- 作者:A. Acampora ; J.H.G. Macdonald ; C.T. Georgakis ; N. Nikitas
- 关键词:Twin cable ; Cable vibrations ; Dry inclined cable galloping ; Cable aerodynamics ; System identification ; Ambient vibrations ; Full-scale measurements ; Aerodynamic damping ; Critical Reynolds number ; Quasi-steady theory
- 刊名:Journal of Wind Engineering and Industrial Aerodynamics
- 出版年:January, 2014
- 年:2014
- 卷:124
- 期:Complete
- 页码:90-98
- 全文大小:1444 K
This paper presents results from full-scale measurements on the special arrangement of twin cables adopted for the 脴resund Bridge. The monitoring system records wind and weather conditions, as well as accelerations of certain cables and a few locations on the deck and tower. Using the Eigenvalue Realization Algorithm (ERA), the damping and stiffness matrices are identified for different vibration modes of the cables, with sufficient accuracy to identify changes in the total effective damping and stiffness matrices due to the aeroelastic forces acting on the cables. The damping matrices identified from the full-scale measurements are compared with the theoretical damping matrices based on the quasi-steady theory, using three different sets of wind tunnel measurements of static force coefficients on similar shaped twin or single cables, with good agreement. The damping terms are found to be dependent on Reynolds number rather than reduced velocity, indicating that Reynolds number governs the aeroelastic effects in these conditions. There is a significant drop in the aerodynamic damping in the critical Reynolds number range, which is believed to be related to the large amplitude cable vibrations observed on some bridges in dry conditions.
Finally, static drag coefficients are back-calculated from the full-scale vibration measurements, for first time, with reasonable agreement with direct wind tunnel measurements. The remaining discrepancies are believed to be due to the higher turbulence intensity on site than in the wind tunnel.