Multi-modal vortex- and rain–wind- induced vibrations of an inclined flexible cable.

Highlights • The first, second and third mode VIVs of a flexible cable model are reproduced and the frequency lock-in phenomenon is observed for different modes of VIVs. • It is feasible to reproduce multi-mode RWIVs of a flexible cable in a wind tunnel. • Water rivulets on the cable surface excite RWIVs, and higher-mode RWIVs develop at higher wind speeds. • Local distributions of upper rivulet water flow excite multi-mode RWIVs. • RWIVs and VIVs may have causal links. Abstract We reproduce multi-modal vortex-induced vibrations (VIVs) and multi-modal rain–wind-induced vibrations (RWIVs) of an inclined and yawed cable in wind tunnel tests. The flexible cable model has low mass and low damping. First, the cable model is kept dry and exposed to uniform airflow; it experiences first-, second- and third-mode VIVs with the increase of wind speed. The structural responses of VIVs are analysed and the frequency lock-in phenomenon is observed for different modes of VIVs of the flexible cable. In addition to VIVs of the dry cable, RWIVs are excited by guiding water rivulets on the cable surface from a water tube. The first-, second- and third-mode RWIVs of the flexible cable are observed and identified at a much higher range of incoming wind speeds than that of the VIVs. To further explore the origin of the multi-modal behaviours of RWIVs, the upper rivulet is guided and restricted to form locally along the cable. Experimental results reveal that the higher- and multiple-mode RWIVs can be excited by a local rivulet, even under a lower wind speed. Finally, RWIVs are compared to VIVs to uncover their underlying similarities and relationships. [ABSTRACT FROM AUTHOR]