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Shear Evolution of Fiberglass Composites Under Compression

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Abstract

Woven composites can offer mechanical improvements over more traditional engineering materials, yet understanding the complex interplay between the fiber-matrix architecture during loading remains a challenge. This paper investigates the evolution of shear failure behavior during the compression of high performance fiberglass composites with varying resin binders at both quasi-static and dynamic strain rates. All samples are comprised of commercially available woven glass cloth with approximately 56 % fiber volume fraction. Laminates with thermosetting resin binders of silicone, melamine, and epoxy were examined. High-speed imaging reveals that failure occurs within a localized shear band region through multiple fiber-weave matrix interface failure with a characteristic macroscopic angle. The shear evolution was spatially mapped using grayscale histograms of the light intensity in the shear regions, and the resulting characteristic angles were measured and analyzed in the context of a Mohr-Coulomb failure criterion. Optical microscopy and high-speed imaging of the shear formation shows initiation appears due to local instabilities from kinking and microbuckling, influenced by the stacking and interlacing regions of tows.

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References

  1. Hahn HT, Tsai SW (1973) Nonlinear elastic behavior of unidirectional composite laminae. J Compos Mater 7(1):102–118

    Article  Google Scholar 

  2. Gates TS, Sun CT (1991) Elastic/viscoplastic constitutive model for fiber reinforced thermoplastic composites. AIAA J 29(3):457–463

    Article  Google Scholar 

  3. Harding J (1993) Effect of strain rate and specimen geometry on the compressive strength of woven glass-reinforced epoxy laminates. Composites 24(4):323–332

    Article  Google Scholar 

  4. Yoon KJ, Sun CT (1991) Characterization of elastic-viscoplastic properties of an AS4/PEEK thermoplastic composite. J Compos Mater 25(10):1277–1296

    Google Scholar 

  5. Budiansky B, Fleck NA (1993) Compressive failure of fibre composites. J Mech Phys Solids 41(1):183–211

    Article  Google Scholar 

  6. Takeda N, Wan L (1995) Impact compression damage evolution in unidirectional glass fiber reinforced polymer composites. High strain rate effects on polymer, metal and ceramic matrix composites and other advanced materials, pp 109–113

  7. Tay TE, Ang HG, Shim VPW (1995) An empirical strain rate-dependent constitutive relationship for glass-fibre reinforced epoxy and pure epoxy. Compos Struct 33(4):201–210

    Article  Google Scholar 

  8. Weeks CA, Sun CT (1998) Modeling non-linear rate-dependent behavior in fiber-reinforced composites. Compos Sci Technol 58(3):603–611

    Article  Google Scholar 

  9. Lee SH, Waas AM (1999) Compressive response and failure of fiber reinforced unidirectional composites. Int J Fract 100(3):275–306

    Article  Google Scholar 

  10. Vogler TJ, Kyriakides S (2001) On the initiation and growth of kink bands in fiber composites: Part I. experiments. Int J Solids Struct 38(15):2639–2651

    Article  MATH  Google Scholar 

  11. Xiao JR, Gillespie JW (2007) A phenomenological Mohr-Coulomb failure criterion for composite laminates under interlaminar shear and compression. J Compos Mater 41(11):1295–1309

    Article  Google Scholar 

  12. Harding J (1989) Impact damage in composite materials. Sci Eng Compos Mater 1(2):41–68

    Article  Google Scholar 

  13. Abrate S (1991) Impact on laminated composite materials. Appl Mech Rev 44(4):155–90

    Article  Google Scholar 

  14. Abrate S (1994) Impact on laminated composites: recent advances. Appl Mech Rev 47(11):517–544

    Article  Google Scholar 

  15. Cantwell WJ, Morton J (1991) The impact resistance of composite materials—a review. Composites 22 (5):347–362

    Article  Google Scholar 

  16. Kumar P, Garg A, Agarwal BD (1986) Dynamic compressive behaviour of unidirectional GFRP for various fibre orientations. Mater Lett 4(2):111–116

    Article  Google Scholar 

  17. Shokrieh MM, Omidi MJ (2009) Compressive response of glass–fiber reinforced polymeric composites to increasing compressive strain rates. Compos Struct 89(4):517–523

    Article  Google Scholar 

  18. Ochola RO, Marcus K, Nurick GN, Franz T (2004) Mechanical behaviour of glass and carbon fibre reinforced composites at varying strain rates. Compos Struct 63(3):455–467

    Article  Google Scholar 

  19. Staab GH, Gilat A (1995) High strain rate response of angle-ply glass/epoxy laminates. J Compos Mater 29(10):1308–1320

    Article  Google Scholar 

  20. Song B, Chen W, Weerasooriya T (2003) Quasi-static and dynamic compressive behaviors of a S-2 glass/SC15 composite. J Compos Mater 37(19):1723–1743

    Article  Google Scholar 

  21. Vural M, Ravichandran G (2004) Transverse failure in thick S2-glass/epoxy fiber-reinforced composites. J Compos Mater 38(7):609–623

