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带防热层复合材料锥壳热固化变形的数值模拟 被引量:3

Numerical simulation of cure deformation of composite taper shell with thermal protection layer
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摘要 采用数值模拟方法研究带防热层缠绕成型复合材料锥壳热固化变形的形成机理和影响因素.建立了带防热层复合材料锥壳热固化变形预测的三维有限元程序.计算结果表明:外层防热材料和内层结构材料热膨胀系数不匹配是引起壳体固化变形的主要原因.提出在内层和外层之间增加中间过渡层的方法控制壳体的固化变形,中间层材料为丁腈橡胶片时可使固化变形减小20%以上.采用数值模拟方法讨论了中间层模量、厚度以及缠绕张力对壳体固化变形的影响,分析结果表明:固化变形随中间层模量的增加而增加,随中间层厚度的增加略有减小;缠绕张力释放增加壳体的固化变形,缠绕张力越大引起的固化变形越大. A three-dimensional finite element model was developed to simulate and predict the cure deformation during the winding processing of a composite taper shell with thermal protection layers. According to the results of numerical simulation, the first cause of the shell's cure deformation was the thermal expansion coefficient difference between protection material and structural material which lay on outer layers and inner layers respectively. Meanwhile, this cure deformation can be controlled effectively by adding the middle layer between outer layers and inner layers, which reduced about 20% deformation by using nitrile rubber as the middle layer's material. The effects of other influence factors were also discussed: cure deformation was in- creased by improving the middle layer's modulus and decreased slightly by increasing the middle layer's thick- ness ; the relief of winding tension, to some degree, had an impact on deformation, and larger tension leads to higher deformation.
作者 张纪奎 马志阳 李学梅 程小全
机构地区 北京航空航天大学航空科学与工程学院 航天材料及工艺研究所
出处 《北京航空航天大学学报》 EI CAS CSCD 北大核心 2013年第8期1037-1041,共5页 Journal of Beijing University of Aeronautics and Astronautics
基金 国家自然科学基金青年基金资助项目(50903002) 北京航空航天大学凡舟青年基金资助项目(20090506)
关键词 复合材料 防热层 固化变形 数值模拟 影响因素 composite materials thermal protection layer cure deformation numerical simulation in- fluence factor
分类号 TB332 [一般工业技术—材料科学与工程]
  • 相关文献

参考文献14

  • 1王晓洁,梁国正,张炜,谢群炜,惠雪梅.纤维增强树脂基隔热复合材料研究[J].宇航材料工艺,2006,36(3):22-25. 被引量:1
  • 2戴棣,乔新,刘善国.单曲面复合材料层合构件的固化变形计算[J].航空制造技术,1999,42(5):50-52. 被引量:10
  • 3Naji M I,Hoa S V.Curing of thick angle-bend thermoset composite part:curing process modification for uniform thickness and uniform fiber 34 fraction distribution[J].Journal of Composite Materials.2000,34(20):1710-1755.
  • 4Albert C,Fernlund G.Spring-in and warpage of angled composite laminate[J].Composites Science and Technology,2002,62(14):1895-1912.
  • 5Potter K D,Campbell M,Langer C.The generation of geometrical deformations due to tool/part interaction in the manufacture of composite components[J].Composites Part A:Applied Science and Manufacturing,2005,36(A):301-308.
  • 6Fernlund G,Osooly A,Poursartip A,et al.Finite element based prediction of process-induced deformation of autoclaved composite structures using 2D process analysis and 3D structural analysis[J].Composite Structures.2003,62(2):223-234.
  • 7White S R,Hahn H T.Process modeling of composite materials:residual stress development during cure,part Ⅰ:model formulation[J].Journal of Composite Materials.1992,26(16):2402-2422.
  • 8Calius E P,Lee S Y,Springer G S.Filament winding cylinders II:validation of the model[J].Journal of Composite Materials.1990,24(12):1299-1343.
  • 9Schledjewski R,Latrille M.Processing of unidirectional fiber reinforced tapes fundamental on the way to a process simulation tool[J].Composites Science and Technology.2003,63(14):1223-1230.
  • 10张宗毅,邓贵德,寿比南,李晓阳.缠绕张力对环缠绕复合材料气瓶应力的影响[J].压力容器,2011,28(5):7-14. 被引量:16

二级参考文献40

  • 1任明法,郑长良,陈浩然.具有内衬的缠绕容器缠绕层等张力设计的迭代搜索[J].复合材料学报,2004,21(5):153-158. 被引量:20
  • 2张霞.隔热材料性能的影响因素[J].材料开发与应用,1994,9(2):7-10. 被引量:19
  • 3杨庆生,杨卫,陈浩然,唐立民.复合材料的宏观性能与参数设计[J].力学与实践,1996,18(3):1-7. 被引量:9
  • 4沈军,谢怀勤,侯涤洋.纤维缠绕聚合物基复合材料压力容器的可靠性设计[J].复合材料学报,2006,23(4):124-128. 被引量:21
  • 5Chen Hungwen, Sun Huaiku, Liu Tienchih. Autofrettage analysis of a fibre-reinforced composite tube structure incorporated with a SMA [J]. Composite Structures, 2009, 89(4) : 497-508.
  • 6Jahromi B H, Farrahi G H, Maleki M. Residual stresses in autofrettaged vessel made of functionally graded material [J]. Engineering Structures, 2009, 31(12): 2930-2935.
  • 7Salzar R S. Influence of autofrettage on metal matrix composite reinforced gun barrels [J]. Composites Part B, 1999, 30(8):841-847.
  • 8Hu J, Chandrashekhara K. Fracture analysis of hydrogen storage composite cylinders with liner crack accounting for autofrettage effect[J]. International Journal of Hydrogen Energy, 2009, 34(8): 3425- 3435.
  • 9Kim C H, Park J H, Kim C, Choi J C. Expert system for process planning of pressure vessel fabrication by deep drawing and ironing [J]. Journal of Materials Processing Technology, 2004, 155/156(30): 1465-1473.
  • 10Alegre J M, Bravo P, Preciado M. Fatigue behavior of an autofrettaged high-pressure vessel for the food industry [J]. Engineering Failure Analysis, 2007, 14(2): 396-407.

共引文献45

同被引文献135

引证文献3

二级引证文献126

北京航空航天大学学报
2013年 第8期

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