Numerical Simulation of Galloping for Iced Quad-Bundled Conductor

Jun Jie Shi; Ya Nan Li; Li Qin

doi:10.4028/www.scientific.net/AMR.1025-1026.955

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 1025-1026Numerical Simulation of Galloping for Iced...

Numerical Simulation of Galloping for Iced Quad-Bundled Conductor

Abstract:

The theoretical study of galloping can effectively promote anti-galloping techniques. Cable element is utilized to imitate the bundled conductor, and beam elements are used to simulated the spacers, established galloping finite element analysis model which can consider sub-conductors wake interference. The finite element equation was solved by time integration method and the calculation program was compiled by MATLAB. Through numerical simulation analysis, compared the dancing in the case of considering the effect of the sub-conductor wake and ignoring the effect of the sub-conductor wake. The results showed that considering the effect of the wake on aerodynamic loads has a greater vertical vibration amplitude. This method can provide reference for the study of prevention technology on dancing.