Development and Implementation of a Continuous Vertical Track-Support Testing Technique

Li, Dingqing; Thompson, Randy; Marquez, P; Kalay, Semih

doi:10.3141/1863-09

Cited by 14 publications

(11 citation statements)

References 1 publication

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“…Over the past two decades, two deflection/track modulus measurement techniques have been developed and tested in North America: the Track Loading Vehicle (TLV) developed by the Transportation Technology Center, Inc. (TTCI) and the University of Nebraska Real-Time Vertical Track Deflection Measurement System (UNL system, commercially known as MRail) developed under the sponsorship of the Federal Railroad Administration (FRA). 6,13,[17][18][19] The focus of this study is on the UNL system that has shown the potential to measure deflection at relatively higher speeds and at lower equipment costs. 20 The UNL system measures the relative vertical distance (referred to as Y rel ) between the rail surface and the rail/wheel contact plane at a distance of 1.22 m from the nearest wheel to the sensor system.…”

Section: Introductionmentioning

confidence: 99%

“…The application of on-train techniques for measuring the track modulus at revenue speed provides a comprehensive overview of railway line conditions over long distances of track. 12–16 Despite this significant advantage, measuring the vertical rail deflection from a moving car is a challenge due to the difficulty in defining a reference point. Moreover, the interpretation of the on-train deflection measurement data still needs more investigation.…”

Section: Introductionmentioning

confidence: 99%

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Evaluating the potential of a rolling deflection measurement system to estimate track modulus

Nafari

Gül

Roghani

et al. 2016

Proceedings of the Institution of Mechanical Engineers, Part F:

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Over the past two decades, a rolling deflection measurement system aiming to continuously measure the track modulus has been under development at the University of Nebraska-Lincoln under the sponsorship of the Federal Railroad Administration. This system measures the relative vertical distance (referred to as Y rel) between the rail surface and the rail/wheel contact plane at a distance of 1.22 m from the nearest wheel to the sensor system. The aim of this study was to investigate the potential of using the Y rel measurement as an indicator of the track modulus for various rail foundation conditions. To meet this objective, a detailed finite element model capable of simulating moving loads and track modulus variation was developed. One of the unique contributions of this study is that it presents a comprehensive study of the Y rel-track modulus relationship by defining more realistic support conditions using discrete spring supports and by simulating the stochastic nature of the track modulus along a 160-m track length. The numerical model was employed to examine the accuracy of estimating the track modulus using the Y rel measurements when foundation stiffness is variable. Furthermore, the correlation between the statistical properties of the track modulus and Y rel was studied over different track segment lengths.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Evaluating the potential of a rolling deflection measurement system to estimate track modulus

Nafari

Gül

Roghani

et al. 2016

Proceedings of the Institution of Mechanical Engineers, Part F:

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“…A number of train-mounted measurement systems have been developed for the estimation of track stiffness continuously along rails. 16–25 This includes the Track Loading Vehicle (TLV; developed by the Transportation Technology Center, Inc.) and the University of Nebraska Real-Time Vertical Track Deflection Measurement System (commercially known as MRail; developed under the sponsorship of the Federal Railroad Administration) that measure the VTD from moving railcars under axle loads that are representative of fully loaded railcars. 16,17,19,20 These train-mounted VTD measurement systems have potential use for the estimation of maximum bending moments and stresses in the rail by applying the mathematical correlation between rail deflections and bending stresses.…”

Section: Train-mounted Vtd Measurement Systemsmentioning

confidence: 99%

“…Train-mounted instruments that measure the vertical track deflection (VTD) under train loading have become available over the last decade. 16–20 These instruments present an opportunity to estimate rail bending stresses over long distances, and thus characterize the spatial variation of bending stresses. 15,16 However, the effect of track modulus and its variability on the mathematical correlation between rail deflection and bending stresses has not been thoroughly investigated and, as a result, the method used to estimate rail bending stresses from VTD measurements is overly simplistic.…”

Section: Introductionmentioning

confidence: 99%

Estimation of vertical bending stress in rails using train-mounted vertical track deflection measurement systems

Nafari

Gül

Hendry

et al. 2017

Proceedings of the Institution of Mechanical Engineers, Part F:

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This paper presents a new methodology for the estimation of bending stresses over long sections of rails from the vertical track deflections measured using train-mounted instrumentation. The basis of this method is to apply mathematical correlations between the rail deflections and stresses to interpret the deflection measurements. A new finite element modeling method was developed to investigate mathematical correlations between the rail deflections and stresses for different ranges of track modulus. The stochastic nature of the track modulus, as one of the dominant factors influencing rail deflections and stresses, was simulated. The rail responses to applied loads were then calculated and compared for scenarios of constant and variable track modulus values. The study resulted in a detailed framework that can be employed to estimate rail bending stresses from train-mounted vertical track deflection measurements. This framework allows the estimation of the probability distributions of maximum tensile and compressive bending stresses in the rail head and base, which are necessary for calculating the rail reliability under applied loading.

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“…Although these techniques provide accurate estimations of track stiffness, they are laborious and time-consuming, especially when multi-point measurements are required. On the other hand, on-train measurement systems allow the measurement of rail deflections over long distances and thus provide a good overall evaluation of the entire railway network [10][11][12][13][14][15]. Comprehensive analysis is typically needed to investigate the relationship between deflection measurements from on-train systems and track modulus [16,17].…”

Section: Introductionmentioning

confidence: 99%

Continuous Evaluation of Track Modulus from a Moving Railcar Using ANN-Based Techniques

Ngoan¹,

Gül²,

Nafari³

2020

Vibration

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Track foundation stiffness (also referred as the track modulus) is one of the main parameters that affect the track performance, and thus, quantifying its magnitudes and variations along the track is widely accepted as a method for evaluating the track condition. In recent decades, the train-mounted vertical track deflection measurement system developed at the University of Nebraska–Lincoln (known as the MRail system) appears as a promising tool to assess track structures over long distances. Numerical methods with different levels of complexity have been proposed to simulate the MRail deflection measurements. These simulations facilitated the investigation and quantification of the relationship between the vertical deflections and the track modulus. In our previous study, finite element models (FEMs) with a stochastically varying track modulus were used for the simulation of the deflection measurements, and the relationships between the statistical properties of the track modulus and deflections were quantified over different track section lengths using curve-fitting approaches. The shortcoming is that decreasing the track section length resulted in a lower accuracy of estimations. In this study, the datasets from the same FEMs are used for the investigations, and the relationship between the measured deflection and track modulus averages and standard deviations are quantified using artificial neural networks (ANNs). Different approaches available for training the ANNs using FEM datasets are discussed. It is shown that the estimation accuracy can be significantly increased by using ANNs, especially when the estimations of track modulus and its variations are required over short track section lengths, ANNs result in more accurate estimations compared to the use of equations from curve-fitting approaches. Results also show that ANNs are effective for the estimations of track modulus even when the noisy datasets are used for training the ANNs.

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Development and Implementation of a Continuous Vertical Track-Support Testing Technique

Cited by 14 publications

References 1 publication

Evaluating the potential of a rolling deflection measurement system to estimate track modulus

Evaluating the potential of a rolling deflection measurement system to estimate track modulus

Estimation of vertical bending stress in rails using train-mounted vertical track deflection measurement systems

Continuous Evaluation of Track Modulus from a Moving Railcar Using ANN-Based Techniques

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