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Finite element implementation of a steel-concrete bond law for nonlinear analysis of beam-column joints subjected to earthquake type loading

  • Fleury, F. (Civil Engineering Research Unit(URGC-Structures), National Institute of Applied Science (INSA of Lyon)) ;
  • Reynouard, J.M. (Civil Engineering Research Unit(URGC-Structures), National Institute of Applied Science (INSA of Lyon)) ;
  • Merabet, O. (Civil Engineering Research Unit(URGC-Structures), National Institute of Applied Science (INSA of Lyon))
  • Published : 1999.01.25

Abstract

Realistic steel-concrete bond/slip relationships proposed in the literature are usually uniaxial. They are based on phenomenological theories of deformation and degradation mechanisms, and various pull-out tests. These relationships are usually implemented using different analytical methods for solving the differential equations of bond along the anchored portion, for particular situations. This paper justifies the concepts, and points out the assumptions underlying the construction and use of uniaxial bond laws. A finite element implementation is proposed using 2-D membrane elements. An application example on an interior beam-column joint illustrates the possibilities of this approach.

Keywords

References

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