Criticality of self-heating in degradation processes of polymeric composites subjected to cyclic loading: A multiphysical approach

• Autorzy: Katunin A. , Wronkowicz A. , Bilewicz M. , Wachla D.

Identyfikatory

DOI

10.1016/j.acme.2017.03.003

• Języki publikacji: EN

Abstrakty

EN

In this paper, the criticality of the self-heating effect accompanying the fatigue process of polymeric composites is studied by monitoring various physical parameters, which reflects degradation progress in a direct or indirect way. The occurring self-heating effect, resulted from the mechanical energy dissipation due to the viscoelastic nature of a polymeric matrix of composites, under certain loading conditions, may dominate the fatigue process, causing significant intensification of degradation and thermal failure at temperature often higher than the glass-transition temperature. The aim of this study is to determine the critical values of the self-heating temperature, which exceeding results in damage initiation and, in consequence, intensive degradation and failure. Additionally, performed tests enable evaluation of sensitivity of particular techniques as well as obtaining more accurate results with physical justification. Following the obtained results, the critical value of a self-heating temperature, at which domination of the fatigue process by the self-heating effect is observed, is at a level of 65–70 °C. Information about the obtained critical values has a great importance both during the design stage of composite structures subjected to cyclic loading as well as their further operation.

Słowa kluczowe

EN

fatigue of composite structures; thermal failure; self-heating effect; damage initiation; structural degradation

PL

kompozyty; samozapłon; szkoda

• Wydawca: Springer ; Wrocław University of Science and Technology
• Czasopismo: Archives of Civil and Mechanical Engineering
• Rocznik: 2017
• Tom: Vol. 17, no. 4
• Strony: 806--815
• Opis fizyczny: Bibliogr. 27 poz., rys., tab., wykr.

Twórcy

autor

Katunin A.

• Institute of Fundamentals of Machinery Design, Silesian University of Technology, 18A Konarskiego Street, 44-100 Gliwice, Poland

autor

Wronkowicz A.

• Institute of Fundamentals of Machinery Design, Silesian University of Technology, 18A Konarskiego Street, 44-100 Gliwice, Poland

autor

Bilewicz M.

• Institute of Engineering Materials and Biomaterials, Silesian University of Technology, 18A Konarskiego Street, 44-100 Gliwice, Poland

autor

Wachla D.

• Institute of Fundamentals of Machinery Design, Silesian University of Technology, 18A Konarskiego Street, 44-100 Gliwice, Poland

