振动冲击非线性能量汇多参数的协同效应

Petro Lizunov, Olga Pogorelova, Tetiana Postnikov
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摘要

本文研究了单面振动冲击非线性能量槽(ssvi NES)阻尼器的动力学和效率随激振力参数的变化规律。阻尼器与一个线性振荡器耦合,这是主要结构。结果表明,阻尼器在较宽的激振力幅值范围内和激振频率范围内都是有效的,激振力幅值范围大于谐振频率;阻尼器在这些区域的效率是相当稳定的。“主结构- ssvi系统”的振动冲击系统动力学丰富而复杂,但这并不影响阻尼器的效率。在复杂的振荡状态下,阻尼器产生双边冲击:它既撞击障碍物,又直接撞击主结构,这实际上将单面NES变成了双面NES。阻尼器的优化过程和最佳参数的选择在阻尼器设计中起着非常重要的作用。优化多个阻尼器参数而不是三个,显示出协同效应,效果更好。
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The synergistic effect of the multiple parameters of vibro-impact nonlinear energy sink
This article studies the dynamics and efficiency of a vibro-impact damper (single-sided vibro-impact nonlinear energy sink—SSVI NES) depending on the exciting force parameters. The damper is coupled with a linear oscillator—the primary structure. It is shown that the damper is quite effective in a wide range of the exciting force amplitude and in the range of its frequency, which are higher than the resonant frequency; damper efficiency in these regions is fairly stable. The dynamics of the vibro-impact system “primary structure—SSVI NES” is rich and complex, which, however, does not impair the damper efficiency. In complex oscillatory regimes, the damper makes bilateral impacts: it hits both an obstacle and directly against the primary structure, which actually turns a single-sided NES into a double‐sided one. The optimization procedure and the choice of optimal damper parameters play a very important role in damper design. Optimizing multiple damper parameters instead of three shows a synergistic effect and provides better results.
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