. The analysis of change dependencies of percent increase in the analyzed parameters and their sensitivity to friction and wear of the frictional contactsurfaces of the composite material is performed. It is determined that, at the stage of normal wear, percent increase in the friction coefficient does not occur, and the percent increase in temperature grows linearly. It is found that the acoustic emission is more sensitive to friction and wear of the surfaces of the composite material relative to the temperature in the friction zone and friction coefficient. It is shown that acoustic emission allows to fix the stage that precedes the extremely gross wear stage, which is an important task in the diagnostics of friction units.

Author Biographies

Сергей Федорович Филоненко, National Aviation University Komarova 1, Kyiv, Ukraine, 03680

Professor, director

Institute of Information-Diagnostic Systems

Татьяна Васильевна Нимченко, National Aviation University Komarova 1, Kyiv, Ukraine, 03680

Candidate of Engineering, Associate Professor

Department of Information Security Tools, Institute of Information-Diagnostic Systems

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  26. Xu, J., Liu, L., Jiang, L., Munroe, P., Xie, Z. H. (2013). Unraveling the mechanical and tribological properties of a novel Ti5Si3/TiC nanocomposite coating synthesized by a double glow discharge plasma technique. Ceramics International, 39 (8), 9471–9481.
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  31. Kalogiannakis, G., Quintelier, J., De Baets, P., Degrieck, J., Van, D. (2008). Hemelrijck Identification of wear mechanisms of glass/polyester composites by means of acoustic emission. Wear, 264 (3–4), 235–244.
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Published

2014-06-26

How to Cite

Филоненко, С. Ф., & Нимченко, Т. В. (2014). Sensitivity of an acoustic emission to wearing of surfaces of a composite material. Eastern-European Journal of Enterprise Technologies, 3(9(69), 35–41. https://doi.org/10.15587/1729-4061.2014.23971

Issue

Section

Information and controlling system