多层压电悬臂梁的机电模型

J. Brufau-Penella, M. Puig-Vidal
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引用次数: 3

摘要

本文给出了描述多层压电悬臂梁在电子和力学耦合域上行为的组成方程。该研究是基于控制欧拉-伯努利悬臂梁运动的偏微分方程和一对线性耦合压电方程的模态分析。这类材料模型化的一个重要因素是能量损失项;本文考虑了粘性阻尼的贡献,使我们能够提取更真实的成分方程,使材料作为传感器和作动器。将该方程发展为每个模态的无限线性组合,使我们能够提取一个紧凑的集总等效电路,作为传感器或执行器在任何频率区域工作,而不是经典的简化模型。将理论简化为三层商业悬臂梁的动力学研究,并与实验结果进行了比较
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Electromechanical Model of a Multi-Layer Piezoelectric Cantilever
In this paper the constituent equations that describe the behavior of a multi-layer piezoelectric cantilever on the coupled electronic and mechanical domain are presented. The study is based on the modal analysis of the partial differential equations governing the motion of an Euler-Bernoulli cantilever beam and on a pair of linearly coupled piezoelectric equations. An important element in the modelization of such materials is the energy loss term; in this paper a viscous damping contribution is considered which allows us to extract more realistic constituent equations for the material to work as sensor and actuator. The development of this equation as an infinite linear combination of each mode allows us to extract a compact lumped equivalent electrical circuit to work at any frequency region as sensor or actuator instead of the classical reduced models. Theory is reduced to study the dynamics of a triple-layer commercial cantilever and then is compared with experimental results
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