[1] GHIASI H,FAYAZBAKHSH K,PASINI D,et al. Optimum stacking sequence design of composite materials Part II:Variable stiffness design[J]. Composite Structures,2010, 93(1):1-13. [2] STEGMANN J, LUND E. Discrete material optimization of general composite shell structures[J]. Int. J. Numer. Methods Eng.,2005,62(14):2009-2027. [3] SØRENSEN S N,SØRENSEN R,LUND E. DMTO-a method for discrete material and thickness optimization of laminated composite structures[J]. Struct. Multidisc Optim.,2014,50(1):25-47. [4] LUND E. Discrete material and thickness optimization of laminated composite structures including failure criteria[J]. Structural & Multidisciplinary Optimization, 2018, 57(6):2357-2375. [5] KIYONO C Y,SILVA E C N,REDDY J N. A novel fiber optimization method based on normal distribution function with continuously varying fiber path[J]. Composite Structures,2017,160:503-515. [6] ZHOU M,FLEURY R,KEMP M. Optimization of composite-recent advances and application[C]//Aiaa/issmo Multidisciplinary Analysis Optimization Conference. 2010. Optimization of Composite-Recent Advances and Application,2010. [7] IRISARRI F X,LASSEIGNE A,LEROY F H,et al. Optimal design of laminated composite structures with ply drops using stacking sequence tables[J]. Compos. Structures,2014,107:559-569. [8] JING Z,SUN Q,SILBERSCHMIDT V V. A framework for design and optimization of tapered composite structures. Part I:From individual panel to global blending structure[J]. Composite Structures,2016,154:106-128. [9] JING Z, SUN Q,CHEN J Q,et al. A framework for design and optimization of tapered composite structures. Part II:Enhanced design framework with a global blending model[J]. Composite Structures,2018,188:531-552. [10] ALBAZZAN M A,HARIK R,TATTING B F,et al. Efficient design optimization of nonconventional laminated composites using lamination parameters:A state of the art[J]. Composite Structures,2019,209:362-374. [11] YAN J,DUAN Z,LUND E,et al. Concurrent multi-scale design optimization of composite frames with manufacturing constraints[J]. Structural and Multidisciplinary Optimization,2017,56(3):519-533. [12] WU C,GAO Y K,FANG J G,et al. Discrete topology optimization of ply orientation for a carbon fiber reinforced plastic (CFRP) laminate vehicle door[J]. Material and Design,2017,128:9-19. [13] AHAMED J,JOOSTEN M,CALLUS P,et al. Ply-overlap hybrid technique for joining dissimilar composite materials[J]. Materials and Design,2016,100:157-167. [14] CZÉL G,PIMENTA S,WISNOM M R,et al. Demonstration of pseudo-ductility in unidirectional discontinuous carbon fibre/epoxy prepreg composites[J]. Composites Science and Technology,2015,106:110-119. [15] SØRENSEN R,LUND E. Topology and thickness optimization of laminated composites including manufacturing constraints[J]. Struct. Multidiciplinary Optim.,2013,48(2):249-265. [16] BOGOMOLNY M,AMIR O. Conceptual design of reinforced concrete structures using topology optimization with elastoplastic material modelling[J]. Int. J. Number, Methods Eng., 2012,90(13):1578-1597. [17] Abaqus 6.13 online documentation,Dassault Systèmes,[EB/OL].2013.http://130.149.89.49:2080/v6.13/books/gsa/default.htm. [18] BAUCOM J N,THOMAS J P,POGUE III W R,et al. Tiled composite laminates[J]. Journal of Composite Materials,2010,44(26):3115-3132. [19] MALKIN R,YASAEE M,TRSAK R S,et al. Bio-inspired laminate design exhibiting pseudo-ductile (graceful) failure during flexural loading[J]. Composites:Part A,2013,54:107-116. [20] ROZYLO P,DEBSKI H,KUBIAK T. A model of low-velocity impact damage of composite plates subjected to compression-after-impact (CAI) testing[J]. Composite Structures,2017,181:158-170. |