Title :
Numerical Simulation for Galloping of Iced Quad-Bundled Conductor under Stochastic Wind Load
Author :
Liu, Xiaohui ; Yan, Bo ; Zhang, Hongyan ; Zhou, Song ; Luo, Hui ; Zhong, Lijun
Author_Institution :
Dept. of Eng. Mech., Chongqing Univ., Chongqing, China
Abstract :
The galloping of iced quad-bundled conductor under the action of stochastic wind load is investigated. A three-node cable element with three translational and one torsional degrees-of-freedom at each node is employed to discretize the bundled conductor and the two-node Euler-Bernoulli beam elements are used to simulate the spacers. With the Kaimal spectrum and the Davenport mutual spectrum, the samples of stochastic wind are numerically simulated by means of the WAWS. The finite element equation is solved by the Newmark time integration method and the Newton-Raphson nonlinear iteration strategy. The numerical results indicate that the galloping amplitude of iced quad-bundled conductor under stochastic wind load is larger than that as wind is simplified as steady.
Keywords :
Newton-Raphson method; conductors (electric); finite element analysis; iterative methods; overhead line mechanical characteristics; power transmission lines; Davenport mutual spectrum; Kaimal spectrum; Newmark time integration method; Newton-Raphson nonlinear iteration strategy; WAWS; degrees-of-freedom; finite element equation; galloping amplitude; iced quad-bundled conductor galloping; numerical simulation; stochastic wind load; three-node cable element; two-node Euler-Bernoulli beam elements; Aerodynamics; Conductors; Nonlinear equations; Numerical simulation; Power cables; Power engineering and energy; Power transmission lines; Stochastic processes; Transmission line matrix methods; Transmission line theory;
Conference_Titel :
Power and Energy Engineering Conference (APPEEC), 2010 Asia-Pacific
Conference_Location :
Chengdu
Print_ISBN :
978-1-4244-4812-8
Electronic_ISBN :
978-1-4244-4813-5
DOI :
10.1109/APPEEC.2010.5449014
