Abstract
For aim of providing a stable working environment for those sensitive payloads on-orbit, typically the space telescope and laser communication equipment and so on, micro-vibrations generated by those instruments should be taken measures to suppress. Therefore, this article proposes a novel vibration isolation stage for controlling the low frequency vibration caused by solar arrays, which is difficult to suppress by traditional methods. By adoption of compliant mechanism embedded multilevel amplifiers and giant magnetostrictive actuator, not only the large working stroke with nano-precision could be achieved, but also the required stable output capability in low frequency is obtained. The conceptual scheme and working principle are presented firstly in this paper. And then the theoretical amplification ratio model is constructed and static analysis and dynamic analysis are carried out by ANSYS. Finally, experimental tests are conducted for verifying the related performance. It proves that the proposed stage is capable of suppressing low frequency disturbance.
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Hur, G.: Isolation of micro-vibrations due to reaction wheel assembly using a source-path-receiver approach for quantitative requirements. J. Vibr. Control 25(8), 1424–1435 (2019)
Sun, X.Q., Yang, B.T.: Optimal design and experimental analyses of a new micro-vibration control payload-platform. J. Sound Vibr. 374, 43–60 (2016)
Duan, X.C., Qiu, Y.Y.: On the mechatronic servo bandwidth of a stewart platform for active vibration isolating in a super antenna. Robot. Comput.-Integr. Manuf. 40, 66–77 (2016)
Yang, X.L., Wu, H.T.: Dynamic modeling and decoupled control of a flexible Stewart platform for vibration isolation. J. Sound Vibr. 439, 398–412 (2019)
Wang, P.Y., Xu, Q.S.: Design of a flexure-based constant-force XY precision positioning stage. Mech. Mach. Theory 108, 1–13 (2017)
Liu, P.B., Yan, P.: Design and trajectory tracking control of a piezoelectric nano-manipulator with actuator saturations. Mech. Syst. Sig. Process. 111, 529–544 (2018)
Zhang, H., Zhang, T.L.: Design of a uniform bias magnetic field for giant magnetostrictive actuators applying triple-ring magnets. Smart Mater. Struct. 22, 1–6 (2013). 115009
Sun, X.Q., Wang, Z.L.: Integrated design of actuator for thin plate optical reflector. Aerosp. Shanghai 3, 60–66 (2018)
Sun, X.Q., Yi, S.C.: A new bi-directional giant magnetostrictive-driven compliant tensioning stage oriented for maintenance of the surface shape precision. Mech. Mach. Theory 126, 359–376 (2018)
Yi, S.C., Yang, B.T.: Microvibration isolation by adaptive feedforward control with asymmetric hysteresis compensation. Mech. Syst. Sig. Process. 114, 644–657 (2019)
Acknowledgments
This research was supported by “the Fundamental Research Funds for the Central Universities (NO. 2232019D3-37)”, the Initial Research Funds for Young Teachers of Donghua University (NO. 103-07-0053049) and the research grant (USCAST2015-05) from Shanghai Aerospace Fund.
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Sun, X., Hu, J., Lu, J., Wang, Z. (2019). A Novel Giant Magnetostrictive Driven-Vibration Isolation Stage Based on Compliant Mechanism. In: Yu, H., Liu, J., Liu, L., Ju, Z., Liu, Y., Zhou, D. (eds) Intelligent Robotics and Applications. ICIRA 2019. Lecture Notes in Computer Science(), vol 11740. Springer, Cham. https://doi.org/10.1007/978-3-030-27526-6_27
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DOI: https://doi.org/10.1007/978-3-030-27526-6_27
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