13th International Conference on Fracture June 16–21, 2013, Beijing, China -10- [21]M. Hojo, C. Gustafson, K. Tanaka and R. Hayashi, in Advanced Materials for Severe Service Applications (Tokyo, Japan, 1987) p. 353. [22]N. Blanco, E. K. Gamstedt, L. E. Asp and J. Costa, Mixed-mode delamination growth in carbon-fibre composite laminates under cyclic loading. Int J Solids Struct, 41 (2004) 4219. [23]L. E. Asp, A. Sjogren and E. S. Greenhalgh, Delamination growth and thresholds in a carbon/epoxy composite under fatigue loading. Journal of Composites Technology and Research, 23 (2001) 55. [24]S. Singh and E. Greenhalgh, Mixed-mode delamination growth in carbon-fiber composites under fatigue loading, (Report DRA/SMC/CR961052/1.0 Defence Research Agency, 1996). [25]A. Argüelles, J. Viña, A. Fernandez-Canteli, I. Viña and J. Bonhomme, Influence of the matrix constituent on mode I and mode II delamination toughness in fiber-reinforced polymer composites under cyclic fatigue. Mech Mater, 43 (2011) 62. [26]M. Kenane, Z. Azari, S. Benmedakhene and M. L. Benzeggagh, Experimental development of fatigue delamination threshold criterion. Composites Part B: Engineering, 42 (2011) 367. [27]P. W. Harper and S. R. Hallett, A fatigue degradation law for cohesive interface elements - Development and application to composite materials. Int J Fatigue, 32 (2010) 1774. [28]S. Maiti and P. H. Geubelle, Cohesive modeling of fatigue crack retardation in polymers: Crack closure effect. Eng Fract Mech, 73 (2006) 22. [29]P. Naghipour, M. Bartsch and H. Voggenreiter, Simulation and experimental validation of mixed mode delamination in multidirectional CF/PEEK laminates under fatigue loading. Int J Solids Struct, 48 (2011) 1070. [30]A. Turon, J. Costa, P. P. Camanho and C. G. Davila, Simulation of delamination in composites under high-cycle fatigue. Compos Part A-Appl S, 38 (2007) 2270. [31]A. Argüelles, J. Viña, A. F. Canteli, M. A. Castrillo and J. Bonhomme, Interlaminar crack initiation and growth rate in a carbon-fibre epoxy composite under mode-I fatigue loading. Compos Sci Technol, 68 (2008) 2325. [32]K. N. Shivakumar, H. Chen, F. Abali, D. Le and C. Davis, A total fatigue life model for mode I delaminated composite laminates. International Journal of Fatigue, 28 (2006) 33. [33]J. R. Gregory and S. M. Spearing, A fiber bridging model for fatigue delamination in composite materials. Acta Mater, 52 (2004) 5493. [34]L. Peng, J. Zhang, R. Bao, H. Yang and B. Fei, Effect of ply orientation on the delamination growth in a laminated composite under cyclic loading: mode I, in "ICCS15" (Porto, Portugal, 2009). [35]J. Zhang, L. Peng, L. Zhao and B. Fei, Fatigue Delamination Growth Rates and Thresholds of Composite Laminates under Mixed Mode Loading. Int J Fatigue, (2012). [36]D. J. Wilkins, J. R. Eisenmann, R. A. Camin, W. S. Margolis and R. A. Benson, in Damage in Composite Materials, ASTM STP 775, edited by K. L. Reifsnider (American Society for Testing and Materials, 1982) p. 168. [37]S. Hashemi, A. J. Kinloch and J. G. Williams, Mechanics and mechanisms of delamination in a poly(ether sulphone)--Fibre composite. Compos Sci Technol, 37 (1990) 429. [38]S. Hashemi, A. J. Kinloch and J. G. Williams, Corrections needed in double-cantilever beam tests for assessing the interlaminar failure of fibre-composites. J Mater Sci Lett, 8 (1989) 125.
RkJQdWJsaXNoZXIy MjM0NDE=