A Time-Domain Model for the Study of High-Frequency Wheelset–Track Interaction

Wenshan Fang , José Martinez-Casas , Stefano Bruni

Urban Rail Transit ›› 2017, Vol. 3 ›› Issue (4) : 203 -213.

PDF
Urban Rail Transit ›› 2017, Vol. 3 ›› Issue (4) : 203 -213. DOI: 10.1007/s40864-017-0049-1
Original Research Papers

A Time-Domain Model for the Study of High-Frequency Wheelset–Track Interaction

Author information +
History +
PDF

Abstract

A mathematical model of dynamic wheelset–track interaction is proposed in this paper. The model is defined in the time domain in order to introduce and correctly evaluate nonlinear and time-variant phenomena related to the contact model and boundary conditions which play a very important role in rail surface degradation phenomena. The complete model can be divided into three main components: the model of the wheelset, the model of the track and the model of wheel–rail contact forces. In the paper, the wheelset is described as a rotating flexible body, and the gyroscopic and inertial effects associated with wheelset rotation are introduced to this model using an ‘Eulerian’ finite element approach based on 3D quadratic solid elements. The discrete supported track is modelled using finite Timoshenko beam element, which takes into account both the vertical and the lateral rail vibration valid up to 1500 Hz. The wheelset and the track are coupled by means of a contact model based on the nonlinear Hertz and Kalker theories. The flexible components of the interaction model make it possible to describe the train–track dynamics in a relatively high-frequency range, which allows the investigation of specific aspects such as rail corrugation. Some numerical results are presented in terms of contact forces and rail–wheel vibration speed in the paper. The effect of wheelset and track flexibility in specific frequency range on train–track interaction dynamics is briefly discussed.

Keywords

Flexible wheelset / Flexible track / Train–track interaction / High-frequency dynamics

Cite this article

Download citation ▾
Wenshan Fang, José Martinez-Casas, Stefano Bruni. A Time-Domain Model for the Study of High-Frequency Wheelset–Track Interaction. Urban Rail Transit, 2017, 3(4): 203-213 DOI:10.1007/s40864-017-0049-1

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Thompson D. Railway noise and vibration: mechanisms, modelling and means of control, 2008, London: Elsevier
[2]

Sun W, Zhou J, Thompson D, Gong D. Vertical random vibration analysis of vehicle–track coupled system using Green’s function method. Veh Syst Dyn, 2014, 52(3): 362-389

[3]

Thompson D, Jones C. A review of the modelling of wheel/rail noise generation. J Sound Vib, 2000, 231(3): 519-536

[4]

Knothe K, Grassie S. Modelling of railway track and vehicle/track interaction at high frequencies. Veh Syst Dyn, 1993, 22(3–4): 209-262

[5]

Arnold J, Kaiser I, Schupp G. Simulation of a railway vehicle’s running behaviour: how elastic wheelsets influence the simulation results. Veh Syst Dyn, 2005, 41: 242-251.
[6]

Gómez J, Vadillo E, Santamaría J. A comprehensive track model for the improvement of corrugation models. J Sound Vib, 2006, 293(3): 522-534

[7]

Kaiser I, Popp K. Interaction of elastic wheelsets and elastic rails: modelling and simulation. Veh Syst Dyn, 2006, 44(sup1): 932-939

[8]

Baeza L, Fayos J, Roda A, Insa R. High frequency railway vehicle–track dynamics through flexible rotating wheelsets. Veh Syst Dyn, 2008, 46(7): 647-659

[9]

Zhai W, Wang K. Lateral hunting stability of railway vehicles running on elastic track structures. J Comput Nonlinear Dyn, 2010, 5(4): 1-9

[10]

Baeza L, Ouyang H. A railway track dynamics model based on modal substructuring and a cyclic boundary condition. J Sound Vib, 2011, 330(1): 75-86

[11]

Baeza L, Vila P, Xie G, Iwnicki SD. Prediction of rail corrugation using a rotating flexible wheelset coupled with a flexible track model and a non-Hertzian/non-steady contact model. J Sound Vib, 2011, 330(18): 4493-4507

[12]

Di Gialleonardo E, Braghin F, Bruni S. The influence of track modelling options on the simulation of rail vehicle dynamics. J Sound Vib, 2012, 331(19): 4246-4258

[13]

Kaiser I. Refining the modelling of vehicle–track interaction. Veh Syst Dyn, 2012, 50(sup1): 229-243

[14]

Martínez-Casas J, Mazzola L, Baeza L, Bruni S. Numerical estimation of stresses in railway axles using a train–track interaction model. Int J Fatigue, 2013, 47: 18-30

[15]

Shabana AA. Dynamics of multibody systems, 2013, Cambridge: Cambridge University Press

[16]

Brown M, Shabana A. Application of multibody methodology to rotating shaft problems. J Sound Vib, 1997, 204(3): 439-458

[17]

Francesco R, Roberto A, Bruni S (2007) A time domain model for the study of high frequency train–track interaction. Paper presented at the 7th international conference on railway bogies and running gears, Budapest
[18]

Petyt M. Introduction to finite element vibration analysis, 2010, Cambridge: Cambridge University Press

[19]

Johnson KL, Johnson KL. Contact mechanics, 1987, Cambridge: Cambridge University Press
[20]

Kalker JJ. Three-dimensional elastic bodies in rolling contact, 1990, Amsterdam: Kluwer

Funding

China Scholarship Council(201407090055)

AI Summary AI Mindmap
PDF

143

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/