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Effect of base isolation on the seismic response of multi-column bridges

  • Saiidi, M. (Civil Engineering Department, University of Nevada) ;
  • Maragakis, E. (Civil Engineering Department, University of Nevada) ;
  • Griffin, G. (Exeltech Engineering)
  • Published : 1999.10.25

Abstract

A nonlinear model for time-step analysis of bridges subjected to two orthogonal horizontal components of earthquake motions was developed. The focus of the study was on elastomeric isolators with or without lead cores. The hysteretic behavior of the isolators, the columns, abutments, and shear keys was taken into account. The nonlinear analysis showed that, contrary to linear theory prediction, the use of isolators does not necessarily increase the displacement of the superstructure. Furthermore, it was shown that properly designed isolators can reduce the ductility demand in RC bridge columns substantially.

Keywords

References

  1. Blakely, R.W.G. (1982), "Application of base isolation to seismic resistant bridges", Comparison of United States and New Zealand Practices for Highway Bridges, ATC-12, August, 77-82.
  2. Bouc, R. (1971), "Modele Mathematique d'hysteresis" , Acoustica, 24, 16-24.
  3. Buckle, I.G. and Mayes, R.L. (1989), "The application of seismic isolation to bridges", Seismic Engineering: Research and Practice, Proceedings of Structures Congress, 633-642.
  4. Fenves, G., Whittaker, A., Huang, W.-H., Clark, P. and Mahin, S. (1998), "Analytical and testing of seismically isolated bridges under bi-axial excitation", The 5th Caltrans Seismic Research Workshop, Session 6, Sacramento, California, June.
  5. Foutch, D. and Chen, K.-H. (1994), "Optimal design strategies for base-isolated bridges" , Proceedings of the Tenth US-Japan Bridge Engineering Workshop, Lake Tahoe, Nevada, Session ix, May.
  6. Griffin, G., Saiidi, M. and Maragakis, E. (1995), "Nonlinear seismic response analysis of isolated bridges with multiple columns", Civil Engineering Department, Report No. CCEER-95-6, University of Nevada, Reno, November.
  7. Jiang, Y. and Saiidi, M. (1990), "4-spring element for cyclic response of R/C columns", Journal of Structural Engineering, ASCE, 116(4), April, 1018-1029. https://doi.org/10.1061/(ASCE)0733-9445(1990)116:4(1018)
  8. Saiidi, M. (1982), "Hysteresis models for reinforced concrete" , Journal of the Structural Division, ASCE, 108(ST5), May, 1077-1085.
  9. Sultan, M., Sheng, L.-H. and Onesto, A. (1998), "Summary of FHWA/CALTRANS/HITEC seismic isolator and energy dissipator evaluation program for highway bridges", The 5th Caltrans Seismic Research Workshop, Session 6, Sacramento, California, June.
  10. Wen, Y. (1980), "Equivalent linearization for hysteretic systems under random excitation" , Journal of Applied Mechanics, 47, March, 150-154. https://doi.org/10.1115/1.3153594

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