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Applied Composite Materials

Erschienen in:

01.07.2007

A Meso–Macro Three Node Finite Element for Draping of Textile Composite Preforms

verfasst von: Nahiène Hamila, Philippe Boisse

Erschienen in: Applied Composite Materials | Ausgabe 4/2007

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Abstract

The composite textile reinforcement draping simulations allows the conditions for a successful process to be determined and, most importantly, the positions of the fibres after forming to be known. This last point is essential for the structural computations of the composite part and for resin injection analyses in the case of LCM processes. Because the textile composite reinforcements are multiscale materials, continuous (macro) approaches and discrete (meso) approaches that model the yarns have been developed. The finite element that is proposed in this paper for textile fabric forming is composed of woven unit cells. The mechanical behaviour of these is analyzed by 3D computations at the mesoscale regarding biaxial tensions and in plane shear. The warp and weft directions of the woven fabric can be in arbitrary direction with respect to the direction of the element side. This is very important in the case of multi-ply deep drawing and when using remeshing. The element is efficient because it is close to the physic of the woven cell while avoiding the very large number of unknowns in the discrete approach. A set of validation tests and forming simulations on single ply and multi-ply are presented and show the efficiency of the approach. In particular the importance of the in-plane shear behaviour is emphasized in the case of a draping on a cube.

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Pora, J.: Composite materials in the airbus A380-from history to future, Proceedings of ICCM13, Beijing, July 2001

Sinke J.: Manufacturing of GLARE parts and structures. Appl. Compos. Mater. 10(4–5), 293–305 (2003)CrossRef

Hammami, A., Trochu, F., Gauvin, R., Wirth, S.: Directional permeability measurement of deformed reinforcement. J. Reinf. Plas. Compos. 15, 552–562 (1996)

Takano, N., Zako, M., Okazaki, T., Terada, K.: Microstructure-based evaluation of the influence of woven architecture on permeability by asymptotic homogenization theory. Compos. Sci. Technol. 62, 1347–1356 (2002)CrossRef

Song, Y.S.: Mathematical analysis of resin flow through fibrous porous media, Appl. Compos. Mater. 13(5), 335–343 (2006)CrossRef

Mark, C., Taylor, H.M.: The fitting of woven cloth to surfaces. J. Text. Inst. 47, 477–488 (1956)

Van Der Ween, F.: Algorithms for draping fabrics on doubly curved surfaces. Int. J. Numer. Meth. Eng. 31, 1414–1426 (1991)CrossRef

Long, A.C., Rudd, C.D.: A simulation of reinforcement deformation during the production of preform for liquid moulding processes. Proc. Inst. Mech. Eng. J. Eng. Manuf. 208, 269–278 (1994)

Spencer, A.J.M.: Theory of fabric-reinforced viscous fluid. Composites. Part A 31, 1311–1321 (2000)CrossRef

10.

Dong, L., Lekakou, C., Bader, M.G.: Processing of composites: simulations of the draping of fabrics with updated material behaviour law. J. Compos. Mater. 35, 138–163 (2001)CrossRef

11.

Peng, X., Cao, J.: A continuum mechanics-based non-orthogonal constitutive model for woven composite fabrics. Composites. Part A. 36, 859–874 (2005)CrossRef

12.

Boisse, P., Gasser, A., Hagege, B., Billoet, J.L.: Analysis of the mechanical behaviour of woven fibrous material using virtual tests at the unit cell level. Int. J. Mater. Sci. 40, 5955–5962 (2005)CrossRef

13.

Ten Thije, R.H.W., Akkerman, R., Huetink, J.: Large deformation simulation of anisotropic material using an updated Lagrangian finite element method, Comput. Methods Appl. Mech. Eng. 196(33–34), 3141–3150 (2007)CrossRef

14.

Durville, D.: Modélisation par éléments finis des propriétés mécaniques de structures textiles: de la fibre au tissu. Eur. J. Comput. Mech. 11(2–3–4), 463–477 (2002)

15.

Pickett, A.K.: Review of finite element methods applied to manufacturing and failure prediction in composite structures. Appl. Compos. Mater. 9, 43–58 (2002).CrossRef

16.

Sze, K.Y., Liu, X.H.: A new skeletal model for fabric drapes. Int. J. Mech. Mater. Des. 2, 225–243 (2005)

17.

Duhovic, M., Bhattacharyya, D.: Simulating the deformation mechanisms of knitted fabric composites. Composites. A 37(11), 1897–1915 (2006)CrossRef

18.

Douthe, C., Baverel, O., Caron, J.F.: Form-finding of a grid shell in composite materials. J. Int. Assoc. Shell Spat. Struct. 47, 53–62, (2006)

19.

