Open Access Open Access  Restricted Access Subscription Access

Finite Element Simulation of Wheel-Rail Interaction:Technical Note


Affiliations
1 Mech. and Industrial Dept., Indian Institute of Tech. Roorkee, Uttarakhand, India
 

   Subscribe/Renew Journal


This paper deals with quasi-static analysis of wheel-rail interaction. The model has been developed for analysing the contact patches behaviour, pressure distribution, von mises stress and strain. A solid model has been developed using SOLIDWORKS on the basis of UIC-60 rail profile and S-1002 wheel profile. Finite element analysis of the solid model has been done using ANSYS software. It has been observed that wheel-rail interaction is nonlinear and exceeded the yield strength of wheel material. The analysis of the worn thread of wheel has enabled the identification of the contact patches and critical sections of the wheel-rail interface.

Keywords

Finite Element Analysis, Wheel-Rail Interaction, Contact Patches, Contact Stress, ANSYS.
User
Subscription Login to verify subscription
Notifications
Font Size

  • GENSYS Users Manual, Release 9910.
  • S.K. Sharma, R.C. Sharma, A. Kumar and S. Palli. 2015. Challenges in rail vehicle-track modeling and simulation, Int. J. Vehicle Structures & Systems, 7(1), 1-9. https://doi.org/10.4273/ijvss.7.1.01.
  • R.C. Sharma. 2012. Recent advances in railway vehicle dynamics, Int. J. Vehicle Structures & Systems, 4(2), 52-63. https://doi.org/10.4273/ijvss.4.2.04.
  • S. Iwnicki. 1998. The Manchester benchmarks for rail vehicle simulation, Int. J. Vehicle Mechanics & Mobility, 30(3-4), 295-313.
  • J.L. Smith. 1953. Stresses due to tangential and normal loads on an elastic solid with application to some contact stress problems, J. Appl. Mech., 157-166.
  • D.O. Haines. 1963. Contact stress distribution on elliptical contact surfaces subjected to radial and tangential forces, Proc. IMechE, 177(4), 45-54.
  • A. Sackfield and D.A. Hills. 1983. Some useful results in the classical Hertz contact problem, J. Strain Analysis for Engg. Design, 18(2), 101-105.
  • A.S. Sladkowski. 2005. Analysis of wheel-rail interaction using FE software, Wear, 258, 1217-1223. https://doi.org/10.1016/j.wear.2004.03.032.
  • M. Wiest, E. Kassa, W. Daves, J.C.O. Nielsen and H. Ossberger. 2008. Assessment of methods for calculating contact pressure in wheel-rail/switch contact, Wear, 265, 1439-45. https://doi.org/10.1016/j.wear.2008.02.039.
  • R.C. Sharma and S. Palli. 2016, Analysis of creep force and its sensitivity on stability and vertical-lateral ride for railway vehicle, Int. J. Vehicle Noise & Vibration, 12(1), 60-76. https://doi.org/10.1504/IJVNV.2016.077474.
  • G.P. Donzella. 2010. A failure assessment diagram for components subjected to rolling contact loading, Int. J. Fatigue, 256-268. https://doi.org/10.1016/j.ijfatigue.2009.06.016.
  • V. Monfared. 2011. A new analytical formulation for contact stress and prediction of the crack propagation path in rolling bodies and comparing with finite element model (FEM) results statically, Int. J. Phys. Sci., 6(15), 3613-3618.
  • P.T. Zwierczyk and K. VĂ¡radi. 2014. Frictional contact FE analysis in a railway wheel-rail contact, Periodica Polytechnica, 58(2), 93-99. https://doi.org/10.3311/PPme.7229.
  • O.K.M.A. Arslan. 2012. 3-D Railway wheel contact using FEA, Advance Engg. Software, 325-331.

Abstract Views: 335

PDF Views: 141




  • Finite Element Simulation of Wheel-Rail Interaction:Technical Note

Abstract Views: 335  |  PDF Views: 141

Authors

Shiv Prakash Dubey
Mech. and Industrial Dept., Indian Institute of Tech. Roorkee, Uttarakhand, India
Satish C. Sharma
Mech. and Industrial Dept., Indian Institute of Tech. Roorkee, Uttarakhand, India
Suraj P. Harsha
Mech. and Industrial Dept., Indian Institute of Tech. Roorkee, Uttarakhand, India

Abstract


This paper deals with quasi-static analysis of wheel-rail interaction. The model has been developed for analysing the contact patches behaviour, pressure distribution, von mises stress and strain. A solid model has been developed using SOLIDWORKS on the basis of UIC-60 rail profile and S-1002 wheel profile. Finite element analysis of the solid model has been done using ANSYS software. It has been observed that wheel-rail interaction is nonlinear and exceeded the yield strength of wheel material. The analysis of the worn thread of wheel has enabled the identification of the contact patches and critical sections of the wheel-rail interface.

Keywords


Finite Element Analysis, Wheel-Rail Interaction, Contact Patches, Contact Stress, ANSYS.

References





DOI: https://doi.org/10.4273/ijvss.10.3.13