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Influence of loading condition and reinforcement size on the concrete/reinforcement bond strength

  • Turk, Kazim (Department of Civil Engineering, Engineering Faculty, Firat University) ;
  • Caliskan, Sinan (Division of Civil Engineering, Faculty of Engineering and Physical Sciences, University of Dundee) ;
  • Sukru Yildirim, M. (Department of Civil Engineering, Corlu Engineering Faculty, Trakya University)
  • Received : 2004.05.11
  • Accepted : 2004.09.16
  • Published : 2005.02.20

Abstract

The paper reports on a study of bond strength between reduced-water-content concrete and tensile reinforcement in spliced mode. Three different diameters (12, 16 and 22 mm) of tensile steel were spliced in the constant moment zone, where there were two bars of same size in tension. For each diameter of reinforcement, a total of nine beams ($1900{\times}270{\times}180mm$) were tested, of which three beams were with no axial force (positive bending) and the other six beams were with axial force (combined bending). The splice length was selected so that bars would fail in bond, splitting the concrete cover in the splice region, before reaching the yield point. It was found that there was a considerable size effect in the experimental results, i.e., as the diameter of the reinforcement reduced the bond strength and the deflection recorded at the midspan increased significantly, whilst the stiffness of the beams reduced. It was also found for all reinforcement sizes that higher bond strength and stiffness were obtained for beams tested in combined bending than that of the beams tested in positive bending only.

Keywords

References

  1. Chaallal, O. and Benmokrane, B. (1993), 'Pullout and bond of glass-fiber rods embedded in concretes and cement grout', RILEM Materials Structure J., 26(157),167-175 https://doi.org/10.1007/BF02472934
  2. Darwin, D., Zuo, J., Tholen, M.L. and Idun, E.K. (1996), 'Development length criteria for conventional and high relative rib area reinforcing bars', ACI Struct. J. 93(3), 347-359
  3. De Larrard, F., Scahaller, I. and Fuchs, J. (1993), 'Effect of bar diameter on the bond strength of passive reinforcement in high-performance concrete', ACI Materials J., 90(4), 333-339
  4. Esfahani, M.R. and Rangan, B.V. (1998), 'Bond between normal strength and high-strength concrete and reinforcing bars in splices in beams', ACI Struct. J., 95(3),272-280
  5. Gambarova, G.P. and Giuriani, E. (1985), Discussion of 'Fracture mechanics of bond in reinforced concrete' by lngraffea, A.R., Gerstle, W.H., Gergely, P. and Saouma, V., J. Struct. Eng., ASCE, 115(5), 1161-1163
  6. Giovanni, A.P., Egidio, M. and Ezio, G. (1996), 'Experimental study of splitting and flexural cracks in a RC beam with overlapped splices', Materials and Structures, 29, 19-27 https://doi.org/10.1007/BF02486003
  7. Giuriani, E. (1981), 'Experimental investigation on the bond-slip law of deformed bars in concrete', Advanced Mechanics of Reinforced Concrete, Delft, The Netherlands, 121-242
  8. Hamad, B.S. and Mansour, M.Y. (1996), 'Bond strength of noncontact tension lap splices', ACI Struct. J., 93(3), 316-326
  9. Orangun, C.O., Jirsa, J.O. and Breen, J.E. (1975), 'Strength of anchored bars: A re-evaluation of test data on development length and splices', Center of Highway Research, University of Texas at Austin, Research report 154-3F
  10. Orangun, C.O., Jirsa, J.O. and Breen, J.E. (1977), 'A reevaluation of test data on development length and splices', ACI J., 74(11), 114-122
  11. Tassio, T.P. and Koroneos, E.G. (1984), 'Local bond-slip by means of the Morie method', Proc., American Concrete Institute J., 81(4), 27-34
  12. Tepfers, R. (1973), 'A theory of bond applied to overlapped tensile reinforcement splices for deformed bars', Division of Concrete Structures, Chalmers University of Technology, Gothenburg, Publication No. 73 :2, 328
  13. Tepfers, R. (1979), 'Cracking of concrete cover along anchored deformed reinforcing bars', Magazine of Concrete Research, 31(106), 3-12 https://doi.org/10.1680/macr.1979.31.106.3
  14. Tighiouart, B., Benmokrane, B. and Gao, D. (1998), 'Investigation of bond in concrete member with fiber reinfoced polymer (FRP) bars', Construction Building Materials J., 12, 453-462 https://doi.org/10.1016/S0950-0618(98)00027-0
  15. Turk, K. and Yi1dirim, M.S. (2003), 'Bond strength of reinforcement in splices in beams', Struct. Eng. Mech., 16(4),469-478 https://doi.org/10.12989/sem.2003.16.4.469

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