The study of railway dynamics is still a productive area of research given the rapid technological evolution of this transport system regarding load and speed. Morocco is no exception to this rule, especially after the commissioning of the first high-speed line in Africa. This study describes herein an experiment to measure vertical and transverse accelerations in a locomotive on a railroad line connecting the two cities of Mchraa Ben Abbou and Marrakech. The observed accelerations constitute the vehicle's dynamic responses while running at a constant speed on a track with irregularities (also known as track geometry), which is considered the main driving force of train dynamics and the track system. They are used to evaluate passenger comfort and safety. It can also be observed that body accelerations increase with the introduction of track irregularities as compared to a smoother track. In this study, an analysis of these experimental measurements is performed based on boxplot simulations comparing the distributions of the transverse and vertical components of vehicle acceleration. It was found that the medians and first and third quartiles of both distributions are very close.

 

Doi: 10.28991/CEJ-2022-08-10-014

Full Text: PDF

Track Irregularities; Train-Track Interaction; Railway Line; Vehicle Acceleration.

Malveiro, J., Sousa, C., Ribeiro, D., & Calçada, R. (2018). Impact of track irregularities and damping on the fatigue damage of a railway bridge deck slab. Structure and Infrastructure Engineering, 14(9), 1257–1268. doi:10.1080/15732479.2017.1418010.

Xu, L., Li, Z., Zhao, Y., Yu, Z., & Wang, K. (2022). Modelling of vehicle-track related dynamics: a development of multi-finite-element coupling method and multi-time-step solution method. Vehicle System Dynamics, 60(4), 1097–1124. doi:10.1080/00423114.2020.1847298.

Pecile, B. (2017). Dynamic model of vehicle-railway interaction in the presence of geometric defects on the surfaces in contact. PhD Thesis, University of Valenciennes and Hainaut-Cambresis, Valenciennes, France. (In French).

Haigermoser, A., Luber, B., Rauh, J., & Gräfe, G. (2015). Road and track irregularities: Measurement, assessment and simulation. Vehicle System Dynamics, 53(7), 878–957. doi:10.1080/00423114.2015.1037312.

Nielsen, J. C. O., & Li, X. (2018). Railway track geometry degradation due to differential settlement of ballast/subgrade – Numerical prediction by an iterative procedure. Journal of Sound and Vibration, 412, 441–456. doi:10.1016/j.jsv.2017.10.005.

Kassou, F., Benbouziyane, J., Ghafiri, A., & Sabihi, A. (2021). A New Approach to Analyse the Consolidation of Soft Soils Improved by Vertical Drains and Submitted to Progressive Loading. KSCE Journal of Civil Engineering, 25(1), 51–59. doi:10.1007/s12205-020-0060-z.

Lamprea-Pineda, A. C., Connolly, D. P., & Hussein, M. F. M. (2022). Beams on elastic foundations – A review of railway applications and solutions. Transportation Geotechnics, 33, 100696. doi:10.1016/j.trgeo.2021.100696.

Blanco-Saura, A. E., Velarte-González, J. L., Ribes-Llario, F., & Real-Herráiz, J. I. (2018). Study of the dynamic vehicle-track interaction in a railway turnout. Multibody System Dynamics, 43(1), 21–36. doi:10.1007/s11044-017-9579-2.

Kukulski, J., Gołębiowski, P., Makowski, J., Jacyna-Gołda, I., & Żak, J. (2021). Effective method for diagnosing continuous welded track condition based on experimental research. Energies, 14(10). doi:10.3390/en14102889.

Skarova, A., Harkness, J., Keillor, M., Milne, D., & Powrie, W. (2022). Review of factors affecting stress-free temperature in the continuous welded rail track. Energy Reports, 8, 769–775. doi:10.1016/j.egyr.2022.05.046.

El Moueddeb, M., Louf, F., Boucard, P. A., Dadié, F., Saussine, G., & Sorrentino, D. (2020). A lightweight numerical model of railway track to predict mechanical stress state in the rail. International Journal of Transport Development and Integration, 4(2), 152–162. doi:10.2495/TDI-V4-N2-152-162.

Groß-Thebing, A., Knothe, K., & Hempelmann, K. (1992). Wheel-Rail contact mechanics for short wavelengths rail irregularities. Vehicle System Dynamics, 20(Sup1), 210–224. doi:10.1080/00423119208969399.

Kedia, N. K., Kumar, A., & Singh, Y. (2021). Effect of Rail Irregularities and Rail Pad on Track Vibration and Noise. KSCE Journal of Civil Engineering, 25(4), 1341–1352. doi:10.1007/s12205-021-1345-6.

Kouroussis, G., Gazetas, G., Anastasopoulos, I., Conti, C., & Verlinden, O. (2011). Discrete modelling of vertical track-soil coupling for vehicle-track dynamics. Soil Dynamics and Earthquake Engineering, 31(12), 1711–1723. doi:10.1016/j.soildyn.2011.07.007.

Bogdevičius, M., Žygiene, R., Dailydka, S., Bartulis, V., Skrickij, V., & Pukalskas, S. (2015). The dynamic behaviour of a wheel flat of a railway vehicle and rail irregularities. Transport, 30(2), 217–232. doi:10.3846/16484142.2015.1051108.

Salcher, P., Adam, C., & Kuisle, A. (2019). A Stochastic View on the Effect of Random Rail Irregularities on Railway Bridge Vibrations. Structure and Infrastructure Engineering, 15(12), 1649–1664. doi:10.1080/15732479.2019.1640748.

Nielsen, J. C. O., Lombaert, G., & François, S. (2015). A hybrid model for prediction of ground-borne vibration due to discrete wheel/rail irregularities. Journal of Sound and Vibration, 345, 103–120. doi:10.1016/j.jsv.2015.01.021.

Soyiç Leblebici, A., & Türkay, S. (2017). Influence of Wheel-Rail Contact Stiffness on the H2 Controlled Active Suspension Design. IFAC-PapersOnLine, 50(1), 3642–3647. doi:10.1016/j.ifacol.2017.08.710.

Zhang, X., Thompson, D., & Sheng, X. (2020). Differences between Euler-Bernoulli and Timoshenko beam formulations for calculating the effects of moving loads on a periodically supported beam. Journal of Sound and Vibration, 481, 115432. doi:10.1016/j.jsv.2020.115432.

Martínez-Casas, J., Giner-Navarro, J., Baeza, L., & Denia, F. D. (2017). Improved railway wheelset–track interaction model in the high-frequency domain. Journal of Computational and Applied Mathematics, 309, 642–653. doi:10.1016/j.cam.2016.04.034.

Xu, L., Chen, X., Li, X., & He, X. (2018). Development of a railway wagon-track interaction model: Case studies on excited tracks. Mechanical Systems and Signal Processing, 100, 877–898. doi:10.1016/j.ymssp.2017.08.008.

Guo, Y., & Zhai, W. (2018). Long-term prediction of track geometry degradation in high-speed vehicle–ballastless track system due to differential subgrade settlement. Soil Dynamics and Earthquake Engineering, 113, 1–11. doi:10.1016/j.soildyn.2018.05.024.