Metamodelling of wheel–rail normal contact in railway crossings with elasto-plastic material behaviour

Skrypnyk, Rostyslav; Nielsen, Jens C. O.; Ekh, Magnus; Pålsson, Björn

doi:10.1007/s00366-018-0589-3

Cited by 21 publications

(15 citation statements)

References 22 publications

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“…The present study uses the multidisciplinary iterative methodology presented in [9]. Since the time of its original publication, the methodology has been improved in terms of computational efficiency and robustness (see [6,13]). The methodology predicts the rail damage at sampled cross-sections along the crossing rail.…”

Section: Simulation Methodologymentioning

confidence: 99%

“…The normal contact problem is solved using a Hertzian-based metamodel (see [13]) that has been calibrated against 3D FE simulations of wheel-rail contact with nonlinear material properties. The metamodel was calibrated for rail contact radii (in the plane of each rail cross-section) in the interval 20; 500 ½ � mm, wheel contact radii in the plane of the wheel cross-section and in the circumferential direction in the intervals 60; 1000 ½ � mm and 450; 480 ½ � mm, respectively, and normal wheel-rail contact loads in the interval 100; 300 ½ � kN, cf.…”

Section: Simulation Methodologymentioning

confidence: 99%

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On the influence of crossing angle on long-term rail damage evolution in railway crossings

Skrypnyk

Pålsson

Nielsen

et al. 2021

International Journal of Rail Transportation

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The rails in railway crossings are subjected to severe load environment leading to degradation of running surface due to wear and accumulated plastic deformation. To compare long-term degradation of three fixed crossings with different crossing angles, nominally designated 1:12, 1:15, and 1:18.5, a multidisciplinary simulation methodology is applied to predict damage of the crossing rail. For a given traffic scenario, including up to 65 MGT of facing move passenger traffic in through route, the results show that damage increases with increasing crossing angle. The ratio between the maximum damage for the crossings with the largest and smallest crossing angles is found to be about three in terms of wear and about two for plastic deformation. Initially high rate of plastic deformation reduces significantly after the first 2-5 MGT, and after 10-30 MGT it approaches a nearly constant value that is significantly lower than the wear rate.

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Section: Simulation Methodologymentioning

confidence: 99%

Section: Simulation Methodologymentioning

confidence: 99%

On the influence of crossing angle on long-term rail damage evolution in railway crossings

Skrypnyk

Pålsson

Nielsen

et al. 2021

International Journal of Rail Transportation

Self Cite

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“…Compared with the normal track, the current studies on railway crossings are mainly based on numerical simulation. Typical contributions include wheel-rail interaction analysis [11][12][13][14][15][16][17][18][19][20][21], damage analysis [16,17,22,23], and prediction [18,24,25] as well as crossing geometry and track stiffness optimization for better dynamic performance [16,26]. Field measurements are mainly used for the validation of numerical models.…”

Section: Methodsmentioning

confidence: 99%

Train Hunting Related Fast Degradation of a Railway Crossing—Condition Monitoring and Numerical Verification

Liu

Markine

2020

Sensors

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This paper presents the investigation of the root causes of the fast degradation of a railway crossing. The dynamic performance of the crossing was assessed using the sensor-based crossing instrumentation, and the measurement results were verified using the multi-body system (MBS) vehicle-crossing model. Together with the field inspections, the measurement and simulation results indicate that the fast crossing degradation was caused by the high wheel-rail impact forces related to the hunting motion of the passing trains. Additionally, it was shown that the train hunting was activated by the track geometry misalignment in front of the crossing. The obtained results have not only explained the extreme values in the measured responses, but also shown that crossing degradation is not always caused by the problems in the crossing itself, but can also be caused by problems in the adjacent track structures. The findings of this study were implemented in the condition monitoring system for railway crossings, using which timely and correctly aimed maintenance actions can be performed.

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“…In other words, a specific location rather than a whole turnout is selected to investigate the dynamic behavior. There have been recent attempts to deal with computational costs [27,30] which, while promising, are still insufficient to expand the simulation scale.…”

Section: Geometry and Materials Propertiesmentioning

confidence: 99%

New Insights from Multibody Dynamic Analyses of a Turnout System under Impact Loads

et al. 2019

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A railway turnout is an essential infrastructure for managing railway traffic flexibility. In contrast, it imposes restrictions on train operations such as lower operational speeds through the turnout due to the complex movements of trains over the turnout. This results in the large-amplitude dynamic responses of the train-turnout interaction. Previous studies have focused on the train-turnout interactions entailing the wheel-rail contact forces and stresses. Very few of the studies considered the effects of the contact forces on the turnout structure and its components such as sleepers and bearers. Those previous studies neglected the dynamic forces and estimated the behavior of train-turnout interactions based on quasi-static calculations. In reality, turnouts are subjected to high impact forces, which can be higher than the permissible track forces. Consequently, a numerical model capable of determining impact forces was developed here, to evaluate the dynamic behaviors of a railway turnout and their effects on such turnout components as bearers, ballast, and so on. The model consists of a structured beam grillage laying on an elastic foundation with rigid wheelsets and a bogie. The model was verified by field measurements. The new insight stemmed from this study shows that neglecting the contribution of dynamic forces can result in the unsafe underestimation of train turnout behaviors.

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Metamodelling of wheel–rail normal contact in railway crossings with elasto-plastic material behaviour

Cited by 21 publications

References 22 publications

On the influence of crossing angle on long-term rail damage evolution in railway crossings

On the influence of crossing angle on long-term rail damage evolution in railway crossings

Train Hunting Related Fast Degradation of a Railway Crossing—Condition Monitoring and Numerical Verification

New Insights from Multibody Dynamic Analyses of a Turnout System under Impact Loads

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