Behaviour of ballast under principal stress rotation: Multi-laminate approach for moving loads

Railway tracks are subjected to millions of loading cycles over time and at high speeds, these moving trains induce dynamic amplification of vertical stresses and rotation of principal stress axes in the track layers. It is important to predict and analyse the behaviour of ballast under these loads...

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Bibliographic Details
Published inComputers and geotechnics Vol. 125; p. 103655
Main Authors Malisetty, Rakesh Sai, Indraratna, Buddhima, Vinod, Jayan
Format Journal Article
LanguageEnglish
Published New York Elsevier Ltd 01.09.2020
Elsevier BV
Subjects
Constitutive models
Deformation
High speed rail
Laminates
Loads (forces)
Mathematical models
Moving loads
Multilaminate
Plasticity
Principal stress rotation
Railroad ballast
Railway tracks
Rotation
Shear stress
Stability
Stress ratio
Surface stability
Tracks (paths)
Traffic induced stress paths
Traffic induced stress paths
Multilaminate
Principal stress rotation
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Summary:Railway tracks are subjected to millions of loading cycles over time and at high speeds, these moving trains induce dynamic amplification of vertical stresses and rotation of principal stress axes in the track layers. It is important to predict and analyse the behaviour of ballast under these loads with complex stress paths involving principal stress rotation. In this paper, a constitutive model based on a multi-laminate framework is used to predict the deformation and degradation of ballast under complex stress paths. The yield and plastic potential surfaces are developed based on a non-linear critical state and bounding surface plasticity concepts. The proposed model is validated with independent test data to capture the influence of confining stress, loading frequency, Cyclic Stress Ratio (CSR) and Shear Stress Ratio (ητ) on the permanent strain response. Furthermore, the response of ballast under traffic loading stress paths with different CSR and ητ is analysed. These model predictions show that higher CSRand ητ values lead to exacerbated particle breakage of ballast, large and unstable axial strains and dilatant volumetric strains. Furthermore, a stability surface is proposed based on model predictions, to estimate the allowable CSR and ητ for a stable response.
ISSN:0266-352X
1873-7633
DOI:10.1016/j.compgeo.2020.103655