Fatigue behaviour of composite tubes under multiaxial loading

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42 Acknowledgement Fifth International Conference on Fatigue of Composites This study was supported in part by the Ministry of Education, Culture, Sports, Science and Technology of Japan under a Grant-in-Aid for Scientific Research (No. 20360050). References [1] Hertzberg, R.W., Deformation and Fracture Mechanics of Engineering Materials, (1989), p. 467, Wiley. [2] Sendeckyj, G.P., Life prediction for resin-matrix composite materials, (Reifsnider, K.L., editor), Fatigue of Composite Materials, (1990), pp. 431-483, Elsevier Science Publishers. [3] Harris, B., Ed., Fatigue in Composites, (2003), Woodhead Publishing Limited, Cambridge UK. [4] Ellyin, F. and EL-Kadi, H., A fatigue failure criterion for fiber reinforced composite laminae, Composite Structures, 15, (1990), 61-74. [5] Kawai, M., Damage mechanics model for off-axis fatigue behavior of unidirectional carbon fiber-reinforced composites at room and high temperatures, in Massard, T. and Vautrin, A., Proc. of 12th Int. Conf. on Composite Materials (ICCM12), Paris, France, July 5-9, (1999), p. 322. [6] Kawai, M., Yajima, S., Hachinohe, A. and Takano, Y., Off-axis fatigue behavior of unidirectional carbon fiber-reinforced composites at room and high temperatures, Journal of Composite Materials, 35(7), (2001), 545-576. [7] Kawai, M., Yajima, S., Hachinohe, A. and Kawase, Y., High-temperature off-axis fatigue behaviour of unidirectional carbon fiber-reinforced composites with different resin matrices, Composites Science and Technology, 61, (2001), 1285-1302. [8] Kawai, M. and Suda, H., Effects of non-negative mean stress on the off-axis fatigue behavior of unidirectional carbon/epoxy composites at room temperature, Journal of Composite Materials, 38 (10), (2004), 833-854. [9] Kawai, M., A phenomenological model for off-axis fatigue behavior of unidirectional polymer matrix composites under different stress ratios, Composites, Part A, Vol. 35, No. 7-8, (2004), 955-963. [10] Azzi, V.D. and Tsai, S.W., Anisotropic strength of composites, Experimental Mechanics, 5, (1965), 283-288. [11] Caprino, G. and D‟Amore, A. Flexural fatigue behaviour of random continuous-fibre-reinforced thermoplastic composites, Composites Science and Technology, Vol. 58, (1998), pp. 957-965. [12] Caprino, G. and Giorleo, G., Fatigue lifetime of glass fabric/epoxy composites, Composites Part A, Vol. 30, (1999), pp. 299-304. [13] D‟Amore, A., Caprino, G., Stupak, P., Zhou, J. and Nicolais, L., Effect of stress ratio on the flexural fatigue behaviour of continuous strand mat reinforced plastics, Science and Engineering of Composite Materials, Vol. 5, No. 1, (1996), pp. 1-8. [14] Goodman, J. Mechanics Applied to Engineering, 1899, Longman Green, Harlow, UK. [15] Smith, R.N., Watson, P., Topper, T.H., A stress strain function for the fatigue of metals, Journal of Materials, JMLSA, 1970, 5(4); 767-778. [16] Walker, K., The effect of stress ratio during crack propagation for 2024-T3 and 7075-T6 aluminum, In: Effects of environment and complex load history on fatigue life. ASTM STP 462, 1970, pp.1-14. [17] Harris, B., Reiter, H., Adam, T., Dickson, R.F., Fernando, G., Fatigue behaviour of carbon fibre reinforced plastics, Composites, Vol. 21, No. 3, (1990), pp. 232-242. [18] Adam, T., Gathercole, N., Reiter, H., Harris, B., Fatigue life prediction for carbon fibre composites, Advanced Composites Letter, Vol. 1, (1992), pp. 23-26. [19] Gathercole, N., Reiter, H., Adam, T., Harris, B., Life prediction for fatigue of T800/5245 carbon-fibre composites: I. constant-amplitude loading, Fatigue, Vol. 16, (1994), pp. 523-532. [20] Harris, B., Gathercole, N., Lee, J.A., Reiter, H., Adam, T., Life-prediction for constant-stress fatigue in carbon-fibre composites, Phil. Trans. R. Soc. London, Vol. A355, (1997), pp. 1259-1294. [21] Beheshty, M.H., Harris, B., Adam, T., An empirical fatigue-life model for high-performance fibre composites with and without impact damage, Composites Part A, Vol. 30, (1999), pp. 971-987. [22] Ramani, S.V. and Williams, D.P., Notched and unnotched fatigue behavior of angle-ply graphite/epoxy composites, (Reifsnider, K.L. and Lauraitis, K.N., editors), Fatigue of Filamentary Composite Materials, ASTM STP 636, (1977), pp. 27-46. [23] Boller, K.H., Fatigue properties of fibrous glass-reinforced plastics laminates subjected to various conditions. Modern Plastics, Vol. 34, (1957), pp.163-186, 293. [24] Boller, K.H., Fatigue characteristics of RP laminates subjected to axial loading. Modern Plastics, Vol. 41, (1964), pp.145-150, 188. [25] Kawai, M., A method for identifying asymmetric dissimilar constant fatigue life diagrams of CFRP laminates, Proceedings of the Fifth Asian-Australasian Conference on Composite Materials (ACCM-5), Hong Kong, November 27-30, 2006. [26] Kawai, M. and Koizumi, K., Nonlinear constant fatigue life diagrams for carbon/epoxy laminates at room temperature, Composites Part A, Vol. 38, (2007), pp. 2342-53.
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Page 1 and 2: Fiifth IInternatiionall Conference
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Page 5 and 6: Fatigue behaviour of composite tube
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Effect of Water Uptake on the Fatig
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Delamination during fatigue testing
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Strength (N) Sample 1 Sample 2 Samp
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3.2.2 Creep/ recovery test J Basser
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Stress (MPa) 30 25 20 15 10 5 0 J B
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4.2.3 Stiffness degradation J Basse
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Abstract A residual stiffness - res
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An Energy-Based Fatigue Approach fo
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An Energy-based Fatigue Approach fo
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Experimental characterization and a
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Abstract Calorimetric Analysis of d
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Fatigue-driven Residual Life Models
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Experimental analysis and modelling
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4. FEM analysis 4.1 Configuration P
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References P Nimdum, J Renard. / Ex
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F Schmidt, T J Adam, P Horst. / Fat
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Abstract Fatigue Damage initiation
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B Esmaeillou, P Fereirra, V Belleng
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F Q Wu, W X Yao. / Fatigue life pre
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Composite Glass/Epoxy [1] Graphite/
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C S Shin, S W Yang. / Post-Impact F
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Delamination detection in CFRP lami
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5. Conclusion N Hu, Y L Liu, H Fuku
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S J Zhu, M Kichise, A Usuki, M Kato
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Fatigue Behavior of Unidirectional
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2.3 Fatigue Testing H Katogi, Y Shi
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H Katogi, Y Shimamura, K Tohgo, T F
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M-H R Jen, Y-C Sung, etc. / Fabrica
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Fatigue and Fracture of Elastomeric
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fatigue conditions. C Bathias, S Y
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Correlation between crack propagati
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Thermal fatigue of AX41 magnesium a
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4. Discussion Z Drozd, etc. / Therm
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Abstract Fatigue behaviour of woven
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Damage in thermoplastic composite s
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Abstract Residual life predictions
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