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Investigation of bond behavior between lightweight aggregate concrete and steel rebar using bending test

  • Arslan, Mehmet Emin (Department of Civil Engineering, Karadeniz Technical University) ;
  • Durmus, Ahmet (Department of Civil Engineering, Karadeniz Technical University)
  • Received : 2010.03.03
  • Accepted : 2010.10.14
  • Published : 2011.08.25

Abstract

This paper investigates bond behavior of structural lightweight concrete (SLWC) and ordinary concrete (OC) comparatively using bending test called Standard Belgium Hinged Beam Test (SBHBT). For this purpose the experiments were carried out as three series on 36 beam specimens (12 specimens of SLWC and OC with $20{\phi}$ development length, 12 specimens of SLWC with $25{\phi}$ development length). For each series bond behavior of steel rebars with 8, 10, 12, 14 mm diameters were tested. The results indicate that bond strength of SLWC is considerable lower than OC and $20{\phi}$ development length is insufficient for steel rebars with 12 mm and 14 mm diameters. Therefore development length of SLWC was extended to $25{\phi}$, even if 8 and 10 mm steel rebars provided acceptable bond strength. In this way, bond strength between SLWC and 8 and 10 mm steel rebars was developed. In addition, adequate bond behavior was achieved for 12 mm rebar but the beam in which 14 mm rebar used exceeded their bearing capacity by shear forces before yield stress. This result shows that SBHBT is more convenient for small sized steel rebars.

Keywords

References

  1. ACI 318-05 (2005), Building code requirements for structural concrete and commentary, ACI/2005.
  2. Arda, T.S. (1968), Compilation about bond behavior in reinforced concrete, First Edition, I.T.U., Istanbul.
  3. Arslan, M.E. (2007), Investigation of bond strength of structural lightweight concrete and ordinary concrete comparatively in bending, MSc Thesis, Karadeniz Technical University.
  4. Babu, K.G. and Babu, D.S. (1989), "Behavior of lightweight expanded polystyrene concrete containing silica fume", Cement Concrete Res., 33, 755-762.
  5. Campione, G. and Mendola, L.L. (2004), "Behavior in compression of lightweight fiber reinforced concrete confined with transverse steel reinforcement", Cement Concrete Comp., 26, 645-656. https://doi.org/10.1016/S0958-9465(03)00047-7
  6. Chi, J.M., Huang, R., Yang, C.C. and Chang, J.J. (2003), "Effect of aggregate properties on the strength and stiffness of lightweight concrete", Cement Concrete Comp., 25, 197-205. https://doi.org/10.1016/S0958-9465(02)00020-3
  7. Dahil, H.A. (2001), Comparative study of bond strength between steel rebars and high performance and ordinary concrete, MSc Thesis, Karadeniz Technical University.
  8. Dominguez, N., Fernandez, M.A. and Ibrahimbegovic, A. (2010). "Enhanced solid element for modeling of reinforced concrete structures with bond-slip", Comput. Concrete, 7(4), 347-364. https://doi.org/10.12989/cac.2010.7.4.347
  9. Ersoy, U. and Ozcebe, G. (2001), Reinforced concrete: basic principles and designing according to TS-500-2000 and Turkey's earthquake resistant design code (1998), Expanded New Edition, Evrim Publishing.
  10. Ferguson, P.M. (1965), Reinforced concrete fundamentals, Second Edition, John Wiley and Sons.
  11. Husem, M. (1995), Investigation of lightweight aggregate concrete produced with aggregate of blacksea region and ordinary concrete comparatively, Ph.D. Thesis, Karadeniz Technical University.
  12. Husem, M. and Durmu , A. (1993), "Lightweight aggregate concretes produced with aggregates of blacksea region", Advances in Civil Engineering, First Technical Congress, Book of Proclamation, Gazi Magusa-KKTC, 580-589.
  13. Husem, M. and Durmu , A. (1995), "Investigation of bond strength of lightweight aggregate concrete and ordinary concrete comparatively", Turkey Civil Engineering XIII, Technical Congress, Istanbul, 341-354.
  14. Ichinose, T., Kanayama, Y., Inoue, Y. and Bolander, J.E. (2004), "Size effect on bond strength of deformed bars", Constr. Build. Mater., 18, 549-558. https://doi.org/10.1016/j.conbuildmat.2004.03.014
  15. Juang, J.L. and Hsu, H.L. (2006), "Bond mechanism effect on the flexural behavior of steel reinforced concrete composite members", Steel Comp. Struct., 6(5), 387-400. https://doi.org/10.12989/scs.2006.6.5.387
  16. Kayali, O., Haque, M.N. and Zhu, B. (2003), "Some characteristics of high strength fiber reinforced lightweight aggregate concrete", Cement Concrete Comp., 25, 207-213. https://doi.org/10.1016/S0958-9465(02)00016-1
  17. Kilic, A., Atis, C.D., Yasar, E. and Ozcan, F. (2003), "High-strength lightweight concrete made with scoria aggregate containing mineral admixtures", Cement Concrete Res., 33, 1595-1599. https://doi.org/10.1016/S0008-8846(03)00131-5
  18. Shang, F., An, X., Kawai, S. and Mishima, T. (2010), "Open-slip coupled model for simulating three-dimensional bond behavior of reinforcing bars in concrete", Comput. Concrete, 7(5), 403-419. https://doi.org/10.12989/cac.2010.7.5.403
  19. Yeih, W., Chang, J.J. and Tsai, C.L. (2004), "Enhancement of the bond strength of epoxy coated steel by the addition of fly ash", Cement Concrete Comp., 26, 315-321. https://doi.org/10.1016/S0958-9465(02)00142-7

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