Boisse, P., Borr, M., Buet, K., Cherouat, A.: Finite element simulation of textile composite forming including the biaxial fabric behaviour, Composites. Part B, 28, 453–464 (1997)CrossRef

20.

Boisse, P., Zouari, B., Daniel, J.L.: Importance of in-plane shear rigidity in finite element analyses of woven fabric composite preforming. Composites. Part A. 37, 2201–2212 (2006)CrossRef

21.

Scardino, F.: An introduction to textile structures and their behaviour. In: Chou, T.W., Ko, F.K (eds.) Textile Structural Composites (Composite Material Series, pp. 1–26). Elsevier, Amsterdam (1989)

22.

Buet-Gautier, K, Boisse, P.: Experimental analysis and modeling of biaxial mechanical behavior of woven composite reinforcements. Exp. Mech. 41(3), 260–269 (2001)CrossRef

23.

Lomov, S.V., Verpoest I.: Model of shear of woven fabric and parametric description of shear resistance of glass woven reinforcements. Compos. Sci. Technol. 66, 919–933 (2006)CrossRef

24.

Launay, J., Hivet, G., Duong, A.V., Boisse, P.: Experimental analysis of the influence of tensions on in plane shear, Compos. Sci. Technol., in press (2007) DOI 10.1016/j.compscitech.2007.06.021

25.

Willems, A., Lomov, S.V., Verpoest, I., Vandepitte, D.: In: Cueto, E., Chinesta, P. (eds.) Conference ESAFORM 10, Zaragoza, AIP Conf. Proc. Vol. 907, 999–1004, (2007)

26.

Gasser, A., Boisse, P., Hanklar, S.: Analysis of the mechanical behaviour of dry fabric reinforcements. 3D simulations versus biaxial tests. Comput. Mater. Sci. 17, 7–20 (2000)

27.

Boisse, P., Buet, K., Gasser, A., Launay, J.: Meso–macro mechanical behaviour of textile reinforcements of thin composites. C.ompos Sci. Technol. 61, 395–401 (2001)CrossRef

28.

Badel, P., Vidal-Sallé, E., Boisse, P.: Computational determination of in plane shear mechanical behaviour of textile composite reinforcements. Comput. Mat. Sci. 40(4), 439–448 (2007)CrossRef

29.

Prodromou, A.G., Chen, J.: On the relationship between shear angle and wrinkling of textile composite preforms. Composites. Part A 28(5), 491–503 (1997)CrossRef

30.

McGuinness, G.B., Bradaigh, C.M.O.: Characterisation of thermoplastic composite melts in rhombus-shear: the picture-frame experiment. Composites. Part A 29(1–2), 115–132 (1998)CrossRef

31.

Peng, X.Q., Cao, J., Chen, J., Xue, P., Lussier, D.S., Liu, L.: Experimental and numerical analysis on normalization of picture frame tests for composite materials. Compos. Sci. Technol. 64, 11–21 (2004)CrossRef

32.

Belytschko, T.: An overview of semidiscretisation and time integration procedures. In: Belytschko T., Hughes, T.J.R., (eds). Computation Methods for Transient Analysis, pp.1–65. Elsevier Science, Amsterdam (1983)

33.

Hughes, T.J.H., Belytschko T.: A precise of developments in computational methods for transient analysis. J. Appl. Mech. 50, 1033–1041 (1983)CrossRef

34.

Crisfield, M.A.: Non-linear Finite Element Analysis of Solids and Structures, 2. Wiley, Chichester (1997)

35.

Zienkiewicz, O., Taylor, R.: The Finite Element Method, 1. McGrawHill, London (1989)

36.

Wang, J., Page, J.R., Paton, R.: Experimental investigation of the draping properties of reinforcement fabrics. Compos. Sci. Technol. 58, 229–237 (1998)CrossRef

37.

Potter, K.: Bias extension measurements on cross-plied unidirectional prepreg. Composites. Part A 33, 63–73 (2002)CrossRef

38.

Lebrun, G., Bureau, N., Denault, J.: Evaluation of bias-extension and picture-frame test methods for the measurement of intraply shear properties of PP/glass commingled fabrics. Compos. Struct. 61, 341–352 (2003)CrossRef

39.

Gorczyca, J., Sherwood, J., Chen, J.: A friction model for thermostamping commingled glass–polypropylene woven fabrics. Composites. Part A 38, 393–406 (2007)CrossRef

Titel: A Meso–Macro Three Node Finite Element for Draping of Textile Composite Preforms
verfasst von: Nahiène Hamila
Philippe Boisse
Publikationsdatum: 01.07.2007
Verlag: Springer Netherlands
Erschienen in: Applied Composite Materials / Ausgabe 4/2007
Print ISSN: 0929-189X
Elektronische ISSN: 1573-4897
DOI: https://doi.org/10.1007/s10443-007-9043-1

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