Authors: Ngoc Trung Ngo, Buddhima Indraratna, Cholachat Rujikiathmakjornr

Abstract:

For several hundred years, the design of railway tracks has practically remained unchanged. Traditionally, rail tracks are placed on a ballast layer due to several reasons, including economy, rapid drainage, and high load bearing capacity. The primary function of ballast is to distributing dynamic track loads to sub-ballast and subgrade layers, while also providing lateral resistance and allowing for rapid drainage. Upon repeated trainloads, the ballast becomes fouled due to ballast degradation and the intrusion of fines which adversely affects the strength and deformation behaviour of ballast. This paper presents the use of three-dimensional discrete element method (DEM) in studying the shear behaviour of the fouled ballast subjected to direct shear loading. Irregularly shaped particles of ballast were modelled by grouping many spherical balls together in appropriate sizes to simulate representative ballast aggregates. Fouled ballast was modelled by injecting a specified number of miniature spherical particles into the void spaces. The DEM simulation highlights that the peak shear stress of the ballast assembly decreases and the dilation of fouled ballast increases with an increase level of fouling. Additionally, the distributions of contact force chain and particle displacement vectors were captured during shearing progress, explaining the formation of shear band and the evolutions of volumetric change of fouled ballast.

Keywords: Railway ballast, coal fouling, discrete element modelling, discrete element method.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1338616

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1588

References:

[1] Selig, E.T. and J.M. Waters, Track geotechnology and substructure management. 1994: Thomas Telford, London.
[2] Ngo, N.T., B. Indraratna, and C. Rujikiatkamjorn. “DEM simulation of the behaviour of geogrid stabilised ballast fouled with coal”. Computers and Geotechnics. 2014. 55(2014): pp. 224-231.
[3] Indraratna, B., N.T. Ngo, and C. Rujikiatkamjorn. “Studying the Deformation of Coal Fouled Ballast Stabilised with Geogrid under Cyclic Load”. Journal of Geotechnical and Geoenvironmental Engineering, ASCE. 2013. 139(8): pp. 1275-1289.
[4] Indraratna, B., Ngo, N., Rujikiatkamjorn, C. , and Vinod, J.. "Behavior of Fresh and Fouled Railway Ballast Subjected to Direct Shear Testing: Discrete Element Simulation". International Journal of Geomechanics. 2014.14(1): 34-44.
[5] Feldman, F. and Nissen, D. "Alternative testing method for the measurement of ballast fouling". Conference on Railway Engineering. (2002). Wollongong, RTSA.
[6] Indraratna, B., N.T. Ngo, and C. Rujikiatkamjorn. “Behavior of geogridreinforced ballast under various levels of fouling”. Geotextiles and Geomembranes. 2011. 29(3): pp. 313-322.
[7] Bathurst, R.J. and G.P. Raymond. ‘Geogrid reinforcement of ballasted track”. Transportation Research Record. 1987. 1153: p. 8-14.
[8] Brown, S.F., N.H. Thom, and J. Kwan. “Optimising the geogrid reinforcement of rail track ballast”. In Railfound Conference. 2006. Birmingham.
[9] McDowell, G. R., Harireche, O., Konietzky, H., Brown, S. F. , and Thom, N. H. "Discrete element modelling of geogrid-reinforced aggregates". Proceedings of the ICE - Geotechnical Engineering. (2006). 159(1): 35-48.
[10] Lackenby, J., Indraratna, B., McDowell, G. R. , and Christie, D.. "Effect of confining pressure on ballast degradation and deformation under cyclic triaxial loading". Géotechnique. (2007). 57(6): 527–536..
[11] Indraratna, B., S. Nimbalkar, and N. Tennakoon, The Behaviour of Ballasted Track Foundations: Track Drainage and Geosynthetic Reinforcement. GeoFlorida 2010: Advances in Analysis, Modeling & Design (GSP 199), 2010a. Fratta, D., Puppala, A. and Muhunthan, B. (Eds.) p. 2378-2387.
[12] Cundall, P.A. and O.D.L. Strack. “A discrete numerical model for granular assemblies”. Geotechnique. 1979. 29(1): p. 47-65.
[13] Itasca, Particle flow code in three dimensions (PFC3D). Itasca Consulting Group, Inc., Minnesota, 2008.
[14] Lobo-Guerrero, S. and L.E. Vallejo. “Discrete element method analysis of railtrack ballast degradation during cyclic loading”. Granular Matter. 2006. 8(3-4): pp. 195-204.
[15] Ferellec, J.F. and G.R. McDowell. “Modelling of ballast–geogrid interaction using the discrete-element method”. Geosynthetics International. 2012. 19(6):pp. 470–479.
[16] Lim, W.L. and G.R. McDowell. “Discrete element modelling of railway ballast’. Granular Matter. 2005. 7(1): p. 19-29.
[17] Cui, L. and C. O'Sullivan. “Exploring the macro- and micro-scale response of an idealised granular material in the direct shear apparatus’. Geotechnique. 2006. 56(7): p. 455-468.
[18] Zhang, L. and C. Thornton. “DEM simulation of the direct shear test”. in 15th ASCE Engineering Mechanics Conference. June 2-5, 2002, Columbia University, New York, NY. 2002.