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Abstract

Conventional passive suspension is effective for a particular frequency for which it is designed and fails to serve the purpose below a fixed frequency. Semi-active and active suspensions provide better isolation than passive ones but have limitations. The present work proposes a finite element model of a railway vehicle coach. A Nishimura air spring with a non-linear damper is provided between bogie frame and wheel axle to isolate vibrations in carbody. The ride behavior of the system is analyzed based on ISO comfort specifications and compared the same with passive suspension in the secondary suspension system. Present analytical and FE models are validated by comparing vertical and lateral PSD acceleration curves obtained from these formulations with the same obtained from the experimental test. It is observed that a non-linear air spring in secondary suspension provides a significant improvement in the vertical ride behavior of the railway vehicle system.

Keywords

railway vehicle air spring secondary suspension passive suspension ride behavior

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References

Facchinetti

Mazzola

Alfi

, et al. Mathematical modeling of the secondary air spring suspension in railway vehicles and its effect on safety and ride comfort. Veh Syst Dyn 2010; 48: 429–449.

Oda

Nishimura

. Vibration of air suspension bogies and their design. Bulletin of JSME 1970; 13: 43–50.

Alonso

Giménez

Nieto

, et al. Air suspension characterisation and effectiveness of a variable area orifice. Veh Syst Dyn 2010; 48(S1): 271–286.

Mendia-Garcia

Gil-Negrete Laborda

Pradera-Mallabiabarrena

, et al. A survey on the modelling of air springs – secondary suspension in railway vehicles. Veh Syst Dyn 2022; 60(3): 835–864.

Mendia-Garcia

Gil-Negrete

Nieto

, et al. Analysis of the axial and transversal stiffness of an air spring suspension of a railway vehicle: mathematical modelling and experiments. Int J Real Ther 2024; 12(1): 56–75.

Nguyen

Ahn

. An air spring vibration isolator based on a negative stiffness structure for vehicle seat. Appl Sci 2021; 11: 11539.

. Mathematical modeling and characteristic analysis of the vertical stiffness for railway vehicle air spring system. Math Probl Eng 2020; 2020(1): 1–12.

Torggler

Dutzler

Oberdorfer

, et al. Investigating damage mechanisms in cord-rubber composite air spring bellows of rail vehicles and representative specimen design. Appl Compos Mater 2023; 30: 1979–1999.

Kamada

Karaki

. Active vertical vibration suppression of high-speed railway vehicles by controlling internal pressure of the air spring using μ-synthesis control. Veh Syst Dyn 2024; 62(7): 1621–1636.

10.

Asami

Yokota

Ise

, et al. Theoretical and experimental analysis of the nonlinear characteristics of an air spring with an orifice. J Vib Acoust 2013; 135: 011012.

11.

Quaglia

Sorli

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

12.

Liu

Lee

. Model development and experimental research on an air spring with auxiliary reservoir. Int J Automot Technol 2011; 12(6): 839–847.

13.

Fongue

. Air spring air damper: modelling and dynamic performance in case of small excitations. SAE Int J Passeng Cars Mech Syst 2013; 6: 1196–1208.

14.

Sharma

Lavania

, et al. Industry-driven approach for ANFIS-based intelligent control suspension system with MR damper for enhanced ride quality in passenger rail vehicles for technological investigations. Natl Acad Sci Lett 2024; 47(4): 391–394.

15.

Sharma

Gopala Rao

LVV

Sharma

, et al. Analysis of lateral stability and ride of an Indian railway constrained dual-axle bogie frame. SAE Int J Commer Veh 2023; 16(2): 213–228.

16.

Bhardawaj

Sharma

, et al. Modeling of biomechanical human body model for seat to head transmissibility analysis. Noise Vib Worldw 2023; 54(2-3): 62–74.

17.

Sam Paul

Mohan Gift

Jawar

, et al. Finite Element analysis of Bogie frame. In: Proceedings of 18th National Convention of Mechanical Engineers, 2002, pp. 331–338.

18.

Mazzola

Berg

. Secondary suspension of railway vehicles-air spring modeling: performance and critical issues. Proc Inst Mech Eng F J Rail Rapid Transit 2014; 228: 225–241.

19.

Presthus

. Derivation of air spring model parameters for train simulation. Master’s Thesis. Sweden: Luleå University of Technology, 2002.

20.

Berg

. A three-dimensional air spring model with friction and orifice damping. In: The Dynamics of Vehicles on Roads and on Tracks-Supplement to Vehicle System Dynamics, Proceedings of the 16th IAVSD Symposium, Pretoria, South Africa, 1999, vol 33, pp. 528–539.