Crash Energy Management Crush Zone Designs: Features, Functions, and Forms

Priante, Michelle; Martinez, Eloy

doi:10.1115/jrc/ice2007-40051

Cited by 6 publications

(6 citation statements)

References 4 publications

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“…The SIV measured in the cab of the lead car in the full scale crash energy management train-to-train test is included in the figure. This is a particularly harsh pulse because the crush zone elements were between the cab and the car body [6]. The SIV from a typical automobile crash pulse is also included in the figure.…”

Section: Secondary Impact Velocitymentioning

confidence: 99%

Prototype Design of an Engineer Collision Protection System

Muhlanger

Severson

Perlman

et al. 2012

2012 Joint Rail Conference

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This research program was sponsored by the Federal Railroad Administration (FRA) Office of Research and Development in support of the advancement of improved safety standards for passenger rail vehicles. In a train collision, the cab or locomotive engineer is in a vulnerable position at the leading end of the vehicle. As cars with increased crashworthiness are introduced into service, there is a greater potential to preserve the space occupied by the engineer following an accident. In particular, full-scale impact tests have demonstrated the engineer's space can be preserved at closing speeds up to 30 mph. When sufficient survival space is preserved, the next objective is to protect the engineer from the forces and accelerations associated with secondary impacts between the engineer and the control cab. Given the hard surfaces and protruding knobs in a control cab, even a low speed collision can result in large, concentrated forces acting upon the engineer.Researchers have designed a passive (i.e., requiring no action by the operator) interior protection system for cab car and locomotive engineers. The occupant protection system will protect engineers from the secondary impact that occurs following a frontal train impact, when the engineer impacts the control console. The protection system will result in compartmentalization of a 95th percentile anthropomorphic test device (ATD), and measured injury criteria for the ATD's head, chest, neck, and femur that are below those currently specified in Federal Motor Vehicle Safety Standard (FMVSS) 208 [1].The system that has been developed to protect the engineer includes a specialized airbag and a knee bolster with energy absorbing honeycomb material and deformable brackets. Finite element and lumped mass-spring analyses show the effectiveness of the system in limiting the injury criteria to survivable limits. Component tests have measured the key characteristics of the airbag and the knee brackets and have provided test data necessary to validate the analyses.Two tests were conducted to validate the airbag model. A static deployment test of the airbag measured the inflation progression, the inflated shape and the internal pressure of the airbag. A drop tower test of the airbag measured the force-crush and energy absorbing characteristics of the airbag. The knee bolster assembly consists of two components. Separate quasistatic tests of the aluminum honeycomb and the knee bolster bracket measured the force-crush and energy absorbing characteristics. The component test results were used to improve the computer model and permit analysis of the entire system. This paper discusses the prototype design, including background research, baseline definition and prototype development. The initial prototype design is analyzed using computer models. The components are tested to verify and improve the computer models. The test and analysis results are presented. Future work is planned for fabrication of the cab desk and prototype system to be used in a sled test with a 95 th ...

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Section: Secondary Impact Velocitymentioning

confidence: 99%

Prototype Design of an Engineer Collision Protection System

Muhlanger

Severson

Perlman

et al. 2012

2012 Joint Rail Conference

View full text Add to dashboard Cite

show abstract

“…For a cab car-to-locomotive collision of two passenger trains, equipment with CEM features can protect the passengers and crew for twice the collision speed as conventional equipment [14]. The performance of passenger equipment with CEM features has been measured and analyzed in detail [15,16,17]. This paper includes simplified engineering analysis of CEM features on LNG tenders.…”

Section: Crashworthiness Design Strategymentioning

confidence: 99%

“…Space limitations on the locomotive may inhibit the energy absorption capacity of the pushback coupler when a conventional draft gear is used; other elements, such as the deformable anti-climber and primary energy absorber, may be used to provide the needed energy absorption capacity. Engineering design, analysis, and test efforts, similar to those conducted for passenger equipment [15,16,17], may be necessary to develop prototype and service CEM features for LNG tenders that are service and crashworthiness compatible with existing freight locomotives.…”

Section: Fig 4 Example Pushback Coupler and Deepened Bellmouth [14]mentioning

confidence: 99%

“…FRA also developed a cab car deformable anti-climber design that maintains vertical and lateral load path and also meets traditional strength-based requirements [15,17]. This deformable anti-climber was also tested as part of the CEM trainto-train test.…”

Section: Fig 6 Fra Prototype Deformable Anti-climbermentioning

confidence: 99%

“…The buff stops, which support the draft gear during normal operation, have been modified to fail at a prescribed impact load. These features were tested as part of the CEM trainto-train test [16,17]. In this test, a CEM cab car led passenger train collided with a conventional locomotive-led passenger train at 30 mph.…”

Section: Fig 4 Example Pushback Coupler and Deepened Bellmouth [14]mentioning

confidence: 99%

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Liquefied Natural Gas Tender Crashworthiness in Train-to-Train Collisions

Tyrell

2016

2016 Joint Rail Conference

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Research to facilitate industry efforts to safely use natural gas as a locomotive fuel is being directed by the Federal Railroad Administration’s (FRA’s) Office of Research, Development, and Technology. This research is being conducted cooperatively with the Association of American Railroads (AAR). The research results are being shared with the AAR’s Natural Gas Fuel Tender Technical Advisory Group (NGFT TAG), which includes AAR, Member Railroads, and FRA, with support from ARA and Volpe Center. The NGFT TAG is developing industry requirements, including crashworthiness requirements, for revenue-service natural gas fuel tenders. Five accident scenarios have been drafted by the NGFT TAG: a train-to-train collision, a grade-crossing collision, rollover, shell impact, and head impact. Each scenario includes a description of the equipment, the impact conditions, and the prescribed outcome. Conceptually, these tender scenarios parallel the scenarios described in 49 CFR Part 229 Appendix E for locomotive crashworthiness. The focus of the NGFT TAG discussions has expanded to include alternative static requirements. Conceptually, the tender static requirements parallel the requirements for locomotive crashworthiness in AAR S-580. Requirements in S-580 for locomotive structure include static load capacities, material properties, and material thicknesses. For conventionally-designed locomotives, meeting the static requirements of S-580 is accepted as meeting the dynamic requirements of Appendix E. The tender static requirements under development are intended to provide the same level of crashworthiness as the previously proposed dynamic requirements. The primary advantage of static crashworthiness requirements is that compliance can be shown with classical closed-form engineering analyses. A disadvantage is that design features are presumed, such as the inclusion and location of collision posts in a conventional locomotive design. Design features are not presumed in dynamic crashworthiness requirements; however, compliance must be shown with a design-specific validated computer simulation model. So while dynamic requirements allow for a wide range of design approaches, showing compliance often requires extensive effort. This paper focuses on technical information to help support development of alternative static requirements for the train-to-train collision scenario. The goal of the static requirements is to provide the same level of crashworthiness as the dynamic requirements under discussion by the NGFT TAG. Tender features capable of providing the desired level of performance are proposed. These features have been selected such that a tender with these features would be crashworthy-compatible with a wide range of new and existing locomotive structural designs.

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Energy absorption design for crash energy management passenger trains based on scaled model

Wang

et al. 2021

Struct Multidisc Optim

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Crash Energy Management Crush Zone Designs: Features, Functions, and Forms

Cited by 6 publications

References 4 publications

Prototype Design of an Engineer Collision Protection System

Prototype Design of an Engineer Collision Protection System

Liquefied Natural Gas Tender Crashworthiness in Train-to-Train Collisions

Energy absorption design for crash energy management passenger trains based on scaled model

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