Exact dynamic analysis of multi-segment cable systems

Cable-supported structure is a common system widely used in engineering, with the rapid development of the infrastructure and transportation industry, its structural form has become more and more complicated. Multi-segment cable system, which consists of a suspension cable and several lateral supports, such as the cable-damper system, the main cable of a suspension bridge, etc., is one of the important cable support systems. Due to the low structural rigidity and damping, its dynamic problems have always been the focus of engineering. To obtain a more general conclusion, a unified dynamic model considering the effect of cable sag, additional cable force, flexural stiffness, and the support stiffness of lateral components are considered in this paper for the first time. However, the exact analysis of this model is difficult, in view of this, the dynamic stiffness method is employed in this paper to investigate the dynamic characteristic of the multi-segment cable system. The accuracy of the proposed method is verified by comparing with finite element solutions and experimental results. Results show that the position of lateral supports has a strong coupling effect and influence the lower-order mode more significantly than higher-order modes, and the maximum frequency value can be reached by installing the supports equidistantly. (C) 2020 Elsevier Ltd. All rights reserved.

Automated summary

This study proposed a unified dynamic model considering factors such as cable sag, additional cable force, flexural stiffness, and support stiffness of lateral components for the first time, and used the dynamic stiffness method to investigate the dynamic characteristics of the multi-segment cable system. Results show that the position of lateral supports has a significant impact on the modes, and installing the supports equidistantly can achieve the maximum frequency value.