Effective vibration isolation is crucial for maintaining the performance and longevity of sensitive equipment, particularly in environments with low-frequency disturbances. However, traditional pneumatic springs often exhibit limitations in providing effective vibration isolation under variable operating conditions, such as varying load mass and overload-induced accelerations. To address these limitations, a novel three-chamber pneumatic isolator (TPVI) is proposed. The TPVI features a three-chamber parallel topology that enables decoupled adjustment of stiffness from the static equilibrium position, allowing it to adapt to load variations. Analytical models for the static stiffness and dynamic response of the TPVI were developed and validated through experiments conducted on a physical prototype. Based on this validated model, a comprehensive parametric analysis was performed to establish a design procedure for the TPVI under variable operating conditions. Numerical simulations predict that the TPVI can achieve substantially enhanced low-frequency vibration isolation, particularly in maintaining stable performance under variable operating conditions. This study therefore offers a validated framework for a novel pneumatic vibration isolator, demonstrating a flexible approach for protecting sensitive equipment in dynamic operating environments.
AnJChenGDengX, et al. (2022) Analytical study of a pneumatic quasi-zero-stiffness isolator with mistuned mass. Nonlinear Dynamics108: 3297–3312. DOI: 10.1007/s11071-022-07412-8.
2.
ChenJ-JYinZ-HRakhejaS, et al. (2018) Theoretical modelling and experimental analysis of the vertical stiffness of a convoluted air spring including the effect of the stiffness of the bellows. Proceedings of the Institution of Mechanical Engineers - Part D: Journal of Automobile Engineering232: 547–561. DOI: 10.1177/0954407017704589.
3.
ChongXWuZLiF (2022) Vibration isolation properties of the nonlinear X-combined structure with a high-static and low-dynamic stiffness: theory and experiment. Mechanical Systems and Signal Processing179: 109352. DOI: 10.1016/j.ymssp.2022.109352.
4.
GaoXTengHD (2020) Dynamics and isolation properties for a pneumatic near-zero frequency vibration isolator with nonlinear stiffness and damping. Nonlinear Dynamics102: 2205–2227. DOI: 10.1007/s11071-020-06063-x.
5.
HuangXSuZWangS, et al. (2020) High-frequency disturbance force suppression mechanism of a flywheel equipped with a flexible dynamic vibration absorber. Journal of Vibration and Control26: 2113–2124. DOI: 10.1177/1077546320915340.
6.
JiaoXZhangJLiW, et al. (2023) Advances in spacecraft micro-vibration suppression methods. Progress in Aerospace Sciences138: 100898. DOI: 10.1016/j.paerosci.2023.100898.
7.
LeeJ-HKimK-J (2007) Modeling of nonlinear complex stiffness of dual-chamber pneumatic spring for precision vibration isolations. Journal of Sound and Vibration301: 909–926. DOI: 10.1016/j.jsv.2006.10.029.
8.
LiuCJingXDaleyS, et al. (2015) Recent advances in micro-vibration isolation. Mechanical Systems and Signal Processing56–57: 55–80. DOI: 10.1016/j.ymssp.2014.10.007.
9.
PuHLuoXChenX (2011) Modeling and analysis of dual-chamber pneumatic spring with adjustable damping for precision vibration isolation. Journal of Sound and Vibration330: 3578–3590. DOI: 10.1016/j.jsv.2011.03.005.
10.
SalehiMBagherzadehA (2022) Analysis of in-flight cabin vibration of a turboprop airplane by proposing a novel noise-tolerant signal decomposition method. Journal of Vibration and Control28: 2226–2239. DOI: 10.1177/10775463211007583.
11.
ShiHTAbubakarMBaiXT, et al. (2024) Vibration isolation methods in spacecraft: a review of current techniques. Advances in Space Research73: 3993–4023. DOI: 10.1016/j.asr.2024.01.020.
12.
SunZ-YYueX-HLiA, et al. (2025) A tensegrity-based torsional vibration isolator with broad quasi-zero-stiffness region. Mechanical Systems and Signal Processing224: 112215. DOI: 10.1016/j.ymssp.2024.112215.
13.
VoNYPLeTD (2019) Adaptive pneumatic vibration isolation platform. Mechanical Systems and Signal Processing133: 106258. DOI: 10.1016/j.ymssp.2019.106258.
