Optimization of a Non-Traditional Vibration Absorber for Vibration Suppression and Energy Harvesting

IF 1.9 Q3 ENGINEERING, MECHANICAL
Vibration Pub Date : 2022-06-22 DOI:10.3390/vibration5030022
M. Yuan, Youzuo Jin, Kefu Liu, A. Sadhu
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引用次数: 1

Abstract

This paper investigates the optimization of a non-traditional vibration absorber for simultaneous vibration suppression and energy harvesting. Unlike a traditional vibration absorber, the non-traditional vibration absorber has its damper connected between the absorber mass and the base. An electromagnetic energy harvester is used as a tunable absorber damper. This non-traditional vibration absorber is attached to a primary system that is subjected to random base excitation. An analytical study is conducted by assuming that the base excitation is white noise. In terms of vibration suppression, the objective of the optimization is to minimize the power dissipated by the primary damper and maximize the power dissipated by the absorber damper. It is found that when the primary system is undamped, the power dissipated by the absorber damper remains a constant that is related to the mass ratio. The higher the mass ratio, the higher the power dissipated. When the primary system is damped, the minimization of the power dissipated by the primary damping is equivalent to the maximization of the power dissipated by the absorber damper. The existence of the optimum solutions depends on both the mass ratio and the primary damping ratio. In terms of energy harvesting, the objective of optimization is to maximize the power harvested by the load resistor. It is found that for a given mass ratio and primary damping ratio, the optimum frequency tuning ratio required to maximize vibration suppression is slightly higher than that required to maximize the harvested power. The trade-off issue between vibration suppression and energy harvesting is investigated. An apparatus is developed to allow frequency tuning and damping tuning. Both the numerical simulation and experimental study with band-limited white noise validate the general trends revealed in the analytical study.
用于振动抑制和能量收集的非传统减振器的优化
本文研究了一种用于同时抑制振动和收集能量的非传统减振器的优化。与传统减振器不同,非传统减振器的阻尼器连接在减振器质量和底座之间。电磁能量采集器被用作可调谐吸收阻尼器。这种非传统的减振器连接到一个受到随机基础激励的主系统上。通过假设基底激励是白噪声进行分析研究。在振动抑制方面,优化的目标是使主阻尼器耗散的功率最小化,并使吸收阻尼器耗散的能量最大化。研究发现,当一次系统无阻尼时,吸收阻尼器耗散的功率保持不变,与质量比有关。质量比越高,耗散的功率就越高。当一次系统阻尼时,一次阻尼耗散功率的最小化等于吸收阻尼器耗散功率的最大化。最优解的存在取决于质量比和主阻尼比。在能量收集方面,优化的目标是最大化负载电阻器收集的功率。研究发现,对于给定的质量比和主阻尼比,最大化振动抑制所需的最佳频率调谐比略高于最大化收获功率所需的频率调谐比。研究了振动抑制和能量收集之间的权衡问题。开发了一种允许频率调谐和阻尼调谐的装置。数值模拟和带限白噪声的实验研究都验证了分析研究中揭示的总体趋势。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.20
自引率
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审稿时长
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