非对称压电陶瓷在非对称振动梁主动还原中的应用——半解析解

IF 0.6 4区 物理与天体物理 Q4 ACOUSTICS
A. Brański, Romuald Kuras
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引用次数: 1

摘要

将对称振型梁的主动减振思想推广到非对称振型梁。在对称模态下,采用对称PZT (s-PZT),通过优化得到s-PZT的中心位置为光束曲率最大的点。在后一种情况下,由于点质量的增加而发生的不对称模态导致梁的弯矩和横向位移的不对称分布。在这种情况下,主动减振的最佳方法既需要新的非对称PZT (a-PZT),也需要新的PZT在梁上的特殊分布。用数学方法确定了a-PZT不对称点(a点)应放置在梁弯矩最大的点上。a-PZT不对称性是通过最小化振动振幅在数学上发现的。因此,有可能制定梁的最大弯矩准则。数值计算证实了理论考虑。因此,研究表明,在不对称振动的情况下,a- pzt比s-PZT更有效地减少振动。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Asymmetrical PZT applied to active reduction of asymmetrically vibrating beam – semi-analytical solution
The article extended the idea of active vibration reduction of beams with symmetric modes to beams with asymmetric modes. In the case of symmetric modes, the symmetric PZT (s-PZT) was used, and the optimization of the problem led to the location of the s-PZT centre at the point with the greatest beam curvature. In the latter case, the asymmetric modes that occur due to the addition of the point mass cause an asymmetric distribution of the bending moment and transversal displacement of a beam. In this case, the optimal approach to the active vibration reduction requires both new asymmetric PZT (a-PZT) and its new particular distribution on the beam. It has been mathematically determined that the a-PZT asymmetry point (a-point), ought to be placed at the point of maximum beam bending moment. The a-PZT asymmetry was found mathematically by minimizing the amplitude of the vibrations. As a result, it was possible to formulate the criterion of the maximum bending moment of the beam. The numerical calculations confirmed theoretical considerations. So, it was shown that in the case of asymmetric vibrations, the a-PZTs reduced vibrations more efficiently than the s-PZT.
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来源期刊
Archives of Acoustics
Archives of Acoustics 物理-声学
CiteScore
1.80
自引率
11.10%
发文量
0
审稿时长
6-12 weeks
期刊介绍: Archives of Acoustics, the peer-reviewed quarterly journal publishes original research papers from all areas of acoustics like: acoustical measurements and instrumentation, acoustics of musics, acousto-optics, architectural, building and environmental acoustics, bioacoustics, electroacoustics, linear and nonlinear acoustics, noise and vibration, physical and chemical effects of sound, physiological acoustics, psychoacoustics, quantum acoustics, speech processing and communication systems, speech production and perception, transducers, ultrasonics, underwater acoustics.
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