Investigation on active vibration isolation of a Stewart platform with piezoelectric actuators

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• 作者：Chaoxin Wang^a ; ^b ; Xiling Xie^a ; ^b ; Yanhao Chen^a ; ^b ; Zhiyi Zhang^a ; ^b ; ^{chychang@sjtu.edu.cn" class="auth_mail" title="E-mail the corresponding author}
• 关键词：Mirco-vibration control ; Stewart platform with a cubic configuration ; Adaptive control ; Jacobi matrix
• 刊名：Journal of Sound and Vibration
• 出版年：2016
• 出版时间：24 November 2016
• 年：2016
• 卷：383
• 期：Complete
• 页码：1-19
• 全文大小：2371 K

文摘

A Stewart platform with piezoelectric actuators is presented for micro-vibration isolation. The Jacobi matrix of the Stewart platform, which reveals the relationship between the position/pointing of the payload and the extensions of the six struts, is derived by kinematic analysis. The dynamic model of the Stewart platform is established by the FRF (frequency response function) synthesis method. In the active control loop, the direct feedback of integrated forces is combined with the FxLMS based adaptive feedback to dampen vibration of inherent modes and suppress transmission of periodic vibrations. Numerical simulations were conducted to prove vibration isolation performance of the Stewart platform under random and periodical disturbances, respectively. In the experiment, the output consistencies of the six piezoelectric actuators were measured at first and the theoretical Jacobi matrix as well as the feedback gain of each piezoelectric actuator was subsequently modified according to the measured consistencies. The direct feedback loop was adjusted to achieve sufficient active damping and the FxLMS based adaptive feedback control was adopted to suppress vibration transmission in the six struts. Experimental results have demonstrated that the Stewart platform can achieve 30 dB attenuation of periodical disturbances and 10–20 dB attenuation of random disturbances in the frequency range of 5–200 Hz.