Train-to-Train Impact Test: Analysis of Structural Measurements

Tyrell, David; Severson, Kristine; Perlman, Amotz; Rancatore, Robert J.

doi:10.1115/imece2002-33247

Cited by 21 publications

(16 citation statements)

References 10 publications

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Section: Introductionmentioning

confidence: 94%

“…Examples of the models developed include: detailed three dimensional non-linear large deformation finite element crush models used to investigate the crush behavior of equipment and lumped parameter models to study the collision dynamic behavior of single cars, connected cars, and complete consists. The fidelity of the modeling approaches has been demonstrated by the close agreement of predicted responses with measurements taken from full-scale testing [1,2,3] for key test parameters.As part of this research, a series of tests are being carried out to compare the crashworthiness performance of conventional equipment and the performance of improved crashworthiness equipment [4]. The measurements made during these tests also allow the refinement of analytical models.…”

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confidence: 94%

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Fullscale Two-Car Impact Test: A Comparison of Measured and Model Results

Rancatore¹,

Mayville²,

Baldwin³

2004

Joint Rail

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The Volpe National Transportation Systems Center is conducting research into the crashworthiness of rail vehicles in support of the Federal Railroad Administration's Office of Research and Development. The approach taken has focused on the review of accidents, development of analytical tools and performing full-scale testing. A series of inline full-scale impact tests have been performed using conventional passenger cars. Recent full-scale testing included two instrumented coupled conventional passenger cars impacting a fixed barrier at 26 mph. The cars were instrumented with accelerometers, strain gages and string potentiometers. From these measurements, car translations, rotations, relative displacements and coupler forces were calculated. A rigid body dynamics model of the two-car configuration was developed and used to design the test. In order to improve the collision dynamics models of passenger cars, the results from this test are being used to refine that model. This paper describes the two-car impact test, the reduction of data collected during the test and the refined collision dynamics model. Post-test refinements allow the model to more accurately simulate the vertical and lateral motions of the cars, including the timing of the lateral buckling of the cars. The post-test model also more accurately simulates the climbing of the impact car as it crushes. Comparisons between the refined model results with the measured data are presented for the motion of the center of gravity of the cars, coupled car interactions and forces, and lateral buckling. INTRODUCTIONThe Federal Railroad Administration's Office of Research and Development, with the assistance of the Volpe Center, has been conducting research studies on the crashworthiness behavior of conventional and modified passenger rail equipment. The goal of these studies is to enhance the safety of both passengers and crewmembers in the event of a derailment or collision. Work conducted for these studies includes the development of analytical models as well as scaled and fullscale testing. Examples of the models developed include: detailed three dimensional non-linear large deformation finite element crush models used to investigate the crush behavior of equipment and lumped parameter models to study the collision dynamic behavior of single cars, connected cars, and complete consists. The fidelity of the modeling approaches has been demonstrated by the close agreement of predicted responses with measurements taken from full-scale testing [1,2,3] for key test parameters.As part of this research, a series of tests are being carried out to compare the crashworthiness performance of conventional equipment and the performance of improved crashworthiness equipment [4]. The measurements made during these tests also allow the refinement of analytical models. As a result these refined models can predict the crashworthiness of trains with increased fidelity [5,6].A rigid barrier impact test was conducted on two coupled conventional Budd Company Pioneer rail...

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Section: Introductionmentioning

confidence: 94%

mentioning

confidence: 94%

Fullscale Two-Car Impact Test: A Comparison of Measured and Model Results

Rancatore¹,

Mayville²,

Baldwin³

2004

Joint Rail

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“…The overall objective of this series of tests is to evaluate incremental improvements in the crashworthiness performance of modern corner post designs when compared against the performance of older designs [10,11,12]. The grade crossing tests were designed to address the concern of operator vulnerability to bulk crushing resulting from offset/oblique collisions where the primary load resisting structure is the end frame design.…”

Section: Soa Cab Car Dynamic Full-scale Testingmentioning

confidence: 99%

Review of Severe Deformation Recommended Practice Through Analyses: Comparison of Two Cab Car End Frame Designs

2005

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Non-linear large deformation analyses have been conducted to evaluate the performance of the cab car corner and collision posts of the Federal Railroad Administration's ( FRA) sponsored state-of-the-art (SOA) end frame design and the Bombardier M7 design under quasi-static and dynamic test conditions. Pre-test analysis predictions of the dynamic performance of the SOA corner post closely match test measurements. A similar analysis of the corner post was performed on the M7 design, and the results compared with the SOA test and analysis results. Using this M7 model, analysis results for the quasi-static test of the collision post were developed, and compared with the test measurements. Up to the onset of material failure, the analysis results and test measurements closely agree. After the onset of material failure, the results progressively diverge. Overall, the crashworthiness performance of the collision posts of the SOA and M7 designs were found to be essentially the same, and the performance of the M7 corner post design was found to perform better than the SOA corner post design. This difference in performance comes from the sidewall support in the M7 design, which is not present in the SOA design.

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“…These elements were constrained to move only in the longitudinal direction. Specific values used in the model were chosen to be consistent to collision dynamics models that were developed by the Volpe Center [1,8].…”

Section: Trailing Vehicles and Vehicle Connectionsmentioning

confidence: 99%

Analysis of Colliding Vehicle Interactions for the Passenger Rail Train-to-Train Impact Test

Stringfellow¹,

Rancatore²,

Llana³

et al. 2004

Joint Rail

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A full-scale train-to-train impact test was performed in which a cab car-led passenger train traveling at 30 mph collided with a standing locomotive-led train. During the test, the lead cab car overrode the cab of the standing locomotive, sustaining approximately 20 feet of crush, while the cab of the locomotive remained essentially intact.In this study, a finite element-based analysis of the collision was performed. The first 0.5 seconds of the collision was simulated. Results of the analysis were compared with accelerometer and video test data. Specific comparisons are made between test data and model predictions for: motions of the cab car and the standing locomotive; longitudinal forces arising between the cab car and the standing locomotive and between the respective lead and trailing vehicles; and the mode of deformation of the cab car and the locomotive.The results of the study indicate that the model captures pertinent features of the first 0.3 seconds of the collision, particularly with respect to longitudinal vehicle motions and collision forces. After 0.3 seconds, agreement between model predictions and test data becomes progressively worse. This is attributable to the model's inability to capture the massive fracture that occurs at the front of the cab car.

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Train-to-Train Impact Test: Analysis of Structural Measurements

Cited by 21 publications

References 10 publications

Fullscale Two-Car Impact Test: A Comparison of Measured and Model Results

Fullscale Two-Car Impact Test: A Comparison of Measured and Model Results

Review of Severe Deformation Recommended Practice Through Analyses: Comparison of Two Cab Car End Frame Designs

Analysis of Colliding Vehicle Interactions for the Passenger Rail Train-to-Train Impact Test

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