Investigating the Influence of Auxiliary Rails on Dynamic Behavior of Railway Transition Zone by a 3D Train-Track Interaction Model

Heydari-Noghabi, Hamidreza; Varandas, José N.; Esmaeili, Morteza; Zakeri, Jabbar Ali

doi:10.1590/1679-78253906

Cited by 27 publications

(11 citation statements)

References 16 publications

(8 reference statements)

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“…The stiffness of the tracks was computed using the Talbot-Wasiutynski method(Ali Zakeri and Abbasi 2012, Heydari-Noghabi, Varandas et al 2017, Sadeghi, Liravi et al 2017. For this purpose, the vertical deflections of the rail relative to the tunnel invert were measured for two different axle loads.…”

Section: Field Measurements Proceduresmentioning

confidence: 99%

Effectiveness of track stiffness reduction in attenuation of metro induced vibrations received by historical buildings

Sadeghi

Esmaeili

2018

Lat. Am. j. solids struct.

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Preservation of historical buildings is a main challenge in civil engineering field. One of the main concerns in this regard is metro induced vibration received by historical structures. There is a need to evaluate effectiveness of vibration mitigation measures in preservation of monumental buildings. The most widely used method of reducing metro vibrations is changes in the structure of the vibration source (not sufficiently investigated in the literature). In response to this need, effectiveness of track stiffness reduction in mitigation of vibration was investigated in this research. Comprehensive field tests were conducted in the Iranian metro lines. The track stiffness as well as the induced vibrations were measured. It was shown that track stiffness has noticeable role in the track levels of vibration, and in turn in metro vibration reduction. The amounts of vibration reduction were derived as a function of track stiffness reduction.

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Section: Field Measurements Proceduresmentioning

confidence: 99%

Effectiveness of track stiffness reduction in attenuation of metro induced vibrations received by historical buildings

Sadeghi

Esmaeili

2018

Lat. Am. j. solids struct.

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“…For example, this simple coupling model was employed to study the response of a track when the train ran on a transition zone [4]. The similar methodology was also used to establish a simplified three-dimentional (3D) train-track model to conduct sensitivity analysis on the vehicle speed, vehicle load, auxiliary track number, and track stiffness [5]. More recently, the dynamic responses of track in the marine environment were also modelled by the train-track coupling model [6].…”

Section: Introductionmentioning

confidence: 99%

Dynamic Response of a Bridge–Embankment Transition with Emphasis on the Coupled Train–Track–Subgrade System

Zhang

Guo

et al. 2020

Applied Sciences

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Dynamic response of a bridge–embankment transition is determined by, and therefore an indicator of, the coupled train–track–subgrade system. This study aims to investigate the approach of coupling the train–track–subgrade system to determine the dynamic response of the transition. The coupled system is established numerically based on the weak energy variation, the overall Lagrange format of D’Alembert’s principle and dynamics of the multi-rigid body, which is verified by in-site measurements. With this model, the influence of rail bending, differential settlement and other factors on the dynamic performance of the transition system is analyzed. The results show that when the train driving speed is 350 km/h, basic requirements should be satisfied. These requirements include that the irregularity bending of the bridge–embankment transition section should be less than 1/1000, the rigidity ratio should be controlled within 1:6, and the length of the transition section should be more than 25 m. In addition, the differential settlement should not exceed 5 mm. Among these factors, the differential settlement and the bending of the rail surface are the main ones to cause the severe dynamic irregularity of the transition section. Our analysis also indicates a requirement to strengthen the 18 m and 25–30 m distance from the abutment tail and the bed structure.

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“…16 Although a review of the literature related to the ballasted tracks indicates that rail irregularity and rail pad stiffness have the most effects on the wheel/ rail force, very few works have been carried out on the effect of rail pad stiffness on the wheel/rail force in slab track. For instance, Heydari-Noghabi et al 17 simulated the vehicle/slab track interaction using a two-dimensional (2D) numerical model. Their model consists of rail, rail pad, slab, hydraulically bonded layer, and subgrade.…”

Section: Introductionmentioning

confidence: 99%

“…The interaction of wheel and rail was considered as the nonlinear Hertz spring in their model. In the research carried out by Heydari-Noghabi et al, 17 the effect of rail pad stiffness on the slab deflection is investigated in the railway transition zone without any rail irregularity. Lei and Zhang 18 developed a three-layer numerical model of vehicle/ slab track interaction.…”

Section: Introductionmentioning

confidence: 99%

Effect of rail pad stiffness on the wheel/rail force intensity in a railway slab track with short-wave irregularity

Khajehdezfuly

2019

Proceedings of the Institution of Mechanical Engineers, Part F:

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In this paper, a two-dimensional numerical model is developed to investigate the effect of rail pad stiffness on the wheel/rail force in a slab track with harmonic irregularity. The model consists of a vehicle, nonlinear Hertz spring, rail, rail pad, concrete slab, resilient layer, concrete base, and subgrade. The rail is simulated using the Timoshenko beam element for considering the effects of high-frequency excitation produced by short-wave irregularity. The results obtained from the model are compared with those available in the literature and from the field to prove the validity of the model. Through a parametric study, the effect of variations in rail pad stiffness, vehicle speed, and harmonic irregularity on the wheel/rail force is investigated. For the slab track without any irregularity, the wheel/rail force is at maximum when the vehicle speed reaches the critical speed. As the rail pad stiffness increases, the critical speed increases. When the amplitude of irregularity is high, wheel jumping phenomenon may occur. In this situation, as the vehicle speed and rail pad stiffness are increased, the dynamic wheel/rail force is increased. In the low-frequency range, the wheel/rail force increases as the rail pad stiffness increases. In the high-frequency range, the wheel/rail force increases as the rail pad stiffness is decreased.

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Investigating the Influence of Auxiliary Rails on Dynamic Behavior of Railway Transition Zone by a 3D Train-Track Interaction Model

Cited by 27 publications

References 16 publications

Effectiveness of track stiffness reduction in attenuation of metro induced vibrations received by historical buildings

Effectiveness of track stiffness reduction in attenuation of metro induced vibrations received by historical buildings

Dynamic Response of a Bridge–Embankment Transition with Emphasis on the Coupled Train–Track–Subgrade System

Effect of rail pad stiffness on the wheel/rail force intensity in a railway slab track with short-wave irregularity

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