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含界面相的单向纤维增强复合材料三维应力场的二重双尺度方法 被引量:8

Dual two-scale method for 3D stress computation of unidirectional-fibre reinforced composites considering interphase
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摘要 提出了计算含界面相的单向纤维增强复合材料三维应力的二重双尺度方法。在性能预报方面,首先对界面相和纤维进行均匀化得到均匀化夹杂,然后对均匀化夹杂和基体进行均匀化得到宏观均匀材料;在应力场描述方面,从宏观均匀场出发,利用双尺度渐近展开技术经过两次应力场传递,依次得到单胞和应力集中区域的应力场。与有限元方法相结合,计算了宏观轴向均匀拉伸载荷条件下含界面相的单向纤维增强复合材料的三维应力场分布。数值结果表明在此载荷条件下最大应力发生在每根纤维的中截面内,靠近纤维与界面相的交界处。讨论了界面相性能对应力场分布的影响,结果显示纤维、界面相与基体力学性能的等差过渡有利于缓解纤维在界面附近的应力集中。 A dual two-scale method was presented for computing 3D stress fields of unidirectional-fibre reinforced composites considering the interphase.In the prediction of properties,the homogenized inclusion was obtained by homogenizing the fibre and the interphase,and the macroscopic homogenized material was obtained by homogenizing the homogenized inclusion and the matrix.In the characterization of 3D stress fields,by twice stress transmissions,the stress fields of the unit cell and the stress concentration area were obtained in turn by the two-scale asymptotic technique.Combining with the finite element method,the 3D stress fields of the proposed composites,which are under the macroscopic axial uniform tensile load,were computed by the dual two-scale method.The numerical results show that the maximum stress occurs within the region which is in the middle section of each fibre and close to the border between fibre and interphase.The influence of different interphases on the distributions of stress fields was also discussed.The results show that arithmetical transition of the properties of fibre,interphase and matrix is beneficial to releasing stress concentration.
作者 唐绍锋 梁军 杜善义
机构地区 哈尔滨工业大学复合材料与结构研究所
出处 《复合材料学报》 EI CAS CSCD 北大核心 2010年第1期167-172,共6页 Acta Materiae Compositae Sinica
基金 国家自然科学基金(10772060) 黑龙江省杰出青年基金(JC-2006-13)
关键词 二重双尺度方法 三维应力场 界面相 单向纤维增强复合材料 宏观性能 有限元方法 dual two-scale method 3D stress fields interphase unidirectional-fibre reinforced composites macroscopic properties finite element method(FEM)
分类号 TB33 [一般工业技术—材料科学与工程] O343.7 [理学—固体力学]
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参考文献11

  • 1Lions J L. Some methods in the mathematical analysis of systems and their control [MJ. Beijing:Science Press, 1981.
  • 2Kesavan S. Homogenization of elliptic eigenvalue problems I [J].Applied Mathematics and Optimization, 1979, 5 (1): 153-167.
  • 3Kesavan S. Homogenization of elliptic eigenvalue problems II [J]. Applied Mathematics and Optimization, 1979, 5 (1) : 197-216.
  • 4崔俊芝,曹礼群.基于双尺度渐近分析的有限元算法[J].计算数学,1998,20(1):89-102. 被引量:31
  • 5Song Y S, Youn J R. Asymptotic expansion homogenization of permeability tensor for plain woven fabrics [J]. Composites Part A, 2006, 37(11): 2080-2087.
  • 6汪海滨,张卫红,杨军刚,许英杰,曾庆丰.考虑孔隙和微裂纹缺陷的C/C-SiC编织复合材料等效模量计算[J].复合材料学报,2008,25(3):182-189. 被引量:26
  • 7Alzina A, Toussaint E, Beakou A, Skoczen B. Multiscale modeling of thermal conductivity in composite materials for cryogenic structures [J]. Composite Structures, 2006, 74(2) : 175-185.
  • 8Alzina A, Toussaint E, Beakou A. Multiscale modeling of the thermoelastic behavior of braided fabric composites for cryogenic structures[J]. International Journal of Solids and Structures, 2007, 44(21): 6842-6859.
  • 9Tang Shaofeng, Huang Fuhua, Liang Jun, Du Shanyi. Multiscale analysis for thermo- elasticity properties of composite materials with small periodic configuration [J]. Key Engineering Materials, 2007, 334/335: 25-28.
  • 10雷友锋,魏德明,高德平.细观力学有限元法预测复合材料宏观有效弹性模量[J].燃气涡轮试验与研究,2003,16(3):11-15. 被引量:36

二级参考文献27

  • 1周储伟.高体积含量颗粒增强复合材料的一个细观力学模型 Ⅰ:弹性分析与等效模量[J].复合材料学报,2005,22(4):125-130. 被引量:15
  • 2邱克鹏,张卫红,孙士平.蜂窝夹层结构等效弹性常数的多步三维均匀化数值计算分析[J].西北工业大学学报,2006,24(4):514-518. 被引量:14
  • 3[1]Eshelby J D. The Determination of the Elastic Field of an Ellipsoidal Inclusion and Related Problem [C]. London: Proceedings of the Royal Society Series A, 1957.
  • 4[2]Hill R. A Self-consistent Mechanics of Composite Materials [J]. J Mech Phys Solids, 1965,13:213-222.
  • 5[3]Mori T, Tanaka K. Average Stress in Matrix and Average Enengy of Materials with Misfitting Inclusions[J]. Acta Metall,1973,21:571-574.
  • 6[4]Caruso J J. Application of Finite Element Substructuring to Composites Micromechanics [R]. NASA TM-83729, 1984.
  • 7[5]Brockenbrough J R, Suresh S, Wienecke H A. Deformation of MMCs with Continuous Fibers: Geometrical Effects of Fiber Distribution and Shape [J]. Acta Metall Mater, 1991, 39: 735-752.
  • 8[6]Zhang W C, Evans K E. Numerical Prediction of Mechanical Properties of Anisotropic Composite Materials [J]. Computers and Structures, 1988,29(3):413-422.
  • 9[7]Fang Daining, Liu Tieqi . On the effect of Fiber Shape and Packing Array on Elastic Properties of Fiber-Polymer-Matrix Composites [J]. Inter J Polymeric Mater, 1996,34(1): 75-90.
  • 10[8]Nakamura T, Suresh S. Effects of thermal residual stresses and fiber packing on deformation of metal matrix composites [J]. Acta Metall. Mater., 1993, 41(6):1665-1681.

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复合材料学报
2010年 第1期

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