Characterization of Damage in Triaxial Braided Composites under Tensile Loading
Publication: Journal of Aerospace Engineering
Volume 22, Issue 3
Abstract
Carbon fiber composites that utilize flattened, large tow yarns in woven or braided forms are being used in many aerospace applications. The complex fiber architecture and large unit cell size in these materials present challenges for both understanding the deformation process and measuring reliable material properties. In this paper composites made using flattened 12k and 24k (referring to the number of fibers in the fiber tow) standard modulus carbon fiber yarns in a triaxial braided architecture are examined. Standard straight-sided tensile coupons were tested with the 0° axial braid fibers either parallel to (axial tensile test) or perpendicular to (transverse tensile test) the applied tensile load. The nonuniform surface strain resulting from the triaxial braided architecture was examined using photogrammetry. Local regions of high strain concentration were examined to identify where failure initiates and to determine the local strain at the time of failure initiation. Splitting within fiber bundles was the first failure mode observed at low to intermediate strains. For axial tensile tests the splitting was primarily in the bias fibers, which were oriented 60° to the applied load. At higher strains in the axial tensile test, out-of-plane deformation associated with localized delamination between fiber bundles or damage within fiber bundles was observed. For transverse tensile tests, the splitting was primarily in the 0° axial fibers, which were oriented transverse to the applied load. The initiation and accumulation of local damage caused the global transverse stress-strain curves to become nonlinear and caused failure to occur at a reduced ultimate strain for both the axial and transverse tensile tests. Extensive delamination at the specimen edges was also observed. Modifications to the standard straight-sided coupon geometry are needed to minimize these edge effects when testing the large unit cell type of material examined in this work.
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References
ASTM International. (2006). “Standard test method for tensile properties of polymer matrix composite materials.” ASTM D3039, Philadelphia.
Bowman, C. L. (2003). “Mechanical properties of triaxial braided carbon/epoxy composites.” Proc., 35th Int. SAMPE Technical Conf.—Materials and Processing: Enabling Flight . . . Our Legacy and Future, Dayton, Ohio, SAMPE, Covina, Calif.
Defense Technical Information Center. (2002). Composite materials handbook, MIL-HDBK-17-1F, Fort Belvoir, Va.
Fergusson, A. D., et al. (2006). “Flexural testing of composite sandwich structures with digital speckle photogrammetry.” Appl. Mech. Mater., 5–6, 135–144.
Gliesche, K., et al. (2005). “Investigations of in-plane shear properties of -carbon/epoxy composites using tensile testing and optical deformation analysis.” Compos. Sci. Technol., 65(2), 163–171.
GOM optical measuring techniques. (2009). “Industrial 3D measurement techniques.” ⟨www.gom.com⟩.
Grediac, M. (2004). “The use of full-field measurement methods in composite material characterization: Interest and limitations.” Composites, Part A, 35(7–8), 751–761.
Hale, R. D. (2003). “An experimental investigation into strain distribution in 2D and 3D textile composites.” Compos. Sci. Technol., 63, 2171–2185.
Hubner, J. P., et al. (2004). “Luminescent photoelastic coatings.” Exp. Mech., 44(4), 416–424.
Littell, J. D. (2008). “The experimental and analytical characterization of the macromechanical response for triaxial braided composite materials.” D.Phil. dissertation, Univ. of Akron, Akron, Ohio, ⟨http://www.ohiolink.edu/etd/view.cgi?acc_num=akron1224164770⟩.
Littell, J. D., et al. (2008). “Measurement of epoxy resin tension, compression, and shear stress-strain curves over a wide range of strain rates using small test specimens.” J. Aerosp. Eng., 21(3), 162–173.
Masters, J. E. (1996). “Strain gage selection criteria for textile composite materials.” NASA Contractor Rep. No. 198286, NASA, Washington, D.C.
Masters, J. E., et al. (1993). “The effects of specimen width on tensile properties of triaxially braided textile composites.” Proc., 3rd NASA Advanced Composites Technology Conf., Washington, D.C., 1(2), 523–536.
Masters, J. E., and Ifju, P. G. (1996). “A phenomenological study of triaxially braided textile composites loaded in tension.” Compos. Sci. Technol., 56(3), 347–358.
Masters, J. E., and Portanova, M. A. (1996). “Standard test methods for textile composites.” NASA Contractor Rep. No. 4751, NASA, Washington, D.C.
Pindera, M. J., Ifju, P., and Post, D. (1990). “Iosipescu shear characterization of polymeric and metal matrix composites.” Exp. Mech., 30(1), 101–108.
Tomblin, J., et al. (2001). “Material qualification methodology for biaxially braided RTM composite material systems.” AGATE-WP3.3-033048-116, AGATE, Wichita, Kan.
Tomblin, J. S., Ng, Y. C., and Raju, K. S. (2001). “Material qualification and equivalency for polymer matrix composite material systems.” DOT/FAA/AR-00/47, Federal Aviation Administration, Washington, D.C.
Tsotsis, T. K., et al. (2006). “Towards rapid screening of new composite matrix resins.” Compos. Sci. Technol., 66(11–12), 1651–1670.
Information & Authors
Information
Published In
Journal of Aerospace Engineering
Volume 22 • Issue 3 • July 2009
Pages: 270 - 279
Copyright
© 2009 ASCE.
History
Received: Jun 18, 2008
Accepted: Mar 12, 2009
Published online: Jun 15, 2009
Published in print: Jul 2009
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