Effects of surface design on aerodynamic forces of iced bridge cables

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    Abstract

    In recent years the relevance of ice accretion for wind-induced vibration of structural bridge cables has been recognised and became a subject of research in bridge engineering. Full-scale monitoring and observation indicate that light precipitation at moderate low temperatures between zero and -5°C may lead to large amplitude vibrations of bridge cables under wind action. For the prediction of aerodynamic instability quasi-steady models have been developed estimating the cable response magnitude based on structural properties and aerodynamic force coefficients for drag, lift and torsion. The determination of these force coefficients require a proper simulation of the ice layer occurring under the specific climatic conditions, favouring real ice accretion over simplified artificial reproduction. The work presented in this paper was performed to study whether the design of bridge cable surface influences the accretion of ice to an extent that the aerodynamic forces differ significantly amongst the designs. The experiments were conducted in a wind tunnel facility capable amongst others to simulate in-cloud icing conditions.
    Original languageEnglish
    Title of host publicationProceedings of the Symposium on the Dynamics and Aerodynamics of cables
    Number of pages8
    Publication date2014
    Publication statusPublished - 2014
    EventSymposium on the Dynamics and Aerodynamics of cables - Technical University of Denmark, Kgs. Lyngby, Denmark
    Duration: 25 Sept 201426 Sept 2014

    Conference

    ConferenceSymposium on the Dynamics and Aerodynamics of cables
    LocationTechnical University of Denmark
    Country/TerritoryDenmark
    CityKgs. Lyngby
    Period25/09/201426/09/2014

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