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Applied Composite Materials

Erschienen in:

01.08.2016

Simulation of High Velocity Impact on Composite Structures - Model Implementation and Validation

verfasst von: Dominik Schueler, Nathalie Toso-Pentecôte, Heinz Voggenreiter

Erschienen in: Applied Composite Materials | Ausgabe 4/2016

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Abstract

High velocity impact on composite aircraft structures leads to the formation of flexural waves that can cause severe damage to the structure. Damage and failure can occur within the plies and/or in the resin rich interface layers between adjacent plies. In the present paper a modelling methodology is documented that captures intra- and inter-laminar damage and their interrelations by use of shell element layers representing sub-laminates that are connected with cohesive interface layers to simulate delamination. This approach allows the simulation of large structures while still capturing the governing damage mechanisms and their interactions. The paper describes numerical algorithms for the implementation of a Ladevèze continuum damage model for the ply and methods to derive input parameters for the cohesive zone model. By comparison with experimental results from gas gun impact tests the potential and limitations of the modelling approach are discussed.

Vorheriger Artikel Bearing Abilities and Progressive Damage Analysis of Three Dimensional Four-Directional Braided Composites with Cut-Edge

Nächster Artikel Investigation on the Geometric Imperfections driven Local Buckling Onset in Composite Conical Shells

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MAAXIMUS More Affordable Aircraft through EXtended, Integrated and Mature NUmerical Sizing, EU Aeronautics Research Project, FP7-213371, 2008-2013.

Olsson R.: Mass criterion for wave controlled impact response of composite plates. Compos. A: Appl. Sci. Manuf. 31(8), 879–887 (2000)CrossRef

Ladevèze P., LeDantec E.: Damage modelling of the elementary ply for laminated composites. Compos. Sci. Technol. 43(3), 257–267 (1992)CrossRef

Allix O., Ladeveze P.: Interlaminar interface modelling for the prediction of delamination. Compos. Struct. 22(4), 235–242 (1992)CrossRef

Johnson A.F., Pickett A.K., Rozycki P.: Computational methods for predicting impact damage in composite structures. Compos. Sci. Technol. 61(15), 2183–2192 (2001)CrossRef

Pickett A.K., Fouinneteau M.R.C., Middendorf P.: Test and modelling of impact on pre-loaded composite panels. Appl. Compos. Mater. 16(4), 225–244 (2009)CrossRef

Heimbs S., Bergmann T., Schueler D., Toso-Pentecôte N.: High velocity impact on preloaded composite plates. Compos. Struct. 111, 158–168 (2014)CrossRef

Turon A., Davila C.G., Camanho P.P., Costa J.: An engineering solution for mesh size effects in the simulation of delamination using cohesive zone models. Eng. Fract. Mech. 74(10), 1665–1682 (2007)CrossRef

Chadwick A., Evans R., Findlay D., Rickett B., Spriggs J.: Airport Runway Debris Detection Study Report no: 72/01/R/146/U. Technical report, Roke Manor Research Limited (2001)

10.

Wu D., Salerno A., Malter U., Aoki R., Kochendörfer R., Kächele P.K., et al.: Inspection of aircraft structural components using lockin-thermography. Quantitative Infrared Thermography, QIRT. 96, 251–256 (1996)

11.

Imielińska K., Castaings M., Wojtyra R., Haras J., Le Clezio E., Hosten B.: Air-coupled ultrasonic C-scan technique in impact response testing of carbon fibre and hybrid: glass, carbon and Kevlar/epoxy composites. J. Mater. Process. Technol. 157, 513–522 (2004)CrossRef

12.

Liu D.: Impact-induced delamination—a view of bending stiffness mismatching. J. Compos. Mater. 22(7), 674–692 (1988)CrossRef

13.

Guynn, E. G., and O’Brien, T. K. (1985). The influence of lay-up and thickness on composite impact damage and compression strength. In Proc 26th AIAA/ASME/ASCE/AHS/ASC Structures, Structural dynamics and Materials Conf, Orlando, FL (pp. 15–17).

14.

Kachanov, L. (2013). Introduction to continuum damage mechanics (Vol. 10). Springer Science & Business Media.

15.

Nezhad H.Y., Merwick F., Frizzell R.M., McCarthy C.T.: Numerical analysis of low-velocity rigid-body impact response of composite panels. International Journal of Crashworthiness. 20(1), 27–43 (2015)CrossRef

16.

McCarthy M.A., Xiao J.R., Petrinic N., Kamoulakos A., Melito V.: Modelling bird impacts on an aircraft wing–part 1: material modelling of the fibre metal laminate leading edge material with continuum damage mechanics. International Journal of Crashworthiness. 10(1), 41–49 (2005)CrossRef

17.