Bibliografia

• [1] R. Lang, J.A. Manson, Crack tip heating in short-fibre composites under fatigue loading conditions, Journal of Materials Science 22 (1987) 3576–3580.
• [2] D. Rittel, On the conversion of plastic work to heat during high strain rate deformation of glassy polymers, Mechanics of Materials 31 (1999) 131–139.
• [3] A. Kahirdeh, M.M. Khonsari, Energy dissipation in the course of the fatigue degradation: mathematical derivation and experimental quantification, International Journal of Solids and Structures 77 (2015) 74–85.
• [4] R. Talreja, Fatigue of Composite Materials, Technomic Publishing Company, Inc., Lancaster, PA, 1987.
• [5] L. Toubal, M. Karama, B. Lorrain, Damage evolution and infrared thermography in woven composite laminates under fatigue loading, International Journal of Fatigue 28 (12) (2006) 1867–1872.
• [6] J.A.M. Ferreira, J.D.M. Costa, P.N.B. Reis, M.O.W. Richardson, Analysis of fatigue and damage in glass-fibre-reinforced polypropylene composite materials, Composites Science and Technology 59 (10) (1999) 1461–1467.
• [7] M. Naderi, M.M. Khonsari, Thermodynamic analysis of fatigue failure in a composite laminate, Mechanics of Materials 46 (2012) 113–122.
• [8] A. Katunin, M. Fidali, Fatigue and thermal failure of polymeric composites subjected to cyclic loading, Advanced Composites Letters 21 (3) (2012) 64–69.
• [9] A. Kahirdeh, M.M. Khonsari, Criticality of degradation in composite materials subjected to cyclic loading, Composites: Part B 61 (2014) 375–382.
• [10] A. Kahirdeh, M.M. Khonsari, Acoustic entropy of the materials in the course of degradation, Entropy 18 (8) (2016) 280.
• [11] S. Mortazavian, A. Fatemi, Fatigue behavior and modeling of short fiber reinforced polymer composites: a literature review, International Journal of Fatigue 70 (2015) 297–321.
• [12] D. Rittel, N. Eliash, J.L. Halary, Hysteretic heating of modified poly(methylmethacrylate), Polymer 44 (9) (2003) 2817–2822.
• [13] P.G. Pichon, M. Boutaous, F. Méchin, H. Sautereau, Measurement and numerical simulation of the self heating of cross-linked segmented polyurethanes under cyclic loading, European Polymer Journal 48 (2012) 684–695.
• [14] A. Katunin, M. Fidali, Self-heating of polymeric laminated composite plates under the resonant vibrations: theoretical and experimental study, Polymer Composites 33 (1) (2012) 138–146.
• [15] A. Katunin, Thermal fatigue of polymeric composites under repeated loading, Journal of Reinforced Plastics and Composites 31 (15) (2012) 1037–1044.
• [16] V. Bellenger, A. Tcharkhtchi, P. Castaing, Thermal and mechanical fatigue of a PA66/glass fibers composite material, International Journal of Fatigue 28 (10) (2006) 1348–1352.
• [17] M. Naderi, A. Kahirdeh, M.M. Khonsari, Dissipated thermal energy and damage evolution of glass/epoxy using infrared thermography and acoustic emission, Composites: Part B 43 (2012) 1613–1620.
• [18] Z.Y. Liu, S. Beniwal, C.H.M. Jenkins, R.M. Winter, The coupled thermal and mechanical influence on a glassy thermoplastic polyamide: nylon 6,6 under vibro-creep, Mechanics of Time- Dependent Materials 8 (2004) 235–253.
• [19] S. Moisa, G. Landsberg, D. Rittel, J.L. Halary, Hysteretic thermal behavior of amorphous semi-aromatic polyamides, Polymer 46 (25) (2005) 11870–11875.
• [20] M. Karama, Determination of the fatigue limit of a carbon/ epoxy composite using thermographic analysis, Structural Control and Health Monitoring 18 (2011) 781–789.
• [21] A. Katunin, Critical self-heating temperature during fatigue of polymeric composites under cyclic loading, Composites Theory and Practice 12 (1) (2012) 72–76.
• [22] A. Katunin, K. Krukiewicz, R. Turczyn, Evaluation of residual cross-linking caused by self-heating effect in epoxy-based fibrous composites using Raman spectroscopy, Chemik 68 (11) (2014) 957–966.
• [23] F. Magi, D. Di Maio, I. Sever, Damage initiation and structural degradation through resonance vibration: application to composite laminates in fatigue, Composites Science and Technology 132 (2016) 47–56.
• [24] J. de Cazenove, D.A. Rade, A.M.G. de Lima, C.A. Araújo, A numerical and experimental investigation on self-heating effects in viscoelastic dampers, Mechanical Systems and Signal Processing 27 (2012) 433–445.
• [25] T.C. Henry, C.E. Bakis, E.C. Smith, Viscoelastic characterization and self-heating behavior of laminated fiber composite driveshafts, Materials and Design 66 (2015) 346–355.
• [26] S.O. Olajide, B.D. Arhatari, Progress on interacting fatigue, creep & hysteretic heating in polymer adhesively bonded composite joints, International Journal of Fatigue 98 (2017) 68–80.
• [27] A. Katunin, A. Gnatowski, Influence of heating rate on evolution of dynamic properties of polymeric laminates, Plastics, Rubber and Composites 41 (6) (2012) 233–239.

Uwagi

PL

Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017)