0
  • DE
  • EN
  • FR
  • Base de données et galerie internationale d'ouvrages d'art et du génie civil

Publicité

Nonlinear buffeting response of long suspension bridges considering parametric excitation due to large-scale turbulence

 Nonlinear buffeting response of long suspension bridges considering parametric excitation due to large-scale turbulence
Auteur(s): , ,
Présenté pendant IABSE Symposium: Long Span Bridges, Istanbul, Turkey, 26-28 April 2023, publié dans , pp. 351-358
DOI: 10.2749/istanbul.2023.0351
Prix: € 25,00 incl. TVA pour document PDF  
AJOUTER AU PANIER
Télécharger l'aperçu (fichier PDF) 0.56 MB

The accurate modelling of self-excited forces for long-span suspension bridges is known to be very important for both the assessment of the flutter stability and the calculation of the buffeting re...
Lire plus

Détails bibliographiques

Auteur(s): (CRIACIV/Department of Civil and Environmental Engineering/University of Florence Florence, Italy)
(Department of Structural Engineering/Norwegian University of Science and Technology Trondheim, Norway)
(CRIACIV/Department of Civil and Environmental Engineering/University of Florence Florence, Italy)
Médium: papier de conférence
Langue(s): anglais
Conférence: IABSE Symposium: Long Span Bridges, Istanbul, Turkey, 26-28 April 2023
Publié dans:
Page(s): 351-358 Nombre total de pages (du PDF): 8
Page(s): 351-358
Nombre total de pages (du PDF): 8
Année: 2023
DOI: 10.2749/istanbul.2023.0351
Abstrait:

The accurate modelling of self-excited forces for long-span suspension bridges is known to be very important for both the assessment of the flutter stability and the calculation of the buffeting response to turbulent wind. It has also been proved that self-excited forces often parametrically depend on variations of the angle of attack, which can easily be induced by large-scale turbulence. A nonlinear buffeting model is outlined here to explore this issue, emphasising the influence of nonlinear turbulence effects on the stresses in the main structural elements and not only on displacements and accelerations of the bridge deck. The proposed approach is based on the 2D Rational Function Approximation model for self-excited forces, recently developed and experimentally validated by the authors. Despite the complexity of the problem, this model only slightly changes the dynamic equations based on the linearised theory, making it friendly to be implemented. The Hardanger Bridge, in Norway, is chosen as a case study, as its aerodynamic derivatives strongly depend on the angle of attack. The contribution of the wind load to the internal forces in the main cables and in the hangers is found to be only marginal. In contrast, the stresses induced in the deck girder are large, and the results for high wind speed emphasise the strong impact on the torsional moment of the modulation of the self-excited forces due to the spatio-temporal fluctuation of the angle of attack produced by low-frequency turbulence.

Ouvrages et projets