Vortex-induced vibrations of three tandem cylinders in laminar cross-flow: Vibration response and galloping mechanism

Vortex-induced vibrations (VIV) of three tandem cylinders are numerically studied using the immersed boundary method. Cylinders are free to vibrate in the cross-flow direction. The Reynolds number is Re = 100 and the reduced velocity is U-r = 3 similar to 80. Six spacing ratios are selected in the range L/D = 1.2 similar to 5.0. The mass ratio is m* = 2.0, while the damping ratio is set as zero for achieving large vibration amplitudes. The characteristics of the vibration amplitude, drag and lift forces, lift frequency, phase difference between displacement and lift, and the wake patterns are discussed. It is found that, in the case with small LID, large-amplitude vibrations of the cylinders are excited due to strong wake-cylinder interference. However, in the cases with large L/D, the vibration responses of the upstream cylinder resemble those of an isolated cylinder indicating vanishing interference from the downstream cylinders. While, the two downstream cylinders attain large vibration amplitudes even at high reduced velocities. A wake pattern, T+S, i.e. the cylinders alternately shed triple vortices and a single vortex in a vibration cycle, is observed. This wake pattern is caused by the asymmetric vibration of the cylinders and transverse dislocation of the equilibrium positions. With increasing L/D, two different vibration patterns are observed: wake-induced galloping (WG) for the small-L/D case (L/D = 1.2) and vortex-induced vibration (VIV) for the moderate-to large-L/D cases (L/D = 1.5 similar to 5.0). The major characteristic feature of WG, distinct to VIV, are the divergent vibrations of the cylinders with the increasing reduced velocity. The mechanism of WG is elucidated by analyzing the complex but stable interactions between vortices and cylinders. Three pivotal factors are identified: the 'perfect' timing between vortex-shedding and cylinder motion, the transverse dislocation of the equilibrium positions, and the low and decreasing vibration frequency. (C) 2018 Elsevier Ltd. All rights reserved.