Composite Materials Research Progress

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102 Michaël Bruyneel Bruyneel M. (2006). A general and effective approach for the optimal design of fiber reinforced composite structures, Composites Science & Technology, 66, 1303-1314. Bruyneel M. and Duysinx P. (2006). Note on singular optima in laminates design problems, Structural & Multidisciplinary Optimization, 31, 156-159. Bruyneel M., Morelle P. and Delsemme J.P. (2006). Failure analysis of metallic and composite structures with SAMCEF, NAFEMS Seminar – Materials Modelling, Niedernhausen near Wiesbaden, Germany, December 5-6. Bruyneel M., Colson B. and Remouchamps A. (2007). Discussion on some convergence problems in buckling optimization, to appear in Structural & Multidisciplinary Optimization Carpentier A., Michel L., Grihon S. and Barreau J.J. (2006). Buckling optimization of composite panels via lay-up tables. III European Conference on Computational mechanics – Solids, Structures and Coupled Problems in engineering, C.A. Mota Soares et al. (editors), Lisbon, Portugal, 5-9 June 2006. Chao L.P., Gandhi M.V. and Thompson B.S. (1993). A design-for-manufacture methodology for incorporating manufacturing uncertainties in the robust design of fibrous laminated composite structures, Journal of Composite Materials, 27 (2), 175-194. Chao L.P. (1996). Multiobjective optimization design methodology for incorporating manufacturing uncertainties in advanced composite structures, Engineering Optimization, 25, 309-323. Cheng K. (1986). Sensitivity analysis and a mixed approach to the optimization of symmetric layered composite plates, Engineering Optimization, 9, 233-247. Cheng G. and Guo X. (1997). ε-relaxed approach in structural topology optimization, Structural Optimization, 13, 258-266. Colson B., Remouchamps A. and Grihgon S. (2007). Advanced computational structures mechanics optimization, 10 th SAMTECH Users Conference, March 13-14, Liège, Belgium. Dems K. (1996). Sensitivity analysis and optimal design for fiber reinforced composite discs, Structural Optimization, 11, 176-186. Diaconu C.G. and Sekine H. (2004). Layup optimization for buckling of laminated composite shells with restricted layer angles, AIAA Journal, Vol. 42, No 10, 2153-2163. Diaz A. and Bendsøe M.P. (1992). Shape optimization of structures for multiple loading situations using a homogenization method, Structural Optimization, 4, 17-22. Duvaut G., Terrel G., Léné F. and Verijenko V.E. (2000). Optimization of fiber reinforced composites, Composite Structures, 48, 83-89. Duysinx P. (1996). Optimization topologique : du milieu continu à la structure élastique, Doctoral Thesis, Faculté des Sciences Appliquées, Université de Liège, Belgium. Duysinx P. (1997). Layout optimization: a mathematical programming approach, DCAMM Report 540, Technical University of Denmark. Duysinx P. and Bendsøe M.P. (1998). Topology optimization of continuum structures with local stress constraints, Int. J. Num. Meth. Engng., 43, 1453-1478. Fine A.S. and Springer G.S. (1997). Design of composite laminates for strength, weight, and manufacturability, Journal of Composite Materials, 31 (23), 2330-2390. Fleury C. (1973). Méthodes numériques d’optimisation des structures, Internal Report SF-19, Laboratoire d’Aéronautique, Université de Liège.
Optimization of Laminated Composite Structures… 103 Fleury C. and Braibant V. (1986). Structural optimization: a new dual method using mixed variables, Int. J. Num. Meth. Engng., 23, 409-428. Fleury C. (1993). Dual methods for convex separable problems, Optimization of Large Structural Systems, Volume I (G.I.N. Rozvany, editor), 509-530, Kluwer Academic Publishers, The Netherlands. Foldager J., Hansen J.S. and Olhoff N. (1998). A general approach forcing convexity of ply angle optimization in composite laminates. Structural Optimization, 16, 201-211. Foldager J.P. (1999). Design of composite structures, Doctoral Thesis, Special Report N° 39, Institute of Mechanical Engineering, Aalborg University, Denmark. Franco Correia V.M., Mota Soares C.M. and Mota Soares C.A. (1997). Design sensitivity analysis and optimal design of composite structures using higher order discrete models, Engineering Optimization, 29, 85-11. Fukunaga H. and Vanderplaats G.N. (1991a). Strength optimization of laminated composites with respect to layer thickness and/or layer orientation angle, Computers & Structures, 40 (6), 1429- 1439. Fukunaga H. and Vanderplaats G.N. (1991b). Stiffness optimization of orthotropic laminated composites using lamination parameters, AIAA Journal, 29 (4), 641- 646. Fukunaga H. and Sekine H. (1993). Optimum design of composite structures for shape, layer angle and layer thickness distributions, Journal of Composite Materials, 27 (15), 1479- 1492. Gay D. (1991).Matériaux composites, Hermès, Paris. Geier B. and Zimmerman R. (1994). Composite laminate stiffnesses and their derivatives, Advances in Design and Automation, Volume II (Gilmore B.J., Hoeltzel D.A., Dutta D. and Eschenauer H.A., editors), ASME 1994, 237-246. Goldberg D. (1989). Genetic algorithms in search, optimization and machine learning, Addison- Wesley Publishing Company Inc., Reading, MA. Grenestedt J.L. (1990). Composite plate optimization only requires one parameter, Structural Optimization, 2, 29-37. Grenestedt J.L. (1991). Lay-up optimization against buckling of shear panels, Structural Optimization, 3, 115-120. Grenestedt J.L. (1992). Lay-up optimization of composite structures, Doctoral Thesis, Rapport 92-94, Dept. of Lightweight Structures, Royal Institute of Technology of Stockholm, Sweden. Grenestdt J.L. and Gudmundson P. (1993). Lay-up optimization of composite material structures, In: Optimal design with Advanced Materials (P. Pedersen, editor), 311-336, Elsevier Science Publ. B.V. Haftka R.T. and Gürdal Z. (1992). Elements of structural optimization, Kluwer Academic Publishers. Hammer V.B. (1997). Design of composite laminates with optimized stiffness, strength, and damage properties, Doctoral Thesis, DCAMM report S72, Technical University of Denmark. Harrison P., Le Riche R. and Haftka R.T. (1995). Design of stiffened composite panels by genetic algorithm and response surface approximations, AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference, 36th and AIAA/ASME Adaptive Structures Forum, New Orleans, LA; UNITED STATES; 10-13 Apr. 1995. 58-68.
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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 65 and 66: In: Composite Materials Research Pr
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
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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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