Journal of Korean Association for Spatial Structures (한국공간구조학회논문집)

Korean Association for Spatial Structures (한국공간구조학회)
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Mechanical Behavior of Cable Net Structures Considering Sag Ratio

새그 비를 고려한 케이블 네트 구조물의 역학적 거동

  • Received : 2016.04.27
  • Accepted : 2016.06.10
  • Published : 2016.09.15
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Abstract

Cable network system is a flexible lightweight structure which curved cables can transmit only tensile forces. The weight of cable roof dramatically can reduce when the length becomes large. The cable network system is too flexible, most cable systems are stabilized by pretension forces. The tensile force of cable system is greatly influenced by the sag ratio and pretension forces. Determining initial sag ratio of cable roof system is essential in a design process of cable structures. Final sag ratio and pretension depends on initial installed sag and on proper handling during installation. The design shape of cable system has an affect on the sag and pretension, and must be determined using well-defined design philosophy. This paper is carried out the comparative data of the deflection and tensile forces on the geometric non-linear analysis of cable network systems according to sag ratio. The study of cable network system is provided to technical informations for the design of a large span cable roof, analytical results are compared with the results of other researchers. Structural nonlinear analysis of systems having cable elements is relatively complex than other rigid structural systems because displacements are large as a reason of flexibility, initial prestress is applied to cables in order to increase the rigidity, and then divergence of nonlinear analysis occurs rather frequently. Therefore, cable network systems do not exhibit a typical nonlinear behavior, iterative method that can handle geometric nonlinearities are necessary.

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References

  1. Ayhan Nuhoglu, "Nonlinear analysis of cable systems with point based iterative procedure," Scientific Research and Essays, vol 6, pp.1186-1199, 2011
  2. H.B. Jayaraman, W.C. Knudson, "A curved element for the analysis of cable structures," Computer Structures 14, pp.325-333, 1981 https://doi.org/10.1016/0045-7949(81)90016-X
  3. C. H. Thornton and C. Brinstiel, "Three-Dimensional Suspension Structure," ASCE J. Structure Div. 93, 247-270, 1967
  4. West HH, Kar AK, "Discretized initial value analysis of cable nets," International Journal of Solids Structures, pp.247-270, 1970
  5. G. Tibert, "Numerical Analyses of Cable Roof Structures," KTH, 1999
  6. A. Andreu, L. Gil, P. Roca, "A new deformable catenary element for the analysis of cable net structures," Computer Structure 84, pp.1882-1890, 2006 https://doi.org/10.1016/j.compstruc.2006.08.021
  7. W.T. O'Brien, A.J. Francis, "Cable movements under two-dimensional loads," Journal of Structural Division ASCE 90, pp.89-124, 1964
  8. Desai YM, Popplewell A, Shan AH, Buragohain DN, " Geometric nonlinear static analysis of cable supported structures, Computer Structures 29, pp.1001-1009, 1988 https://doi.org/10.1016/0045-7949(88)90326-4
  9. Ever Coarita and Leonardo Flores, "Nonlinear Analysis of Structures Cable-Truss," International Journal of Engineering and technology, vol. 7, pp.160-169, 2015 https://doi.org/10.7763/IJET.2015.V7.786
  10. T. Huu and K. Seung, "Nonlinear static and dynamic of cable structures," Finite Elements in Analysis and Design, vol.47, pp.237-246, 2011 https://doi.org/10.1016/j.finel.2010.10.005
  11. W. Ren, M. Huang, and W. Hu, "A parabolic cable element for static analysis of cable structures," International Journal for Computer Aided Engineering and Software vol.84, pp.1182-1890, 2006
  12. A. Andreu, L. Gil and P.Roca, " A new deformable catenary element for the analysis of cable net structures," Computer and Structures, vol.84, pp.1182-1890, 2006
  13. A. Kwan, "A new approach to geometric nonlinearity of cable structures," Computer and Structures, vol.67, pp.243-352, 1988
  14. Saafan AS, "Theoretical analysis of suspension roofs," Journal of the Structural Division ASCE, pp.393-405
  15. NISA Program, Crane Software, 2015
  16. Design Standard of Cable Structures, Korean Association for Spatial Structures, 2009
  17. Design Standard of Membrane Structures, Korean Association for Spatial Structures, 2010
  18. K.G. Park, S.K Yoon, "Test on the Mechanical Characteristics of Grass Fiber Membrane," Korean Association for Spatial Structures, pp.7-12, 2008

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