Emil Aggestam scite author profile

The vertical dynamic interaction between a railway vehicle and a slab track is simulated in the time domain using an extended state-space vector approach in combination with a complex-valued modal superposition technique for the linear, time-invariant and two-dimensional track model. Wheel-rail contact forces, bending moments in the concrete panel and load distributions on the supporting foundation are evaluated. Two generic slab track models including one or two layers of concrete slabs are presented. The upper layer containing the discrete slab panels is described by decoupled beams of finite length, while the lower layer is a continuous beam. Both the rail and concrete layers are modelled using Rayleigh-Timoshenko beam theory. Rail receptances for the two slab track models are compared with the receptance of a traditional ballasted track. The described procedure is demonstrated by two application examples involving: (i) the periodic response due to the rail seat passing frequency as influenced by the vehicle speed and a foundation stiffness gradient and (ii) the transient response due to a local rail irregularity (dipped welded joint). ARTICLE HISTORY

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Optimisation of slab track design considering dynamic train–track interaction and environmental impact

Aggestam

Nielsen

Lundgren

et al. 2022

Engineering Structures

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Multi-objective optimisation of transition zones between slab track and ballasted track using a genetic algorithm

Aggestam

Nielsen

2019

Journal of Sound and Vibration

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Simulation of vertical dynamic vehicle–track interaction using a three-dimensional slab track model

Aggestam

Nielsen

2020

Engineering Structures

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Calibration and validation of the dynamic response of two slab track models using data from a full-scale test rig

Theyssen

Aggestam

Zhu

et al. 2021

Engineering Structures

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Comparison of the dynamic response and environmental impact between traditional and innovative railway track systems

Aggestam

2022

International Journal of Rail Transportation

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Prediction of long-term differential track settlement in a transition zone using an iterative approach

Nasrollahi

Nielsen

Aggestam

et al. 2023

Engineering Structures

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Emil Aggestam

Numerical model reduction with error control in computational homogenization of transient heat flow

Simulation of vertical dynamic vehicle–track interaction using a two-dimensional slab track model

Optimisation of slab track design considering dynamic train–track interaction and environmental impact

Multi-objective optimisation of transition zones between slab track and ballasted track using a genetic algorithm

Simulation of vertical dynamic vehicle–track interaction using a three-dimensional slab track model

Calibration and validation of the dynamic response of two slab track models using data from a full-scale test rig

Comparison of the dynamic response and environmental impact between traditional and innovative railway track systems

Prediction of long-term differential track settlement in a transition zone using an iterative approach

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