基于立方体STEWART的微振动主动控制分析与实验

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摘要本文采用立方体结构隔振平台，它具有各向同性以及轴向运动解耦等特点。对立方体Stewart平台分别进行运动学和动力学分析，获得杆长与平台姿态的雅克比矩阵，揭示平台振动传递特性。采用压电叠堆为主动控制单元，设计立方体Stewart主动隔振平台，并通过实验测定平台主动杆在5 Hz-120 Hz频带内的输出特性，通过实测数据修正理论分析得到的雅克比矩阵。结合Fx-LMS主动控制算法，对基础干扰进行主动抑制，实验结果表明，在5 Hz-120 Hz范围内，对于单频干扰，平台可实现30 dB抑制效果。

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关键词 ：微振动, 立方体Stewart平台, 主动隔振, 雅克比矩阵, Fx-LMS

Abstract：

A Stewart platform with a cubic configuration was developed having uniformity of stiffness and a control capability in all directions,and a simplified mechanical design.Its kinematic and dynamic analyses were conducted to obtain Jacobian matrix relating the extension of the piezo actuator to 6-DOF of the top plate and to reveal its characteristics of vibration transmissibility.Taking a piezoelectric stack as an active control element,the platform was designed.Tests were performed to measure the output characteristics of the active bar of the platform within the frequency band of 5 Hz to 120 Hz and Jacobian matrix obtained with theoretical analysis was modified with test data.Fx-LMS algorithm was adopted to actively suppress the foundation disturbances.The results showed that within the range of 5 Hz to 120 Hz,the platform is able to achieve 30 dB attenuation effect under a single frequency disturbance.

Key words： micro-vibration Stewart platform with a cubic configuration active isolation Jacobian matrix Fx-LMS

收稿日期: 2015-07-23 出版日期: 2017-02-25

引用本文:

王超新1,2 刘兴天3 张志谊1,2. 基于立方体STEWART的微振动主动控制分析与实验[J]. 振动与冲击, 2017, 36(5): 208-213.
WANG Chaoxin1,2,LIU Xingtian3,ZHANG Zhiyi1,2. Micro-vibration active control for a Stewart platform with a cubic configuration. JOURNAL OF VIBRATION AND SHOCK, 2017, 36(5): 208-213.

链接本文:

http://jvs.sjtu.edu.cn/CN/ 或 http://jvs.sjtu.edu.cn/CN/Y2017/V36/I5/208

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