    Article  Google Scholar 

  22. Khan AS, Colak OU, Centala P (2002) Compressive failure strengths and modes of woven S2-glass reinforced polyester due to quasi-static and dynamic loading. Int J Plast 18(10):1337–1357

    Article  Google Scholar 

  23. El-Habak AMA (1991) Mechanical behaviour of woven glass fibre-reinforced composites under impact compression load. Composites 22(2):129–134

    Article  Google Scholar 

  24. Powers BM, Vinson JR, Hall IW, Hubbard RF (1997) High strain rate properties of cycom 5920/1583. AIAA J 35(3):553–556

    Article  Google Scholar 

  25. Nishida EE, Foster JT, Briseno PE (2012) Constant strain rate testing of a G10 laminate composite through optimized kolsky bar pulse shaping techniques. J Compos Mater 47(23):2955– 2963

    Article  Google Scholar 

  26. Ravi-Chandar K, Satapathy S (2007) Mechanical properties of G-10 glass-epoxy composite. Defense Technical Information Center

  27. Harding J, Dong L (1994) Effect of strain rate on the interlaminar shear strength of carbon-fiber-reinforced laminates. Combust Sci Technol 51(3):347–358

    Article  Google Scholar 

  28. Benloulo ISC, Rodriguez J, Martinez MA, Galvez VS (1997) Dynamic tensile testing of aramid and polyethylene fiber composites. Int J Impact Eng 19(2):135–146

    Article  Google Scholar 

  29. Wang Y, Xia Y (2000) A modified constitutive equation for unidirectional composites under tensile impact and the dynamic tensile properties of kfrp. Compos Sci Technol 60(4):591– 596

    Article  Google Scholar 

  30. Sierakowski RL, Chaturvedi SK (1997) Dynamic loading and characterization of fiber-reinforced composites. Wiley-Interscience, New York

    Google Scholar 

  31. Sierakowski RL (1997) Strain rate effects in composites. Appl Mech Rev 50(12):741–761

    Article  Google Scholar 

  32. Al-Hassani STS, Kaddour AS (1997) Strain rate effects on GRP, KRP and CFRP composite laminates. In: Key engineering materials, vol 141. Trans Tech Publ, pp 427–452

  33. Greszczuk LB (1982) Damage in composite materials due to low velocity impact. Wiley, New York

    Google Scholar 

  34. MatWeb (2014) Material property data. http://www.matweb.com

  35. Frew DJ, Forrestal MJ, Chen W (2002) Pulse shaping techniques for testing brittle materials with a split hopkinson pressure bar. Exp Mech 42(1):93–106

    Article  Google Scholar 

  36. Frew DJ, Forrestal MJ, Chen W (2005) Pulse shaping techniques for testing elastic-plastic materials with a split hopkinson pressure bar. Exp Mech 45(2):186–195

    Article  Google Scholar 

  37. Kolsky H (1949) An investigation of the mechanical properties of materials at very high rates of loading. Proc Phys Soc London, Sect B 62(11):676

    Article  Google Scholar 

  38. Chen W, Song B (2010) Split Hopkinson (Kolsky) bar: design, testing and applications. Springer Science & Business Media

  39. Ramesh KT (2008) High rates and impact experiments. In: Springer handbook of experimental solid mechanics. Springer, pp 929–960

  40. Lamberson LE, Ramesh KT (2015) Spatial and temporal evolution of dynamic damage in single crystal α-quartz. Mech Mater 87:61–79

    Article  Google Scholar 

  41. Moore DE, Lockner DA, Iwata K, Tanaka H, Byerlee JD (2001) How brucite may affect the frictional properties of serpentinite. US Department of the Interior. US Geological Survey

  42. Handin J (1969) On the Coulomb-Mohr failure criterion. J Geophys Res 74(22):5343–5348

    Article  Google Scholar 

  43. Green SJ, Perkins RD et al (1968) Uniaxial compression tests at varying strain rates on three geologic materials. In: The 10th US symposium on rock mechanics (USRMS). American Rock Mechanics Association

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Acknowledgments

The authors are grateful for support of this work through the Research and Educational Programs at the Ohio Aerospace Institute through the NASA Glenn Research Center Faculty Fellowship Program in 2013, as well as the 2014 Harry C. Bartels Faculty Engineering Development Award at Drexel University.

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  1. Drexel University, Philadelphia, PA, 19106, USA

    L. Lamberson, L. Shannahan & S. Pagano

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  1. L. Lamberson
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  2. L. Shannahan
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  3. S. Pagano
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Correspondence to L. Lamberson.

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Lamberson, L., Shannahan, L. & Pagano, S. Shear Evolution of Fiberglass Composites Under Compression. Exp Mech 56, 69–80 (2016). https://doi.org/10.1007/s11340-015-0090-5

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  • DOI: https://doi.org/10.1007/s11340-015-0090-5

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