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Recent topics on bridge aerodynamics

  • Matsumoto, Masaru (Department of Global Environment Engineering, Kyoto University) ;
  • Shirato, Hiromichi (Department of Global Environment Engineering, Kyoto University) ;
  • Yagi, Tomomi (Department of Global Environment Engineering, Kyoto University)
  • Published : 2000.12.25

Abstract

This paper aims to describe the aerodynamic vibrations of various structural elements of bridges, which are particular issues at present. The aerodynamic countermeasures for those vibrations are also discussed considering the generation mechanisms of the aerodynamic instabilities. In this paper, an example of vortex-induced oscillation of bridge deck and its lesson are discussed. Next, the wind-induced cable vibration and its aerodynamic countermeasures are reviewed. Then, the aerodynamic characteristics on two edge girders and their feasibility for application to long span cable-stayed bridges are considered. Furthermore, the bridge decks for future long span bridges are proposed and their aerodynamic characteristics are also discussed.

Keywords

References

  1. An article (1995), "Bridge girder vibration under 16 m/s wind proved the necessity of TMD device for vortex induced oscillation", Nikkei Construction, 28, April, 1995, 38-39 (in Japanese).
  2. Diana, G. (1993), "Analytical and wind-tunnel simulations for the aeroelastic design of the Messina Straits Bridge", Proceedings of the International Seminar on Utilization of Large Boundary Layer Wind Tunnel, Tsukuba, Japan, 183-202.
  3. Matsumoto, M., Shiraishi, N., Shirato, H., Hirai, S., Sano, Y. and Katsura, K. (1990), "On response characteristics of rain vibration of cables and effect of turbulence and Scruton number", Proceedings of the 11th National Symposium on Wind Engineering, 269-274 (in Japanese).
  4. Matsumoto. M, Yabutani, T. and Yoshizumi, F. (1996), "Aerodynamic derivatives and flutter property of modified-rhombus section", Proceedings of the 14th National Symposium on Wind Engineering, 305-310 (in Japanese).
  5. Matsumoto, M. (1998), "Observed behavior of prototype cable vibration and its generation mechanism", Bridge Aerodynamics, A. Larsen and S. Esdahl (eds.), Balkema, 189-211.
  6. Matsumoto, M., Yagi, T., Tsushima, D. and Shigemura, Y. (1999), "Vortex-induced vibration of inclined cables at high wind velocity", Wind Engineering into the 21st Century, Proceedings of the 10th International Conference on Wind Engineering, Copenhagen, Denmark, 979-986.
  7. Matsumoto, M., Daito, Y., Shirato, H., Yagi, T. (1999), "Aerodynamic characteristics of two edge girders", Proceedings of the Seventh East Asia-Pacific Conference on Structural Engineering & Construction, Kochi, Japan, 675-680.
  8. Matsumoto, M., Taniwaki, Y., Abe, K., Nakajima, N. (2000), "Flutter characteristics of 2-box girders for superlong span bridges", Flow-Induced Vibration, Proceedings of the 7th International Conference on Flow-Induced Vibration, Lucerne, Switzerland, S. Ziada and T. Staubli (eds.), 157-164.
  9. Owen, J.S., Vann, A.M. and Davis, J.P. (1994), "The Prototype testing of Kessock Bridge : response to vortex shedding", Proceedings of 2nd UK Conference on Wind Engineering, Warwick, UK.

Cited by

  1. Wind-induced characteristics of two-edge girders for the bending degree-of-freedom vol.9, pp.6, 2005, https://doi.org/10.1007/BF02831486
  2. On the wind loading mechanism of long-span bridge deck box sections vol.91, pp.12-15, 2003, https://doi.org/10.1016/j.jweia.2003.09.011
  3. ON THE AEROELASTIC BEHAVIOUR OF RECTANGULAR CYLINDERS IN CROSS-FLOW vol.16, pp.7, 2000, https://doi.org/10.1006/jfls.2002.0452
  4. Effect of beam slope on the static aerodynamic response of edge-girder bridge-deck vol.25, pp.2, 2000, https://doi.org/10.12989/was.2017.25.2.157
  5. Static Wind Load Evaluation under Steady-State Wind Flow for 2-Edge Sloped Box Girder by Using Wind Tunnel Test vol.2019, pp.None, 2000, https://doi.org/10.1155/2019/9397527
  6. Aerodynamic Characteristics Evaluation of a Cable-Stayed Bridge Section with a New-Type Hybrid Fairing vol.2021, pp.None, 2021, https://doi.org/10.1155/2021/8899558