Composite Materials Research Progress

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48 Jacquemin Frédéric and Fréour Sylvain Ho, N.Q., Pons, F. and Lafarie-Frenot, M.C. (2006). Characterization of an Oxidized Layer in Epoxy Resin and in Carbon Epoxy Composite for Aeronautic Applications, Proceedings of ECCM 12. Jacquemin, F. and Vautrin, A. (2002). A Closed-form Solution for the Internal Stresses in Thick Composite Cylinders Induced by Cyclical Environmental Conditions, Composite Structures, 58: 1–9. Jacquemin, F., Fréour, S., and Guillén, R. (2005). A self-consistent approach for transient hygroscopic stresses and moisture expansion coefficients of fiber-reinforced composites, Journal of Reinforced Plastics and Composites, 24: 485-502. Kaddour, A. S., Hinton, M. J. and Soden, P. D. (2003). Behaviour of ± 45° glass/epoxy filament wound composite tubes under quasi-static equal biaxial tension-compression loading: experimental results, Composites : part B, 34: 689-704. Karakazu, R., Atas, C. and Akbulut, H. (2001). Elastic-plastic Behaviour of Woven-steelfiber-reinforced Thermoplastic Laminated Plates under In-plane Loading, Composites Science and Technology, 61: 1475-1483. Khashaba, U. A., (2004). In-plane shear properties of cross-ply composite laminates with different off-axis angles, Composite Structures, 65: 167-177. Kocks, U. F., Tomé , C. N. and Wenk, H. R. (1998). Texture and Anisotropy, Cambridge University Press. Kröner E. (1953). Dissertation, Technischen Hochschule Stuttgart. Kröner, E. (1958). “Berechnung der elastischen Konstanten des Vielkristalls aus des Konstanten des Einkristalls”, Zeitschrift für Physik, 151: 504–518. Liu, K-S and Tsai, S. W. (1998). A progressive quadratic failure criterion for a laminate, Composite Science and Technology, 58: 1023-1032. Liu, L. et Wagner, H.D. (2005). Rubery and gassy epoxy resins reinforced with carbon nanotubes, Comp. Sci. Tech., 65: 1865-1868. Loos, A. C. and Springer, G. S. (1981). Environmental Effects on Composite Materials, Moisture Absorption of Graphite – Epoxy Composition Immersed in Liquids and in Humid Air, pp. 34–55, Technomic Publishing. Mabelly, P. (1996). Contribution à l’étude des pics de diffraction – Approche expérimentale et modélisation micromécanique, Doctoral Thesis, ENSAM, Aix en Provence. Matthies, S., and Humbert, M. (1993). The realization of the concept of a geometric mean for calculating physical constants of polycrystalline materials, Phys. Stat. Sol. b, 177: K47- K50. Matthies, S., Humbert, M., and Schuman, Ch. (1994). On the use of the geometric mean approximation in residual stress analysis”, Phys. Stat. Sol. b, 186 : K41-K44. Matthies, S. Merkel, S., Wenk, H.R., Hemley, R.J. and Mao, H. (2001). Effects of texture on the determination of elasticity of polycrystalline ε-iron from diffraction measurements, Earth and Planetary Science Letters, 194: 201-212. Mensitieri, G. M., Del Nobile, M. A., Apicella, A. and Nicolais, L. (1995). Moisture-matrix interactions in polymer based composite materials, Revue de l’Institut Français du Pétrole, 50: 551-571. Morawiec, A. (1989). Calculation of polycrystal elastic constants from single-crystal data, Phys. Stat. Sol. b, 154 : 535-541.
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COMPOSITE MATERIALS RESEARCH PROGRE
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Copyright © 2008 by Nova Science P
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vi Contents Chapter 9 Recent Advanc
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viii Lucas P. Durand scale transiti
Page 12 and 13: x Lucas P. Durand machine. In paral
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Page 17 and 18: Multi-scale Analysis of Fiber-Reinf
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Page 67 and 68: Optimization of Laminated Composite
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Page 73 and 74: and γ 2 γ 0 Optimization of Lamin
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Optimization of Laminated Composite
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110 W.H. Zhong, R.G. Maguire, S.S.
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112 Reinforcement: Advanced materia
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130 Yuanxin Zhou, Hassan Mahfuz, Vi
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140 Heat Flow (W/g) Heat Flow (W/g)
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144 Material Yuanxin Zhou, Hassan M
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146 SEM Analysis Yuanxin Zhou, Hass
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150 Governing Equation For the fibe
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152 ⎧ UU = ⎨ ⎩ ⎧ UD = ⎨
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156 Stress (MPa) 120 80 40 0 Yuanxi
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166 Giangiacomo Minak and Andrea Zu
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170 ⎟ ⎞ ⎠ s ⎜ ⎛ ⎝ = a E
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188 A B E (MPa) D 250000 200000 150
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190 D D 1.0 0.9 0.8 0.7 0.6 0.5 0.4
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204 Conclusion Giangiacomo Minak an
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In: Composite Materials Research Pr
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Research Directions in the Fatigue
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Bending force [N] Research Directio
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Damage Variables in Impact Testing
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F peak [kN] 16 14 12 10 8 6 4 2 0 D
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Eletromechanical Field Concentratio
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MV/m. Eletromechanical Field Concen
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276 S.C. Tjong developed in the pas
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278 S.C. Tjong ultrasonic waves gen
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280 S.C. Tjong applications. Goujon
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282 S.C. Tjong nanoparticles were p
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284 S.C. Tjong where DL is lattice
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286 S.C. Tjong stress is temperatur
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288 S.C. Tjong threshold stress res
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290 S.C. Tjong NC Al, and the NC Al
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292 S.C. Tjong (a) (b) Figure 19. T
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294 S.C. Tjong Apart from forming u
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296 S.C. Tjong [29] Saravanan, M.;
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298 braids, 115 broadband, 211 bubb
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300 endothermic, 139 endurance, 32
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302 isostatic pressing, 279, 288 It
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304 piezoelectricity, 261 pitch, 12
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306 67, 69, 70, 71, 72, 73, 84, 94,
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