Sage Journals: Discover world-class research

Abstract

In this paper, a sliding mode control of air suspension with auxiliary chamber subject to system disturbance is proposed for perturbation factors such as nonlinear variation of stiffness damping in air suspension systems, aiming to improve the suspension performance during operation of commercial vehicles. Combine thermodynamics and suspension dynamics theory to establish nonlinear model of the air suspension with auxiliary chamber, consider the nonlinear stiffness and damping of the air spring, and sensor noise and other disturbances, and establish the system state space equations. The nonlinear disturbance observer is designed to estimate the disturbance force and noise disturbance in the system, and the sliding mode controller is designed to calculate the desired control damping force according to the disturbance estimation value. Finally, numerical simulations of the air suspension control system considering the nonlinear force variation of the air spring and external disturbances are carried out on simulated road surface and real road surface data. The results show that the proposed control strategy has strong robustness to the system external disturbance variations, which is conducive to improving the smoothness of the vehicle.

Keywords

Air suspension with auxiliary chamber suspension control nonlinear disturbance observer

Get full access to this article

View all access options for this article.

References

Nguyen

Jiao

Zhang

Control performance of damping and air spring of heavy truck air suspension system with optimal fuzzy control. SAE Int J Veh Dyn Stab NVH 2020; 4(10-04-02-0013): 179–194.

Zhang

Wang

, et al. Semi-active control of air suspension with auxiliary chamber subject to parameter uncertainties and time-delay. Int J Robust Nonlinear Control 2020; 30(17): 7130–7149.

NYP

. Static analysis of low frequency isolation model using pneumatic cylinder with auxiliary chamber. Int J Precis Eng Manuf 2020; 21(4): 681–697.

Karimi Eskandary

Khajepour

Wong

, et al. Analysis and optimization of air suspension system with independent height and stiffness tuning. Int J Autom Technol 2016; 17(5): 807–816.

Jiang

Chen

, et al. Semi-active control of a new quasi-zero stiffness air suspension for commercial vehicles based on event-triggered H∞ dynamic output feedback. Nonlinear Dyn 2023; 111: 12161–12180

Oman

Nagode

The influence of piston shape on air-spring fatigue life. Fatigue Fract Eng Mater Struct 2018; 41(5): 1019–1031.

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.

Mazzola

Berg

Secondary suspension of railway vehicles-air spring modelling: performance and critical issues. Proc IMechE, Part F: J Rail and Rapid Transit 2014; 228(3): 225–241.

Quaglia

Sorli

Air suspension dimensionless analysis and design procedure. Veh Syst Dyn 2001; 35(6): 443–475.

10.

Lee

SJ.

Development and analysis of an air spring model. Int J Autom Technol 2010; 11(4): 471–479.

11.

Yin

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

12.

Zheng

Shangguan

WB.

A combined analytical model for orifice-type and pipe-type air springs with auxiliary chambers in dynamic characteristic prediction. Mech Syst Signal Process 2023; 185: 109830.

13.

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.

14.

Wang

Kin Wong

Zhao

, et al. Observer-based robust gain-scheduled control for semi-active air suspension systems subject to uncertainties and external disturbance. Mech Syst Signal Process 2022; 173: 109045.

15.

Gokul Prassad

Malar Mohan

. A contemporary adaptive air suspension using LQR control for passenger vehicles. ISA Trans 2019; 93: 244–254.

16.

Xie

Zhao

, et al. Fuzzy finite-frequency output feedback control for nonlinear active suspension systems with time delay and output constraints. Mech Syst Signal Process 2019; 132: 315–334.

17.

Pang

Zhang

Chen

, et al. Design of a coordinated adaptive backstepping tracking control for nonlinear uncertain active suspension system. Appl Math Model 2019; 76: 479–494.

18.

Sun

Yuan

Cai

, et al. Model predictive control of an air suspension system with damping multi-mode switching damper based on hybrid model. Mech Syst Signal Process 2017; 94: 94–110.

19.

Liu

Chen

Adaptive sliding mode control for uncertain active suspension systems with prescribed performance. IEEE Trans Syst Man Cybern Syst 2020; 51(10): 6414–6422.

20.

Yoon

Kim

Choi

SB.

Response time of magnetorheological dampers to current inputs in a semi-active suspension system: modeling, control and sensitivity analysis. Mech Syst Signal Process 2021; 146: 106999.

21.

Chen

Jiang

Tang

, et al. Revised adaptive active disturbance rejection sliding mode control strategy for vertical stability of active hydro-pneumatic suspension. ISA Trans 2023; 132: 490–507.

22.

Liu

Pan

Barrier function-based adaptive sliding mode control for application to vehicle suspensions. IEEE Trans Transp Electrification 2020; 7(3): 2023–2033.

23.

Deshpande

Shendge

Phadke

SB.

Dual objective active suspension system based on a novel nonlinear disturbance compensator. Veh Syst Dyn 2016; 54(9): 1269–1290.

24.

Deshpande

Shendge

Phadke

SB.

Nonlinear control for dual objective active suspension systems. IEEE Trans Intell Transp Syst 2016; 18(3): 656–665.

25.

Pusadkar

Chaudhari

Shendge

, et al. Linear disturbance observer based sliding mode control for active suspension systems with non-ideal actuator. J Sound Vib 2019; 442: 428–444.

26.

Chen

Zhang

, et al. Damping characteristic analysis and experiment of air suspension with auxiliary chamber. IFAC-PapersOnLine 2018; 51(17): 166–172.

27.

Moheyeldein

Abd-El-Tawwab

Abd El-gwwad

, et al. An analytical study of the performance indices of air spring suspensions over the passive suspension. Beni-Suef Univ J Appl Sci 2018; 7(4): 525–534.

28.

Wong

Wang

Zhao

Robust finite-time fault-tolerant control for vehicle height and posture regulation with air suspension system subject to actuator faults, uncertainties and external disturbance. Nonlinear Dyn 2023; 111(11): 10113–10130.

Sliding mode control of air suspension with auxiliary chamber subject to system disturbance

Abstract

Keywords

Get full access to this article

References