Sage Journals: Discover world-class research

Abstract

Experimentally and theoretically, this paper combines thermodynamics, aerodynamics and structural dynamics to give a universal dynamical model of dual-chamber air springs, with physical meanings of each stiffness and damping term. An indicator experiment was designed to verify the theory proposed in this paper. The experimental results show that the dynamic stiffness model can well reflect the hysteresis characteristics and the variable stiffness characteristics of the dual-chamber air spring. It can also clearly reveal the frequency dependence of the dynamic stiffness. Finally, based on the derived model, the influence regulation of each parameter term on the dynamic stiffness amplitude and hysteresis phase angle is given numerically. The results show that each term can influence different dynamic characteristic of the dual-chamber air springs. The conclusions of this article can provide positive guidance for the vehicle dynamics matching and design of air springs.

Keywords

Thermodynamics dual-chamber air spring hysteresis characteristics frequency dependence nonlinear characteristic

Get full access to this article

View all access options for this article.

References

Research on vertical stiffness of belted air springs. Veh Syst Dyn 2013; 51: 1655–1673.

Liu

Lee

JC.

Model development and experimental research on an air spring with auxiliary reservoir. Int J Autom Technol 2011; 12: 839–847.

Zhu

Wang

Zhang

Research on theoretical calculation model for dynamic stiffness of air spring with auxiliary chamber. In: IEEE Vehicle Power and Propulsion Conference (VPPC), Harbin, China, 3–5 September 2008. Piscataway: IEEE Press.

Bruni

Vinolas

Berg

, et al. Modelling of suspension components in a rail vehicle dynamics context. Veh Syst Dyn 2011; 49: 1021–1072.

Zeng

Zhang

, et al. The stiffness and damping characteristics of a dual-chamber air spring device applied to motion suppression of marine structures. Appl Sci 2016; 6: 74.

de Melo

Pereira

Morais

. The simulation of an automotive air spring suspension using a pseudo-dynamic procedure. Appl Sci 2018; 8: 1049.

Spiroiu

MA.

Railway vehicle pneumatic rubber suspension modelling and analysis. J Mater Plastic 2018; 55: 24–27.

Mazzola

Berg

Secondary suspension of railway vehicles - air spring modelling: performance and critical issues. J Rail Rapid Transit 2014; 228: 225–241.

Zhu

Yang

Zhang

, et al. Nonlinear dynamic model of air spring with a damper for vehicle ride comfort. Nonlinear Dyn 2017; 89: 1545–1568.

10.

Zhu

Yang

Zhang

Dual-chamber pneumatically interconnected suspension: Modeling and theoretical analysis. Mech Syst Signal Process 2021; 147: 107125.

11.

Liu

Zhen

Dynamic model and experimental research of novel air spring with parallel unidirectional pipes and single additional chamber. SAE technical paper 2021-01-0315, 2021.

12.

Chen

Yin

Rakheja

, et al. Theoretical modelling and experimental analysis of the vertical stiffness of a convoluted air spring including the effect of the stiffness of the bellows. Proc IMechE, Part D: J Automobile Engineering 2018; 232: 547–561.

13.

Chen

Yin

Yuan

, et al. A refined stiffness model of rolling lobe air spring with structural parameters and the stiffness characteristics of rubber bellows. Measurement 2021; 169: 108355.

14.

Wei

Simulation on polytropic process of air springs. Eng Comput 2016; 33: 1957–1968.

15.

Doquier

Multiphysics modelling of multibody systems – application to railway pneumatic suspensions. PhD Thesis, Université Catholique de Louvain, Belgium, 2010.

16.

A three-dimensional coupled dynamics model of the air spring of a high-speed electric multiple unit train. Proc IMechE, Part F: J Rail Rapid Transit 2017; 231: 3–18.

17.

Zeng

Zhang

, et al. The effect of an orifice plate with different orifice numbers and shapes on the damping characteristics of a dual-chamber air spring. J Vibroengineering 2017; 19: 2375–2389.

18.

Lee

Kim

KJ.

Modeling of nonlinear complex stiffness of dual-chamber pneumatic spring for precision vibration isolations. J Sound Vib 2007; 301: 909–926.

19.

Yin

Khajepour

Cao

, et al. A new pneumatic suspension system with independent stiffness and ride height tuning capabilities. Veh Syst Dyn 2012; 50: 1735–1746.

20.

Holtz

van Niekerk

JL.

Modelling and design of a novel air-spring for a suspension seat. J Sound Vib 2010; 329: 4354–4366.

21.

Löcken

Welsch

The dynamic characteristic and hysteresis effect of an air spring. Int J Appl Mech Eng 2015; 20: 127–145.

22.

Lee

SJ.

Development and analysis of an air spring model. Int J Autom Technol 2010; 11: 471–479.

23.

Yin

Jiang

Shangguan

WB.

Complex stiffness model of an air spring with auxiliary chamber considering inertial effects of gas in connecting pipeline. Proc IMechE, Part D: J Automobile Engineering. Epub ahead of print 7 February 2022. DOI: 10.1177/09544070221075425

24.

Zheng

Shangguan

Rakheja

Modeling and performance analysis of convoluted air springs as a function of the number of bellows. Mech Syst Signal Process 2021; 159: 107858.

25.

Yin

, et al. A new dynamic stiffness model with hysteresis of air springs based on thermodynamics. J Sound Vib 2022; 521: 116693.

26.

Zheng

Shangguan

Rakheja

Modeling and analysis of time-domain nonlinear characteristics of air spring with an auxiliary chamber. Mech Syst Signal Process 2022; 176: 109161.

27.

Anderson

JD.

Fundamentals of aerodynamics. New York, NY: McGraw-Hill Education, 2017.

28.

Kim

Hong

MS.

The latest pneumatic engineering. Seoul: Bookshill Press, 2004.

29.

Seo

JJ.

Hydraulic-pneumatic. Gyeonggi: Hyungseul Press, 2000.

30.

Quaglia

Sorli

Air suspension dimensionless analysis and design procedure. Veh Syst Dyn 2001; 35: 443–475.

31.

Singiresu

SR.

Mechanical vibrations. Upper Saddle River, NJ: Pearson Education Limited, 2018.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.02 MB

0.00 MB

A universal dynamical model of dual-chamber air springs with experimental validation

Abstract

Keywords

Get full access to this article

References

Supplementary Material