期刊
INTERNATIONAL JOURNAL OF MECHANICAL SCIENCES
卷 216, 期 -, 页码 -出版社
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.ijmecsci.2021.106980
关键词
arrayed-magnetic-spring; negative stiffness density; vibration isolation; magnetic charge model; stiffness nonlinearity
资金
- National Key R&D Program of China [2020YFB2007301, 2020YFB2007601]
- National Natural Science Foundation of China [52075193]
- National Science and Technology Major Project of China [2017ZX02101007-002]
By proposing a novel compact arrayed-magnetic-spring with negative stiffness (AMS-NS), this paper makes innovative progress in paralleling magnetic negative stiffness with positive stiffness, demonstrating the effective reduction of resonance frequency with AMS-NS. Parametric studies and dynamic experiments further confirm the high negative stiffness density and good isolation performance of AMS-NS.
Paralleling magnetic negative stiffness mechanism (NSM) with positive stiffness serves as an effective way to resolve the inherent contradiction between high load capacity and ultra-low frequency vibration isolation ability. Nevertheless, the stiffness nonlinearity and oversize of common magnetic NSMs restrict their further applications. In this paper, a novel compact arrayed-magnetic-spring with negative stiffness (AMS-NS) is proposed. The AMS-NS, which consists of cuboidal magnets arranged as a rectangular array, possesses high negative stiffness density and ameliorative nonlinearity. An analytical model of the AMS-NS is established based on the magnetic charge model and validated by static experiments. Parametric studies are conducted to provide guidelines for the optimal design of the AMS-NS. In addition, the nonlinear displacement transmissibility of an isolator with the AMS-NS and positive stiffness in parallel (APSP) is derived utilizing the harmonic balance method, and effect of stiffness characteristic of the AMS-NS on the isolation performance are furtherly investigated. Finally, dynamic experiments were conducted on a prototype with APSP, the results demonstrated that the proposed AMS-NS has high negative stiffness density and can effectively reduce the resonance frequency to broaden the vibration isolation band; and the analytical results showed good agreements with the experimental results.
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