Mishnaevsky L., Dong M., Hoenle S., Schmauder S.: Computational mesomechanics of particle-reinforced composites. Comput. Mater. Sci. 16(1), 133–143 (1999)CrossRef

18.

Belytschko T., Liu W.K., Moran B.: Nonlinear Finite Elements for Continua and Structures, 1 edn. Wiley, Chichester (2000)

19.

Mi Y., Crisfield M.A., Davies G.A.O., Hellweg H.B.: Progressive delamination using interface elements. J. Compos. Mater. 32(14), 1246–1272 (1998)CrossRef

20.

Cui W., Wisnom M.R.: A combined stress-based and fracture-mechanics-based model for predicting delamination in composites. Composites. 24(6), 467–474 (1993)CrossRef

21.

Turon A., Camanho P.P., Costa J., Dávila C.G.: An interface damage model for the simulation of delamination under variable-mode ratio in composite materials. NASA/Technical Memorandum. 213277, (2004)

22.

Reeder J.R.: An evaluation of mixed-mode delamination failure criteria. NASA/Technical Memorandum. 104210, (1992)

23.

Wu, E. M., and Reuter Jr, R. C. (1965). Crack extension in fiberglass reinforced plastics (vol. 275). Illinois Univ. Dept. of Theoretical and Applied Mechanics.

24.

Allix O., Lévêque D., Perret L.: Identification and forecast of delamination in composite laminates by an interlaminar interface model. Compos. Sci. Technol. 58(5), 671–678 (1998)CrossRef

25.

Choi H.Y., Chang F.-K.: A model for predicting damage in graphite/epoxy laminated composites resulting from low-velocity point impact. J. Compos. Mater. 26(14), 2134–2169 (1992)CrossRef

26.

Geubelle P.H., Baylor J.S.: Impact-induced delamination of composites: a 2D simulation. Compos. Part B. 29(5), 589–602 (1998)CrossRef

27.

Ladevèze P., Lubineau G.: An enhanced mesomodel for laminates based on micromechanics. Compos. Sci. Technol. 62(4), 533–541 (2002)CrossRef

28.

Zou Z., Reid S.R., Li S., Soden P.D.: Modelling interlaminar and intralaminar damage in filament-wound pipes under quasi-static indentation. J. Compos. Mater. 36(4), 477–499 (2002)CrossRef

29.

Camanho P.P., Davila C.G., De Moura M.F.: Numerical simulation of mixed-mode progressive delamination in composite materials. J. Compos. Mater. 37(16), 1415–1438 (2003)CrossRef

30.

Hallett, S. R. and Harper, P. W. (2015). Modelling delamination with cohesive interface elements. In Numerical modelling of failure in advanced composite materials (pp. 55–72). Elsevier.

31.

Borg R., Nilsson L., Simonsson K.: Simulation of delamination in fiber composites with a discrete cohesive failure model. Compos. Sci. Technol. 61(5), 667–677 (2001)CrossRef

32.

Heimbs S., Heller S., Middendorf P., Hähnel F., Weiße J.: Low velocity impact on CFRP plates with compressive preload: test and modelling. International Journal of Impact Engineering. 36(10), 1182–1193 (2009)CrossRef

33.

Abaqus: Abaqus Analysis User’s Manual. Dassault Systèmes Simulia Corp, Providence (2010)

34.

Chowdhury M.A., Nuruzzaman D.M., Roy B.K.: Experimental investigation of friction coefficient and wear rate of stainless steel 304 sliding against smooth and rough mild steel Counterfaces. Gazi University Journal of Science. 26(4), 597–609 (2013)

35.

Schön J.: Coefficient of friction of composite delamination surfaces. Wear. 237(1), 77–89 (2000)CrossRef

36.

Williams K.V., Vaziri R., Poursartip A.: A physically based continuum damage mechanics model for thin laminated composite structures. Int. J. Solids Struct. 40(9), 2267–2300 (2003)CrossRef

Titel: Simulation of High Velocity Impact on Composite Structures - Model Implementation and Validation
verfasst von: Dominik Schueler
Nathalie Toso-Pentecôte
Heinz Voggenreiter
Publikationsdatum: 01.08.2016
Verlag: Springer Netherlands
Erschienen in: Applied Composite Materials / Ausgabe 4/2016
Print ISSN: 0929-189X
Elektronische ISSN: 1573-4897
DOI: https://doi.org/10.1007/s10443-016-9489-0

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