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基于压电Stewart平台的主动隔振系统设计与控制方法研究

Research on design and control method of active vibration isolation system based on piezoelectric Stewart platform.

作者信息

Fang Zhiyi, Yu Zhiliang, Huang Qingping, Wang Yanfen, Gu Xingsheng

机构信息

East China University of Science and Technology, Shanghai, China.

Aerospace System Engineering Shanghai, Shanghai, 201100, China.

出版信息

Sci Rep. 2025 Jan 6;15(1):944. doi: 10.1038/s41598-024-84980-2.

DOI:10.1038/s41598-024-84980-2
PMID:39762358
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11704038/
Abstract

Space payloads in orbit are vulnerable to small vibrations from satellite platforms, which can degrade their performance. Traditional methods typically involve installing a passive vibration isolation system between the platform and the payload. However, such systems are usually effective only for high-frequency, large-amplitude vibrations and perform poorly in isolating low-frequency vibrations and resonances below 10 Hz. To address this limitation, this paper proposes an active vibration isolation system using a 6-degrees-of-freedom Stewart platform driven by piezoelectric actuators. First, the characteristics of the Stewart platform are analyzed and modeled, with the deformation displacement of each leg calculated through decoupling, allowing for high-precision servo control. Next, given the inherent hysteretic nonlinearity of piezoelectric ceramics, which significantly affects positioning accuracy, the hysteresis mechanism of the actuators is analyzed, and a phenomenological mathematical model based on Bouc-Wen operators is established. A Modified particle swarm optimization (MPSO) method is proposed for identifying the model's nonlinear parameters, significantly enhancing the optimization efficiency. Finally, feedforward inverse compensation and feedback linearization methods are introduced. Experimental results verify that the designed active-passive vibration isolation system greatly improves both the positioning accuracy of the piezoelectric actuators and the active vibration isolation performance of the platform.

摘要

轨道上的空间有效载荷容易受到卫星平台微小振动的影响,这会降低其性能。传统方法通常包括在平台和有效载荷之间安装被动隔振系统。然而,此类系统通常仅对高频、大幅度振动有效,在隔离低于10Hz的低频振动和共振方面表现不佳。为解决这一局限性,本文提出一种使用由压电致动器驱动的六自由度Stewart平台的主动隔振系统。首先,对Stewart平台的特性进行分析和建模,通过解耦计算每条腿的变形位移,实现高精度伺服控制。其次,鉴于压电陶瓷固有的滞后非线性会显著影响定位精度,分析了致动器的滞后机理,并建立了基于Bouc-Wen算子的唯象数学模型。提出一种改进粒子群优化(MPSO)方法来识别模型的非线性参数,显著提高了优化效率。最后,引入前馈逆补偿和反馈线性化方法。实验结果验证了所设计的主被动隔振系统大大提高了压电致动器的定位精度和平台的主动隔振性能。

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