振动
非线性系统
圆柱
涡激振动
分叉
涡流
物理
消散
旋涡脱落
机械
边值问题
霍普夫分叉
能量(信号处理)
范德波尔振荡器
数学分析
振幅
鞍结分岔
控制理论(社会学)
边界(拓扑)
边界层
振动控制
唤醒
联轴节(管道)
刚度
不变(物理)
遗传算法
机械能
数学
作者
Wenxi Zhang,Zhongjun Yin,Hang Guo,Bing Chen
标识
DOI:10.1142/s0219455427500647
摘要
In this paper, the suppression of vortex-induced vibration (VIV) of a cylinder by a nonlinear energy sink (NES) with optimized parameters is investigated. The NES system integrates the auxiliary mass, linear damping, and nonlinear stiffness components and uses the van der Pol wake oscillator to simulate the dynamic characteristics of vortex shedding. The main research contents are as follows: (1) The dynamic equation of the fluid–cylinder–NES coupling system is derived, and the influence of NES parameters on the vibration suppression performance is studied. The slow flow equation is established by using the complexification-averaging (CXA) method. (2) The saddle-node (SN) bifurcation boundary and Hopf bifurcation boundary are derived. The influence of NES parameters on the bifurcation boundary and the influence of bifurcation on the vibration response arestudied. (3) The multiple scales method is used to analyze the slow invariant manifold (SIM), and the necessary conditions for the strongly modulated response (SMR) are derived based on SIM. (4) Aiming to maximize vibration suppression efficiency, a genetic algorithm optimization scheme based on the SMR existence criterion constraint is developed. The results show that the optimization method not only reduces the vibration amplitude of the cylinder by 71.94% but also achieves a continuous SMR response in the ‘lock-in’ interval, which effectively promotes the energy transfer from the cylinder to the NES and improves the energy dissipation efficiency of the system.
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