[1] CZECH K,OLIWA R,KRAJEWSKI D,et al. Hybrid polymer composites used in the arms industry:A review[J]. Materials,2021,14(11):3047. [2] SARFRAZ M S,HONG H,KIM S S. Recent developments in the manufacturing technologies of composite components and their cost-effectiveness in the automotive industry:A review study[J]. Composite Structures,2021,226(16):113864. [3] HARUSSANI M,SAPUAN S,NADEEM G,et al. Recent applications of carbon-based composites in defence industry:A review[J/OL]. Defence Technology,2022. https://doi.org/10.1016/j.dt.2022.03.006. [4] LI Y,XIAO Y,YU L,et al. A review on the tooling technologies for composites manufacturing of aerospace structures:Materials,structures and processes[J]. Composites Part A:Applied Science and Manufacturing,2022,154:106762. [5] LIGON S C,LISKA R,STAMPFL J,et al. Polymers for 3D printing and customized additive manufacturing[J]. Chemical Reviews,2017,117(15):10212-10290. [6] HMEIDAT N S,ELKINS D S,PETER H R,et al. Processing and mechanical characterization of short carbon fiber-reinforced epoxy composites for material extrusion additive manufacturing[J]. Composites Part B:Engineering,2021,223:109122. [7] SPOERK M,SAVANDAIAH C,ARBEITER F,et al. Anisotropic properties of oriented short carbon fibre filled polypropylene parts fabricated by extrusion-based additive manufacturing[J]. Composites Part A:Applied Science and Manufacturing,2018,113:95-104. [8] 侯章浩,田小永,朱伟军,等. 连续纤维增强复合材料变刚度结构3D打印与性能研究[J]. 机械工程学报,2022,58(5):170-177. HOU Zhanghao,TIAN Xiaoyong,ZHU Weijun,et al. 3D printing and performance of continuous fiber reinforced variable stiffness composite structures[J]. Journal of Mechanical Engineering,2022,58(5):170-177. [9] SANO Y,MATSUZAKI R,UEDA M,et al. 3D printing of discontinuous and continuous fibre composites using stereolithography[J]. Additive Manufacturing,2018,24:521-527. [10] WANG Quandai,WANG Junru,ZHANG Yin,et al. Multi-physics simulation and experimental study of the reaction kinetics process of oxygen inhibition zone formation in constrained-surface stereolithography process[J]. Additive Manufacturing,2021,47:102280. [11] WERKEN N V D,TEKINALP H,KHANBOLOUKI P,et al. Additively manufactured carbon fiber-reinforced composites:State of the art and perspective[J]. Additive Manufacturing,2020,31:100962. [12] WANG Y,ZHOU Y,LIN L,et al. Overview of 3D additive manufacturing (AM) and corresponding AM composites[J]. Composites Part A:Applied Science and Manufacturing,2020,139:106114. [13] WEIGAND J J,MILLER C I,JANISSE A P,et al. 3D printing of dual-cure benzoxazine networks[J]. Polymer,2020,189:122193. [14] INVERNIZZI M,NATALE G,LEVI M,et al. UV-Assisted 3D printing of glass and carbon fiber-reinforced dual-cure polymer composites[J]. Materials,2016,9(7):583-595. [15] 邓宇豪,张爱民,包建军,等. 双固化3D打印弹性体光敏树脂的制备与性能[J]. 高分子材料科学与工程,2020,36(7):112-117. DENG Yuhao,ZHANG Aiming,BAO Jianjun,et al. Preparation and properties of photosensitive inks for double curing 3D printing elastomers[J]. Polymer Materials Science and Engineering,2020,36(7):112-117. [16] KONURAY O,ALTET A,BONADA J,et al. Epoxy doped,nano-scale phase-separated poly-acrylates with potential in 3D printing[J]. Macromolecular Materials and Engineering,2021,306(3):2000558. [17] ROMEIS M,DRUMMER D. A dyciandiamine-based methacrylate-epoxy dual-cure blend-system for stereolithography[J]. Multidisciplinary Digital Publishing Institute,2021,13:3139. [18] GRIFFINI G,INVERNIZZI M,LEVI M,et al. 3D-printable CFR polymer composites with dual-cure sequential IPNs[J]. Polymer,2016,91:174-179. [19] YUAN Z,WANG Y,PENG J,et al. An analytical model on through-thickness stresses and warpage of composite laminates due to tool-part interaction[J]. Composites Part B:Engineering,2016,91:408-413. [20] HOSSEINI-TOUDESHKY H,MOHAMMADI B. Thermal residual stresses effects on fatigue crack growth of repaired panels bounded with various composite materials[J]. Composite Structures,2009,89(2):216-223. [21] SANDBERG M,YUKSEL O,BARAN I,et al. Numerical and experimental analysis of resin-flow,heat-transfer,and cure in a resin-injection pultrusion process[J]. Composites Part A:Applied Science and Manufacturing,2020,143:106231. [22] WESTBEEK S,REMMERS J,DOMMELEN J,et al. Multi-scale process simulation for additive manufacturing through particle filled vat photopolymerization[J]. Computational Materials Science,2020,180:109647. [23] CHEN W,ZHANG D. A micromechanics-based processing model for predicting residual stress in fiber-reinforced polymer matrix composites[J]. Composite Structures,2018,204:153-166. [24] CLASSENS K,HAFKAMP T,WESTBEEK S,et al. Multiphysical modeling and optimal control of material properties for photopolymerization processes[J]. Additive Manufacturing,2020,38:101520. [25] CHENG J,XU Y,ZHANG W,et al. A review on the multi-scale simulation of Z-pinned composite laminates[J]. Composite Structures,2022,295:115834. [26] KONURAY O,SALLA J M,MORANCHO J M,et al. Curing kinetics of acrylate-based and 3D printable IPNs[J]. Thermochimica Acta,2020,692:178754. [27] ZADE A,PAKALA S,KUPPUSAMY R R P. Finite element modelling of non-isothermal curing kinetics for resin transfer moulding process[J]. Materials Today:Proceedings,2021,47:5281-5288. [28] YAN X. Finite element simulation of cure of thick composite:Formulations and validation verification[J]. Journal of Reinforced Plastics and Composites OnlineFirst,2008,27(4):339-355. [29] 李金磊. 热固性复合材料制件残余应力形成及影响研究[D]. 大连:大连理工大学,2020. LI Jinlei. Research on the formation and influence of resedual stress in thermosetting composite parts[D]. Dalian:Dalian University of Technology,2020. [30] PATHAM B,HUANG X. Multiscale modeling of residual stress development in continuous fiber-reinforced unidirectional thick thermoset composites[J]. Journal of Composites,2014,5:1-17. [31] BRAUNER C,BLOCK T B,PUROL H,et al. Microlevel manufacturing process simulation of carbon fiber/epoxy composites to analyze the effect of chemical and thermal induced residual stresses[J]. Journal of Composite Materials,2012,46(17):2123-2143. [32] YUAN Z,WANG Y,YANG G,et al. Evolution of curing residual stresses in composite using multi-scale method[J]. Composites Part B:Engineering,2018,155:49-61. [33] 王权岱,杨新宇,惠振文,等. 约束面投影成型基底表面微织构特征对固化层分离力的影响[J]. 机械工程学报,2021,57(17):196-206. WANG Quandai,YANG Xinyu,HUI Zhenwen,et al. Influence of micro-texture characteristics of substrate on separation force in constrained-surface projection based stereolithography[J]. Journal of Mechanical Engineering,2021,57(17):196-206. |