Abstract
Stockbridge dampers are widely used to mitigate the vortex-induced vibrations of overhead electrical line conductors and of many other cable or cable-like structures exposed to the action of wind. Aim of this work is to develop a simple, but accurate, mechanical model of a Stockbridge damper to use in the assessment of such structures vibrations. The model is based on a beam-like description of the messenger cable and on a nonlinear formulation of the cross sections cyclic bending behaviour. At the cross-sectional level, the mechanical behaviour of the messenger cable is reproduced with the classic Bouc-Wen hysteretic model, which has been recognized as adequate to represent the local behaviour mainly controlled by interwire sliding processes. The Bouc-Wen model parameters are identified from experimental results available in literature and used at the local (cross-sectional) level to characterize the mechanical behaviour of the messenger cable. The descending global behaviour of the Stockbridge damper compares very favourably with the experimental results in terms of the impedance function at the clamp and allows for the confident use of the proposed model inside the assessing process of full power lines. The important role of the end zones of the messenger cable is highlighted. In these zones, a boundary layer like transition is found to occur for the bending stiffness of the messenger cable cross section. This largely affects the global behaviour of the Stockbridge damper. The length of these zones complements the model parameters.
Highlights
Stockbridge dampers are widely used to mitigate the vortexinduced vibrations of overhead electrical line conductors [1,2,3,4,5], stay cables [6], and many other cable or cable-like structures exposed to the action of wind, such as the counterweight tension bars of cranes [7].Invented by Stockbridge in 1925 [8] and subsequently modified by many other researchers, these dampers are cheap, reliable, and easy to install
At the cross-sectional level, the mechanical behaviour of the messenger cable is reproduced with the classic Bouc-Wen hysteretic model, which has been recognized as adequate to represent the local behaviour mainly controlled by interwire sliding processes
The Bouc-Wen model parameters are identified from experimental results available in literature and used at the local level to characterize the mechanical behaviour of the messenger cable
Summary
Stockbridge dampers are widely used to mitigate the vortexinduced vibrations of overhead electrical line conductors [1,2,3,4,5], stay cables [6], and many other cable or cable-like structures exposed to the action of wind, such as the counterweight tension bars of cranes [7]. Nonlinear models based on finite element beam elements have been adopted by Langlois and Legeron [14] and Barbieri et al [20, 21] In both cases, phenomenological hysteretic models are adopted and the constitutive parameters are identified from the results of static or dynamic experimental tests. The 3D finite element approach allows introducing a detailed model for the local contact conditions between the wires of the messenger cables as well as between the clamp and the messenger cable, allowing appreciating how these complex local phenomena play a key role in the determination of the overall dynamic characteristics of the Stockbridge damper In spite of their possible accuracy, full-scale nonlinear 3D finite element models are challenging to setup and require a very careful calibration, especially when in presence of many nonlinear contact interfaces.
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