Nonlinear Vibration Isolation of Spacecraft System by a Bionic Variable-Stiffness Device Enhanced by Electromagnetic Component

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2023-10-16 DOI:10.1007/s10338-023-00431-x
Zeyu Chai, Xuyuan Song, Jian Zang, Yewei Zhang
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Abstract

This study addresses the modified bionic vibration isolation technology by introducing the electromagnetic system to simulate biological damping characteristics. It has been proven effective in improving the vibration environment. By assuming the spacecraft-adapter system as a two-degree-of-freedom system, an excellent simplified model can be derived. The novel bionic vibration isolation device (ABVS-EMVI), which combines an active bionic variable-stiffness device (ABVSVI) with the electromagnetic system, is proposed for the purpose of isolating vibration and harvesting energy at the same time. The dynamic equations of the spacecraft-adapter system with ABVS-EMVI are obtained using the Taylor expansion within the framework of the Lagrange equation, and the harmonic balance method is introduced to acquire the amplitude and voltage response of the system. The results indicate that the electromagnetic system can enhance the vibration isolation performance and provide energy harvesting capabilities. After confirming the ability of ABVS-EMVI to deal with different forms and amplitudes of excitation, the performance of vibration isolation and energy harvesting is investigated in terms of various parameters, and several new conclusions have been drawn.

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电磁元件增强仿生变刚度装置对航天器系统非线性隔振的影响
本文通过引入电磁系统来模拟生物阻尼特性,研究了改进的仿生隔振技术。实践证明,该方法对改善振动环境是有效的。将航天器-转接器系统假设为二自由度系统,可以得到一个很好的简化模型。提出了一种新型仿生隔振装置(ABVS-EMVI),该装置将主动变刚度仿生装置(ABVSVI)与电磁系统相结合,实现了隔振和能量收集的双重目的。在拉格朗日方程的框架下,采用泰勒展开法得到了ABVS-EMVI航天器适配器系统的动力学方程,并引入谐波平衡法获得了系统的幅值和电压响应。结果表明,电磁系统可以提高隔振性能,并提供能量收集能力。在确认了ABVS-EMVI处理不同形式和振幅激励的能力后,从不同的参数角度研究了ABVS-EMVI的隔振和能量收集性能,并得出了一些新的结论。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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