Sage Journals: Discover world-class research

Abstract

Stiffness and damping of a structure usually show the opposite change so that the resonant frequency and the static load bearing capacity of a mechanical system often exhibit contradiction. To solve this dilemma, a novel high-damping oscillator which is constructed by a nested diamond structure with the purpose of enhancing the damping property is proposed in this study without reducing the overall systematic stiffness. The mathematical model and geometrical relationships are established at first. And then, the steady-state solutions under base excitation are derived by using the harmonic balance method and further verified by numerical simulation. In addition, the effects of some design parameters on the equivalent damping ratio for the high-damping oscillator are studied to reveal the nonlinear characteristic. Besides, the natural frequency of the nonlinear oscillator is also presented and investigated. By using the displacement transmissibility and comparing with the traditional linear isolator with the same overall stiffness, the vibration suppression performance of the high-damping oscillator is addressed. The obtained calculating results demonstrate that the vibration control performance of the high-damping oscillator outperforms the linear counterpart around resonant frequency. Moreover, the influences of systematic parameters of the high-damping oscillator for the base excitation case on the vibration transmissibility are also discussed, respectively. Finally, an experimental campaign is conducted on an in-house-built test rig to corroborate the accuracy of the analytical solutions of the high-damping oscillation system. The results discussed in this study provide a useful guideline, which can help to design this class of high-damping oscillation system.

Keywords

Nested diamond structure high-damping oscillator vibration suppression geometrical nonlinear

Get full access to this article

View all access options for this article.

References

Antoniadis

Chronopoulos

Spitas

, et al. (2015) Hyper-damping properties of a stiff and stable linear oscillator with a negative stiffness element. Journal of Sound and Vibration 346: 37–52.

Antoniadis

Kyriakopoulos

Papadopoulos

(2017) Hyper-damping behavior of stiff and stable oscillators with embedded statically unstable stiffness elements. International Journal of Structural Stability and Dynamics 17(5): 1740008.

Bayat

Pakar

Emadi

(2013) Vibration of electrostatically actuated microbeam by means of homotopy perturbation method. Structural Engineering and Mechanics 48(6): 823–831.

Bayat

Shahidi

Barari

, et al. (2010) The approximate analysis of nonlinear behavior of structure under harmonic loading. International Journal of the Physical Sciences 5(7): 1074–1080.

Beranek

(1992) Noise and Vibration Control Engineering. Principles and Applications. New York: Wiley.

Bian

Jing

(2017) Nonlinear passive damping of the X-shaped structure. Procedia Engineering 199: 1701–1706.

Bian

Jing

(2019) Superior nonlinear passive damping characteristics of the bio-inspired limb-like or X-shaped structure. Mechanical Systems and Signal Processing 125: 21–51.

Carrella

Brennan

Waters

, et al. (2008) On the design of a high-static-low-dynamic stiffness isolator using linear mechanical springs and magnets. Journal of Sound and Vibration 315: 712–720.

Cheng

Wang

, et al. (2017) Force and displacement transmissibility of a quasi-zero stiffness vibration isolator with geometric nonlinear damping. Nonlinear Dynamics 87(4): 2267–2279.

10.

Chronopoulos

Antoniadis

Collet

, et al. (2015) Enhancement of wave damping within metamaterials having embedded negative stiffness inclusions. Wave Motion 58: 165–179.

11.

Jing

(2014) Nonlinear characteristic output spectrum for nonlinear analysis and design. IEEE/ASME Transactions on Mechatronics 19: 171–183.

12.

Jing

Lang

(2009) Frequency domain analysis of a dimensionless cubic nonlinear damping system subject to harmonic input. Nonlinear Dynamics 58: 469–485.

13.

Jing

Lang

Billings

(2010) Output frequency properties of nonlinear systems. International Journal of Non-Linear Mechanics 45: 681–690.

14.

Kim

K-R

You

Y-h

Ahn

H-J

(2013) Optimal design of a QZS isolator using flexures for a wide range of payload. International Journal of Precision Engineering and Manufacturing 14(6): 911–917.

15.

Krack

Gross

(2019) Harmonic Balance for Nonlinear Vibration Problems. Switzerland: Springer.

16.

Ahn

(2011) A vibration isolation system in low frequency excitation region using negative stiffness structure for vehicle seat. Journal of Sound and Vibration 330: 6311–6335.

17.

Lee

C-M

Goverdovskiy

(2012) A multi-stage high-speed railroad vibration isolation system with “negative” stiffness. Journal of Sound and Vibration 331: 914–921.

18.

Zhao

(2016) New results on robust control for a class of uncertain systems and its applications to Chua’s oscillator. Nonlinear Dynamics 84 (4): 1929–1941.

19.

Liu

Jing

Chen

(2016) Band stop vibration suppression using a passive X-shape structured lever-type isolation system. Mechanical Systems and Signal Processing 68–69: 342–353.

20.

Liu

Jing

Daley

, et al. (2015a) Recent advances in micro-vibration isolation. Mechanical Systems and Signal Processing 56–57: 55–80.

21.

Liu

Jing

(2015b) Vibration isolation using a hybrid lever-type isolation system with an X-shape supporting structure. International Journal of Mechanical Sciences 98: 169–177.

22.

Liu

Huang

Hua

(2013) On the characteristics of a quasi-zero stiffness isolator using Euler buckled beam as negative stiffness corrector. Journal of Sound and Vibration 332: 3359–3376.

23.

Nayfeh

(2000) Nonlinear Interactions: Analytical, Computational, and Experimental Methods. New York: Wiley.

24.

Rivin

(1999) Stiffness and Damping in Mechanical Design. New York: Marcel Dekker.

25.

Rivin

(2003) Passive Vibration Isolation. New York: ASME Press.

26.

Sun

Jing

(2016) Analysis and design of a nonlinear stiffness and damping system with a scissor-like structure. Mechanical Systems and Signal Processing 66–67: 723–742.

27.

Sun

Jing

, et al. (2014) Vibration isolation via a scissor-like structured platform. Journal of Sound and Vibration 333: 2403–2420.

28.

Wang

Jing

(2019) Nonlinear stiffness and dynamical response characteristics of an asymmetric X-shaped structure. Mechanical Systems and Signal Processing 125: 142–169.

29.

Wei

Jing

(2017) A comprehensive review on vibration energy harvesting: modelling and realization. Renewable and Sustainable Energy Reviews 74: 1–18.

30.

Jing

Sun

, et al. (2016) A 6 DOF passive vibration isolator using X-shape supporting structures. Journal of Sound and Vibration 380: 90–111.

31.

Jing

Bian

, et al. (2015) Vibration isolation by exploring bio-inspired structural nonlinearity. Bioinspiration & Biomimetics 10(5): 056015.

32.

Younesian

Hosseinkhani

Askari

, et al. (2019) Elastic and viscoelastic foundations: a review on linear and nonlinear vibration modeling and applications. Nonlinear Dynamics 97: 853–895.

33.

Zhu

Zheng

(2004) Analysis of non-linear dynamics of a two-degree-of-freedom vibration system with non-linear damping and non-linear spring. Journal of Sound and Vibration 271: 15–24.

34.

Zhu

Jing

Cheng

(2012) Magnetorheological fluid dampers: a review on structure design and analysis. Journal of Intelligent Material Systems and Structures 23: 839–873.

Theoretical and experimental studies of a novel nested oscillator with a high-damping characteristic

Abstract

Keywords

Get full access to this article

References