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Transition Time of Ultrasonic Wave as a Tool of Quality Evaluation of Layered Polymer Composites

Autorzy
Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Observation of behaviour phenomena of ultrasonic waves in an object allows for quality assessment, identification and location of discontinuity. Physical nature of acoustic processes is based on propagation of mechanical waves constituting a disturbance of equilibrium of the state of material. The acoustic proces identified by selected characteristics can be a source of information about state of material, its structure, and properties, which is particularly important for systems exhibiting anisotropy properties, and such are layered polymer composites. They are special materials because their properties depend greatly on the manufacturing technology. Therefore, while conducting acoustic tests which use the influence of elastic properties and homogeneity of material structure for propagation of sound waves the adopted method of measuring characteristics which identifies propagation of ultrasonic wave phenomenon is of particular importance. The aim of the work was quality evaluation of layered polymer composites made by Winding and press moulding by the method of echo and C-scan, using head Phased Array. Composites have been tested by thermal and fatigue degradation. Quality evaluation has been made based on the transition time of the ultrasonic wave and the bending strength.
Rocznik
Strony
499--506
Opis fizyczny
Bibliogr. 17 poz., fot., rys., wykr.
Twórcy
autor
  • Institute of Theoretical and Applied Mechanics, Faculty of Mechanical Engineering, Silesian University of Technology, Konarskiego 18A, 44-100 Gliwice, Poland
Bibliografia
  • 1. Advani S., Hsiao K. T. (2012), Manufacturing techniques for polymer matrix composites (PMCs), Woodhead Publishing, Cambridge.
  • 2. Błażejewski W., Hufenbach W., Czulak A., Boehm R. (2005), Preparation and testing of composite tubular samples of glass fiber reinforced [in Polish: Wytwarzanie i badanie kompozytowych próbek rurowych wzmocnionych włóknem szklanym], Kompozyty, 5, 4, 67-71.
  • 3. Fahr A. (2014), Aeronautical applications of nondestructive testing, DStech Publication, Lancaster.
  • 4. Ferreira J. M., Pires J. T. B., Costa J. D., Errajhi O. A., Richardson M. (2007), Fatigue damage and environment interaction of polyester aluminized glass fiber composites, Composite Structure, 78, 3, 397-401.
  • 5. Fuchs E. R. H., Field F. R., Roth R., Kirchain R. E. (2008), Strategic materials selection in the automobil body: economic opportunities for polymer composite design, Composites Science and Technology, 68, 1989-2002.
  • 6. Hufenbach W., Gude M., Czulak A., Gasior P., Kretschmann M. (2011), Manufacturing and pressure tests of braided vessels with integrated optical fiber sensors, Plastics Processing, 6, 454-459.
  • 7. Hull D., Clyne T. W. (1996), An introduction to composite materials, Cambridge University Press, Cambrige.
  • 8. Kočiš S., Figura Z. (1996), Ultrasonic Measurements and Technologies, Chapman & Hall, London.
  • 9. Mackiewicz S., Góra G. (2005), Ultrasonic testing of composite structures in the aerospace industry [in Polish: Ultradźwiękowe badania konstrukcji kompozytowych w przemyśle lotniczym], Procceding of 11th Seminar “Non Destructive Test Methods”, Zakopane.
  • 10. Mackiewicz S., Góra G. (2012), Ultrasonic testing of carbon laminate Phased Array technique [in Polish: Ultradźwiękowe badania laminatów węglowych techniką Phased Array], Procceding of 13th Seminar “Non Destructive Test Methods”, Zakopane.
  • 11. Mallick P. K. (1997), Nondestructive tests. Composites Engineering Handbook, New York.
  • 12. Mittal K. L. (2009), Silanes and Other Coupling Agents, VSP, Boston.
  • 13. Rojek M., Stabik J., Sokół S. (2007), Fatigue and ultrasonic testing of epoxy-glass composites, Journal Achievements in Materials and Manufacturing Engineering, 20, 1-2, 183-186.
  • 14. Rot K., Huskić M., Makarovič M., Mlakar T., Žigon M. (2001), Interfacial effects in glass fibre composites as a function of unsaturated polyester resin composition, Composites Part A: Applied Science and Manufacturing, 32, 3, 511-516.
  • 15. Śliwiński A. (2001), Ultrasounds and their applications [in Polish: Ultradźwięki i ich zastosowania] (2nd ed.), WNT, Warszawa.
  • 16. Szymiczek M., Rojek M., Wróbel G. (2016), The influence of the ageing-fatigue degradation on the mechanical properties of glass-reinforced composites, Polish Journal of Chemical Technology, 18, 1, 113-119.
  • 17. Wróbel G., Pawlak S. (2006), Ultrasonic evaluation of the fibre content in glass/epoxy composites, Journal of Achievements in Materials and Manufacturing Engineering, 18, 1-2, 187-190.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-6518eb5f-252f-4ec2-97a0-32a882ca1ac1
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