PSI - Issue 41

M.Sh. Nikhamkin et al. / Procedia Structural Integrity 41 (2022) 759–765 Author name / Structural Integrity Procedia 00 (2019) 000–000

765

7

Acknowledgements This work was supported by the Russian Science Foundation (grant no. 21-79-30041). References

[1] M. Sh. Nikhamkin, D. G. Solomonov, and N. A. Sazhenkov. Variation of the elastic characteristics of carbon/epoxy fiber laminate as a result of fatigue damage. Mechanics, Resource and Diagnostics of Materials and Structures (MRDMS-2020) AIP Conference Proceedings 2315, 020031 (2020). [2] L.A. Coles, A. Roy, N. Sazhenkov, L. Voronov, M. Nikhamkin, V. Silberschmidt. Ice vs. steel: Ballistic impact of woven carbon/epoxy composites. Part I – Deformation and damage behaviour. Engineering Fracture Mechanics. – 2020. –Vol. 222. - 18 p. [3] Comprehensive Composite Materials Volume 2, 2000, Pages 529-552. [4] Carvelli, V., Pazmino, J., Lomov, S. V., Bogdanovich, A. E., Mungalov, D. D., & Verpoest, I. (2013). Quasi-static and fatigue tensile behavior of a 3D rotary braided carbon/epoxy composite. Journal of Composite Materials, 47(25), 3195–3209. [5] Dynamic Fracture in Carbon-fibre Composites: Effect of Steel and Ice Projectiles / L. A. Coles, A. Roy, L. Voronov, S. Semyonov, M. Nikhamkin, V. V. Silberschmidt // Procedia Structural Integrity. - 2016. - Vol. 2. - P. 366-372. [6] Nikhamkin M.A., Konev I.P., Sazhenkov N.A., Samodurov D.A., Toropitsina A.V., Thermal state of a carbon fiber specimen under fatigue test, Fundamentalniye issledovaniya, 2015, №9-1, p. 44-49 [7] Li, Li & Swolfs, Yentl & Straumit, Ilya & Yan, Xiong & Lomov, Stepan. (2016). Cluster analysis of acoustic emission signals for 2D and 3D woven carbon fiber/epoxy composites. Journal of Composite Materials. 50. 1921-1935. [8] H. Lee, D. Veysset, J.P. Singer, M. Retsch, G. Saini, T. Pezeril, K.A. Nelson, E.L. Thomas, A multiscale modeling methodology for damage progression in polymer-based composites, 12th International Conference on Fracture, ICF-12 6 (2009). [9] Daggumati S., Baere I. De, Paepegem W. Van, Degrieck J., Xu J., Lomov S.V., Verpoest I.. Fatigue and post-fatigue stress-strain analysis of a 5-harness satin weave carbon fibre reinforced composite // Composites Science and Technology. - 2013. - Vol. 74. - P. 20-27. [10] Bensadoun, F., Depuydt, D., Baets, J., Van Vuure, A.W., Verpoest, I. (2013). Influence of fibre architecture on impact and fatigue behaviour of flax fibre-based composites, International Conference on Composite Materials - 7, Montreal, Canada, 29 Jul 2013-03 Aug 2013. [11] Ever J. Barbero, Javier Cabrera Barbero, Determination of material properties for progressive damage analysis of carbon/epoxy laminates, Mechanics of Advanced Materials and Structures, Volume 26, 2019, p.938-947 [12] Nixon-Pearson OJ, Hallett SR, Withers PJ, Rouse J. Damage development in open-hole composite specimens in fatigue. Part 1: Experimental investigation. Compos Struct 2013; Volume 106, pp. 882–889. [13]S. Zabler, C. Fella, A. Dietrich, F. Nachtrab, M. Salamon, V. Voland, T. Ebensperger, S. Oeckl, R. Hanke, N. UhlmannHigh-resolution and high-speed CT in industry and research SPIE Optical Engineering + Applications (2012), p. 850617 [14] Liang S., Gning P.B., Guillaumat L. Properties evolution of flax/epoxy composites under fatigue loading. International Journal of Fatigue, Elsevier, 2014, 63, pp.36-45. [15]Van Paepegem W., De Baere I., Lamkanfi E., Degrieck J. Poisson’s ratio as a sensitive indicator of (fatigue) damage in fibre-reinforced plastics. Fatigue & fracture of engineering materials & structures. V.30(4) (2007). Pp.269-276. [16] Garcea SC, Wang Y, Withers PJ. X-ray computed tomography of polymer composites. Compos Science and Technology 2018; Volume 156, pp.305 –319 . [17] Garcea SC, Sinclair I, Spearing SM. In situ synchrotron tomographic evaluation of the effect of toughening strategies on fatigue micromechanisms in carbon fibre reinforced polymers. Compos Science and Technology 2015; Volume 109, pp.32–39. [18] X- Chu T.C., Ranson W.F., Sutton M.A., Peters W.H. Application of digital-image-correlation techniques to experimental mechanics. Exp. Mech. 1985; 25:232–244. doi:10.1007/BF02325092. [19] ASTM D 3479/D 3479 M Standard Test Method for Tension-Tension Fatigue of Polymer Matrix Composite Materials, ASTM International, PA, 19428-2959 USA, 2012. [20] Apinis R. Acceleration of fatigue tests of polymer composite materials by using high-frequency loadings, Mechanics of Composite Materials. - 2004. - Vol. 40, № 2. - P. 107-118. [21] Impact damage in woven carbon fibre/epoxy laminates: Analysis of damage and dynamic strain fields, L. Coles, A. Roy, L. Voronov, S. Semenov, M. Nikhamkin, N. Sazhenkov, V. V. Silberschmidt , Procedia Engineering. - 2017. - Vol. 199 - P. 2500-2505 [22]Patel A.G., Shah D.S., Patel D.C. A review of progressive damage analysis and fatigue life prediction for degraded e-glass FRP material. International Journal of Technical Innovation in Modern Engineering & Science. V.4 (2018). Issue 12. Pp. 295 -299. [23] Karahana M., Lomov S.V., Bogdanovich A.E., Verpoesta I. Fatigue tensile behavior of carbon/epoxy composite reinforced with non-crimp 3D orthogonal woven fabric. Composites Science and Technology. V.71, Issue 16. Pp. 1961-1972.54.