Dynamics and Stability of Magnetic-Air Hybrid Quasi-Zero Stiffness Vibration Isolation System

Jiang, Youliang; Song, Chunsheng; Ma, Xin; Han, Wei; Mai, Zhihui

doi:10.20855/ijav.2023.28.11919

Cited by 2 publications

(1 citation statement)

References 21 publications

(25 reference statements)

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“…Wu et al 27 changed the negative stiffness mechanism of the classical three-spring structure to three mutually repulsive cube magnets. Jiang et al 28 designed a magnetopneumatic hybrid QZS vibration isolator. Xie et al 29 proposed an MQZS vibration isolator with an air spring, coils, and a ring magnet.…”

Section: Introductionmentioning

confidence: 99%

Three‐magnet‐ring quasi‐zero stiffness isolator for low‐frequency vibration isolation

Wang,

Hou,

Meng

et al. 2024

Int Journal of Mech Sys Dyn

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A three‐magnet‐ring quasi‐zero stiffness (QZS‐TMR) isolator is designed to solve the problem of low‐frequency vibration isolation in the vertical direction of precision equipment. QZS‐TMR has both positive and negative stiffness structures. The positive stiffness structure consists of two mutually repelling magnetic rings and the negative stiffness structure consists of two magnetic rings nested within each other. By modulating the relative distance between positive and negative stiffness structures, the isolator can have QZS characteristics. Compared with other QZS isolators, the QZS‐TMR is compact and easy to manufacture. In addition, the working load of QZS‐TMR can be flexibly adjusted by varying the radial widths of the inner magnetic ring. In this paper, the static analysis of QZS‐TMR is carried out to guide the design, and the low‐frequency vibration isolation performance is studied. In addition, the experimental prototype of QZS‐TMR is designed and manufactured. The static and vibration isolation experiments are carried out on the prototype. The results show that the initial vibration isolation frequency of the experimental prototype is about 4 Hz. The results show an excellent low‐frequency vibration isolation effect, which is consistent with the theoretical research. This paper introduces a new approach to the design of the QZS isolator.

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Section: Introductionmentioning

confidence: 99%

Three‐magnet‐ring quasi‐zero stiffness isolator for low‐frequency vibration isolation

Wang,

Hou,

Meng

et al. 2024

Int Journal of Mech Sys Dyn

View full text Add to dashboard Cite

show abstract

Study of the comfortable efficiency of the automobile using the seat’s Negative-Stiffness-Structure via two mathematical models

Li,

Yang

2024

Noise & Vibration Worldwide

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The isolating performance of NSS (Negative-Stiffness-Structure) on ameliorating the automotive’s comfortable in all vertical, pitching, and rolling directions has been not studied yet. Thus, two vibration models of the automobile including the two-dimensional (2-D) model and three-dimensional (3-D) model are built to evaluate automobile’s comfortable efficiency under various conditions. The reduction of the seat and automobile accelerations has been used as an evaluation index. Results present that seat’s vertical acceleration using NSS is evidently improved compared without NSS in two models of the automobile. Especially, the seat’s root-mean-square acceleration with NSS is strongly deteriorated by 65.1% with 2-D model and reduced by 69.7% with 3-D model in comparison without NSS. However, the seat’s NSS does not affect the pitching vibration of the automobile’s body. Besides, from the comparison results between 2-D and 3-D models, seat’s NSS could strongly ameliorate the comfortable efficiency in both vertical and rolling vibrations while the seat’s NSS does not affect improving the automobile’s pitching angle of the automobile. Therefore, to fully assess NSS’s isolating performance as well as improve the comfortable efficiency of the automobile in all vibration directions, 3-D model of the automobile should be used.

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Dynamics and Stability of Magnetic-Air Hybrid Quasi-Zero Stiffness Vibration Isolation System

Cited by 2 publications

References 21 publications

Three‐magnet‐ring quasi‐zero stiffness isolator for low‐frequency vibration isolation

Three‐magnet‐ring quasi‐zero stiffness isolator for low‐frequency vibration isolation

Study of the comfortable efficiency of the automobile using the seat’s Negative-Stiffness-Structure via two mathematical models

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