Composite Materials Research Progress

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104 Michaël Bruyneel Henderson J.L., Gürdal Z. and Loos A.C. (1999). Combined structural and manufacturing optimization of stiffened composite panels, Journal of Aircraft, 36 (1), 246-254. Herencia J.E., Weaver P.M. and Friswell M.I. (2006). Local optimization of long anisotropic laminated fibre composite panels with T shape stiffeners, 47 th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference, 1 – 4 May 2006, Newport, Rhode Island. Hirano Y. (1979a). Optimum design of laminated plates under shear, Journal of Composite Materials, 13, 329-335. Hirano Y. (1979b). Optimum design of laminated plates under axial compression, AIAA Journal, 17 (9), 1017-1019. Hyer M.W. and Charette R.F. (1991). Use of curvilinear fiber format in composite structure design, AIAA Journal, 29, 1011-1015. Hyer M.W. and Lee H.H. (1991). The use of curvilinear fiber format to improve buckling resistance of composite plates with central circular holes, Composite Structures, 18, 239-261. Kam T.Y. and Lai M.D. (1989). Multilevel optimal design of laminated composite plate structures, Computers & Structures, 31 (2), 197-202. Karandikar H. and Mistree F. (1992). Designing a composite material pressure vessel for manufacture: a case study in concurrent engineering, Engineering Optimization, 18, 235-262. Kicher T.P. and Chao T.L. (1971). Minimum weight design of stiffened fiber composite cylinders, Journal of Aircraft, 8, 562-569. Kogiso N., Watson L.T., Gürdal Z. and Haftka R.T. (1994). Genetic algorithms with local improvement for composite laminate design, Structural Optimization, 7, 207-218. Kristinsdottir B.P., Zabinsky Z.B., Tuttle M.E. and Csendes T. (1996). Incorporating manufacturing tolerances in near-optimal design of composite structures, Engineering Optimization, 23, 1-23. Krog L.A. (1996). Layout optimization of disk, plate, and shell structures, Doctoral Thesis, Special Report N° 27, Institute of Mechanical Engineering, Aalborg University, Denmark. Krog L., Bruyneel M., Remouchamps A. and Fleury C. (2007). COMBOX: a distributed computing process for optimum sizing of composite aircraft box structures. 10 th SAMTECH Users Conference, March 13-14, Liège, Belgium. Lanzi L. and Giavotta V. (2006). Post-buckling optimization of composite stiffened panels: computations and experiments, Composite Structures, 73, 206-220. Le Riche R. and Haftka R.T. (1993). Optimization of laminated stacking sequence for buckling load maximization by genetic algorithms, AIAA Journal, 31 (5), 951-956. Lipton R.P. (1994). On optimal reinforcement of plates and choice of design parameters, Control & Cybernetics, 23 (3), 481-493. Liu B., Haftka R.T. and Akgun M. (2000). Two-level composite wing structural optimization using response surfaces, Structural & Multidisciplinary Optimization, 20, 87-96. Liu B., Haftka R. and Trompette P. (2004). Single level composite wing optimization based on flexural lamination parameters, Structural & Multidisciplinary Optimization, 26, 111-120. Mahadevan S. and Liu X. (1998). Probabilistic optimum design of composite laminates, Journal of Composite Materials, 32 (1), 68-82.
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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
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x Lucas P. Durand machine. In paral
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In: Composite Materials Research Pr
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Multi-scale Analysis of Fiber-Reinf
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T300 fibers (Soden et al., 1998; Ag
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1 I L = L : r v Multi-scale Analysi
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I E ⎡0 ⎢ ⎢0 ⎢ ⎢ ⎢ ⎢0
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Applied macroscopic load Correspond
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Page 67 and 68: Optimization of Laminated Composite
Page 71 and 72: ⎧σ x ⎫ ⎡ mE ⎪ ⎪ ⎢ x
Page 73 and 74: and γ 2 γ 0 Optimization of Lamin
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Page 107 and 108: 3.5 3 2.5 2 1.5 1 Optimization of L
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Page 124 and 125: 110 W.H. Zhong, R.G. Maguire, S.S.
Page 126 and 127: 112 Reinforcement: Advanced materia
Page 144 and 145: 130 Yuanxin Zhou, Hassan Mahfuz, Vi
Page 154 and 155: 140 Heat Flow (W/g) Heat Flow (W/g)
Page 158 and 159: 144 Material Yuanxin Zhou, Hassan M
Page 160 and 161: 146 SEM Analysis Yuanxin Zhou, Hass
Page 164 and 165: 150 Governing Equation For the fibe
Page 166 and 167: 152 ⎧ UU = ⎨ ⎩ ⎧ UD = ⎨
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154 Yuanxin Zhou, Hassan Mahfuz, Vi
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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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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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