Use of Digital Image Correlation to Analyse the Shearing Deformation in Woven Fabric

被引:14
作者
Dridi, S. [1 ,2 ]
Morestin, F. [1 ]
Dogui, A. [2 ]
机构
[1] INSA Lyon, Lab Contact & Struct Mech LaMCoS, Lyon, France
[2] Natl Engn Sch Monastir, Mech Engn Lab, Monastir, Tunisia
来源
EXPERIMENTAL TECHNIQUES | 2012年 / 36卷 / 05期
关键词
Shearing Behaviour; Cotton Fabrics; Bias Extension Test; Picture Frame Test; Digital Image Correlation; PICTURE FRAME; MECHANICAL-BEHAVIOR; BIAXIAL TENSION; BIAS EXTENSION; COMPOSITE; TESTS; SPECIMEN; RATIO;
D O I
10.1111/j.1747-1567.2011.00776.x
中图分类号
TH [机械、仪表工业];
学科分类号
0802 ;
摘要
The mechanical behaviour of a woven structure remains poorly understood because of the material's anisotropic behaviour. This leads to the challenging task of performing a reliable and repeatable investigation for the characterisation of the material properties. Shear properties of the woven fabric are assessed by bias extension and picture frame tests. The aim of the present work is to analyse the shear deformation in plain cotton fabric during bias extension and picture frame tests using digital image correlation. The latter allows direct and local measurement that does not require a numerical or analytical model. Using this optical method, the homogeneity of deformation is studied and the experimental strain is compared to that predicted by theory.
引用
收藏
页码:46 / 52
页数:7
相关论文
共 33 条
[1]  
Bekampiene P, 2009, MATER SCI-MEDZG, V15, P167
[2]   Analysis of the mechanical behavior of woven fibrous material using virtual tests at the unit cell level [J].
Boisse, P ;
Gasser, A ;
Hagege, B ;
Billoet, JL .
JOURNAL OF MATERIALS SCIENCE, 2005, 40 (22) :5955-5962
[3]   A mesoscopic approach for the simulation of woven fibre composite forming [J].
Boisse, P ;
Zouari, B ;
Gasser, A .
COMPOSITES SCIENCE AND TECHNOLOGY, 2005, 65 (3-4) :429-436
[4]   Importance of in-plane shear rigidity in finite element analyses of woven fabric composite preforming [J].
Boisse, Philippe ;
Zouari, Bassem ;
Daniel, Jean-Luc .
COMPOSITES PART A-APPLIED SCIENCE AND MANUFACTURING, 2006, 37 (12) :2201-2212
[5]   Characterization of mechanical behavior of woven fabrics: Experimental methods and benchmark results [J].
Cao, J. ;
Akkerman, R. ;
Boisse, P. ;
Chen, J. ;
Cheng, H. S. ;
de Graaf, E. F. ;
Gorczyca, J. L. ;
Harrison, P. ;
Hivet, G. ;
Launay, J. ;
Lee, W. ;
Liu, L. ;
Lomov, S. V. ;
Long, A. ;
de Luycker, E. ;
Morestin, F. ;
Padvoiskis, J. ;
Peng, X. Q. ;
Sherwood, J. ;
Stoilova, Tz. ;
Tao, X. M. ;
Verpoest, I. ;
Willems, A. ;
Wiggers, J. ;
Yu, T. X. ;
Zhu, B. .
COMPOSITES PART A-APPLIED SCIENCE AND MANUFACTURING, 2008, 39 (06) :1037-1053
[6]   Decrimping behavior of uncoated plain-woven fabrics subjected to combined biaxial tension and shear stresses [J].
Cavallaro, Paul V. ;
Sadegh, Ali M. ;
Quigley, Claudia J. .
TEXTILE RESEARCH JOURNAL, 2007, 77 (06) :403-416
[7]   APPLICATIONS OF DIGITAL-IMAGE-CORRELATION TECHNIQUES TO EXPERIMENTAL MECHANICS [J].
CHU, TC ;
RANSON, WF ;
SUTTON, MA ;
PETERS, WH .
EXPERIMENTAL MECHANICS, 1985, 25 (03) :232-244
[8]   Shear characterisation of viscous woven textile composites: a comparison between picture frame and bias extension experiments [J].
Harrison, P ;
Clifford, MJ ;
Long, AC .
COMPOSITES SCIENCE AND TECHNOLOGY, 2004, 64 (10-11) :1453-1465
[9]  
Kevin P., 2002, COMPOS PART A-APPL S, V33, P63
[10]   Tensile extension properties and deformation mechanisms of multiaxial non-crimp fabrics [J].
Kong, H ;
Mouritz, AP ;
Paton, R .
COMPOSITE STRUCTURES, 2004, 66 (1-4) :249-259
1234