Open Access
Issue
Mechanics & Industry
Volume 19, Number 3, 2018
Article Number 307
Number of page(s) 15
DOI https://doi.org/10.1051/meca/2018030
Published online 12 September 2018
  1. A.S.V. Iryn, A. Zavatny, Determination of longitudinal forces in the cars automatic couplers at train electrodynamic braking, 9th International Scientific Conference Transbalities, 3, pp. 415–421, 2016 [Google Scholar]
  2. B.M. OleksandrMokin, Y. Lobatiuk, Simulation model for the monitoring system of air brake of the train and determining the place of breakage, Int. J. Traffic Transp. Eng. 4 (2014) 184–188 [Google Scholar]
  3. D.H. David Barney, G. Nikandros, Calculating train braking distance, 6th Australian Workshop on Safety Critical Systems and Software (SCS'01), 3 pp. 1–7, 2001 [Google Scholar]
  4. R.V. MarinM, Generalized model of the pressure evolution within the braking system of a vehicle, Int. J. Eng. 1 (2013) 1–6 [Google Scholar]
  5. C. CRĂCIUN, T. MAZILU, Simulation of the longitudinal dynamics forces developed in the body of passenger trains, Int. J. Eng. 3 (2014) 1–8 [Google Scholar]
  6. L. Cantone, T. Durand, Longitudinal forces evaluation of sncf trains, 9th World Congress on Railway Research, 3 pp. 1–12, 2011 [Google Scholar]
  7. X.B. LuYi, G. Bin, Dynamic modeling and experimental verification of bus pneumatic brake system, J. Open Mech. Eng. J. 9 (2015) 52–57 [CrossRef] [Google Scholar]
  8. S.C.S. Sachin, S. Harak, S.P. Harsha, Dynamic analysis of draft gear and draft pad of freight wagon due to localized defects using fem, Int. J. Acoust. Vib. 21 (2015) 281–291 [Google Scholar]
  9. C. Cole, Y.Q. Sun, Simulated comparisons of wagon coupler systems in heavy haul trains, J. Rail Rapid Transit. 220 (2006) 247–256 [CrossRef] [Google Scholar]
  10. O.O.D.Y. Jeong, M.L. Lyons, A. Perlman, Equations of motion for train derailment dynamics, ASME Rail Transp. Division Fall Tech. Conf. 38 (2007) 265–280 [Google Scholar]
  11. W.M.Q. Xu, Z.Q.S. Luo, Coupler rotation behavior and its effect on heavy haul trains, J. Vehicle Mech. Mobility 51 (2013) 1818–1838 [Google Scholar]
  12. W.D. QuTianwei, Ma. Weihua, L. Shihui1, Influence of coupler and buffer on dynamics performance of heavy haul locomotive, J. Open Mech. Eng. 5 (2015) 1033–1038 [Google Scholar]
  13. J.Z. LaiWe, Q. Wang, Investigation of in-train stability and safety assessment for rail vehicles during braking, J. Open Mech. Eng. 30 (2016) 1505–1525 [Google Scholar]
  14. P.K. Jha, S. Gokhale, Modeling and validation of gatimaan express with matlab/simulink, Int. J. Transport Dev. Integration, 162 (2016) 381–396 [Google Scholar]
  15. RDSO, Maintenance manual for bg coaches of lhb design, in Research Designs Standards Organization, pp.11–44, Ministry of Railways, 2012 [Google Scholar]
  16. V. Garg, R.V. Dukkipati, Dynamics of Railway Vehicle System, Academic Press Canada, Ontario, 1984 [Google Scholar]
  17. S. Maksym, C. Colin, Q.S. Yan, M. Mitchell, S. Valentyn, M. Tim, Design and Simulation of Rail Vehicles, CRC Press, Boca Raton, 2014 [Google Scholar]
  18. S. Iwnicki, Handbook of Railway Vehicle Dynamics, CRC Press, Boca Raton, 2006 [CrossRef] [Google Scholar]
  19. A. Nasr, S. Mohammadi, The effects of train brake delay time on in-train forces, Proc IMechE, Part F: J Rail Rapid Transit, 224 (2010) 1033–1038 [CrossRef] [Google Scholar]
  20. B. Allota, L. Banchi, L. Pugi, M. Malvezzi, P. Presciani, A parametric library for the simulation of a union internationale des chemins de fer (uic) pneumatic braking system, Proc IMechE, Part F: J Rail Rapid Transit, 218, 2003 [Google Scholar]

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