14.
VoNYPNguyenMKLeTD (2021) Analytical study of a pneumatic vibration isolation platform featuring adjustable stiffness. Communications in Nonlinear Science and Numerical Simulation98: 105775. DOI: 10.1016/j.cnsns.2021.105775.
15.
XingZ-YYangX-D (2023) A combined vibration isolation system with quasi-zero stiffness and dynamic vibration absorber. International Journal of Mechanical Sciences256: 108508. DOI: 10.1016/j.ijmecsci.2023.108508.
16.
XiongYLiFWangY (2022) A nonlinear quasi-zero-stiffness vibration isolation system with additional X-shaped structure: theory and experiment. Mechanical Systems and Signal Processing177: 109208. DOI: 10.1016/j.ymssp.2022.109208.
17.
XuSWangYSunZ, et al. (2024) A compound regulative pneumatic vibration isolator with quasi-zero stiffness mechanism for load variable instruments. IEEE Transactions on Instrumentation and Measurement73: 1–10. DOI: 10.1109/TIM.2024.3417599.
18.
YaoYLiHLiY, et al. (2020) Analytical and experimental investigation of a high-static-low-dynamic stiffness isolator with cam-roller-spring mechanism. International Journal of Mechanical Sciences186: 105888. DOI: 10.1016/j.ijmecsci.2020.105888.
19.
YuHGaoX (2022) Modeling and stiffness properties for the hydro-pneumatic near-zero frequency vibration isolator with piecewise smooth stiffness. Journal of Vibration Engineering & Technologies10: 527–539. DOI: 10.1007/s42417-021-00390-y.
20.
YuanZZhangZZengL, et al. (2023) Microvibration isolation in sensitive payloads: methodology and design. Nonlinear Dynamics111: 19563–19611. DOI: 10.1007/s11071-023-08943-4.
21.
ZhangWShiMLiuC, et al. (2025) Synchronous low-frequency vibration mitigation and energy harvesting with tunable load bearing capacity and operation band. Communications in Nonlinear Science and Numerical Simulation142: 108588. DOI: 10.1016/j.cnsns.2024.108588.
22.
ZhaoZQiuZZhangX, et al. (2016) Vibration control of a pneumatic driven piezoelectric flexible manipulator using self-organizing map based multiple models. Mechanical Systems and Signal Processing70–71: 345–372. DOI: 10.1016/j.ymssp.2015.09.041.
23.
ZhengYShangguanW-B (2023) A combined analytical model for orifice-type and pipe-type air springs with auxiliary chambers in dynamic characteristic prediction. Mechanical Systems and Signal Processing185: 109830. DOI: 10.1016/j.ymssp.2022.109830.
24.
ZhengYShangguanWBRakhejaS (2021) Modeling and performance analysis of convoluted air springs as a function of the number of bellows. Mechanical Systems and Signal Processing159: 107858. DOI: 10.1016/j.ymssp.2021.107858.
25.
ZhengYShangguanW-BRakhejaS (2022) Modeling and analysis of time-domain nonlinear characteristics of air spring with an auxiliary chamber. Mechanical Systems and Signal Processing176: 109161. DOI: 10.1016/j.ymssp.2022.109161.
26.
ZhuHYangJZhangY, et al. (2017a) A novel air spring dynamic model with pneumatic thermodynamics, effective friction and viscoelastic damping. Journal of Sound and Vibration408: 87–104. DOI: 10.1016/j.jsv.2017.07.015.
27.
ZhuHYangJZhangY (2021) Dual-chamber pneumatically interconnected suspension: modeling and theoretical analysis. Mechanical Systems and Signal Processing147: 107125. 10.1016/j.ymssp.2020.107125.
28.
ZhuHHeSShenJ, et al. (2024) Design and experiment of a large-scale space micro-vibration simulator. Journal of Vibration and Control30: 740–752. 10.1177/10775463221150825.
29.
ZuoSWangDZhangY, et al. (2022) Design and testing of a parabolic cam-roller quasi-zero-stiffness vibration isolator. International Journal of Mechanical Sciences220: 107146. DOI: 10.1016/j.ijmecsci.2022.107146.
