新型 XYθ 压电微型平台的设计、建模和分析,具有高放大比和多种驱动模式

Gaohua Wu, Guoping Li, Yiling Yang, Yanding Wei
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摘要

本文介绍了具有高放大比和完全对称结构的新型 XYθ 压电微平台的设计、建模和分析。通过可重新配置压电致动器的装配位置,所提出的微平台可提供多种致动模式和低平移寄生运动。该微型平台采用改进的四杆放大机构和平行四边形导向机构。在基于矩阵的顺应性建模基础上,获得了静态和动态模型。通过有限元分析(FEA)对理论模型进行了分析。最后,制造了拟议微舞台的原型,建立了实验系统,并测试了微舞台的性能。实验结果表明,微舞台的放大比率为 8.40(x 轴)和 8.52(y 轴)。x 轴和 y 轴方向的位移耦合比分别为 0.83% 和 0.94%。此外,当微动平台使用纯中心旋转的驱动模式时,最大旋转角度为 ± 2379.18 μrad。XYθ 微型平台能够进行多尺度微操作。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Design, modeling, and analysis of a new XYθ piezoelectric microstage featuring high amplification ratios and multiple actuation modes

Design, modeling, and analysis of a new XYθ piezoelectric microstage featuring high amplification ratios and multiple actuation modes

This paper presents the design, modeling, and analysis of a new XYθ piezoelectric microstage with high amplification ratios and fully symmetrical structures. Through the reconfigurable assembly positions of piezoelectric actuators, the proposed microstage can provide multiple actuation modes and low translational parasitic motion. The microstage is devised using improved four-bar amplification mechanisms and parallelogram guiding mechanisms. Based on the matrix-based compliance modeling, static and dynamic models are obtained. The theoretical models are analyzed by finite element analysis (FEA). Finally, a prototype of the proposed microstage is manufactured, an experimental system is set up, and the performance of the microstage is tested. The experimental results show that the microstage has amplification ratios of 8.40 (x-axis) and 8.52 (y-axis). The displacement coupling ratios in the x- and y-axis directions are 0.83% and 0.94%, respectively. Moreover, the maximum rotation angle is ± 2379.18 μrad when the microstage uses the actuation mode of the pure center rotation. The XYθ microstage is capable of multiscale micromanipulation.

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