论文信息 - Analytical Method to Estimate Railroad Spike Fastener Stress

Analytical Method to Estimate Railroad Spike Fastener Stress

Previous research indicates that spike fastener fatigue failures have led to at least ten derailments since 2000. Given that railroads continue to install fastening systems that have experienced spike failures, methods to quantify the stress state of the spike must be developed. Common approaches to quantify the effect of key variables include laboratory experimentation, field instrumentation, or finite element model development. However, these approaches may be both time and cost prohibitive. An analytical method based on beam on elastic foundation mechanics, similar to the analysis of laterally loaded piles in deep foundation design, was developed to estimate the spike stresses. The outcome is a laboratory-validated analytical approach that generates estimates of spike stress. This analytical model was used to investigate key design criteria (timber modulus, spike cross-sectional area, and load applied) that could be changed to improve the resiliency of the fastening system to increase railroad safety. Another outcome of this study is the development of an instrumented spike that quantifies the spike demands when installed and loaded within a crosstie.

J. Riley Edwards | Marcus S. Dersch | Arthur de Oliveira Lima | Matheus Trizotto Silva | Tom Roadcap

[1] Miklós Hetényi,et al. Beams on Elastic Foundation: Theory with Applications in the Fields of Civil and Mechanical Engineering , 1946 .

[2] Tecnica. American Railway Engineering and Maintenance-of-Way Association , 2012 .

[3] Matthew G. Dick,et al. Experimental Measurement and Finite Element Analysis of Screw Spike Fatigue Loads , 2007 .

[4] Bassem O Andrawes,et al. Finite element modelling and field validation of prestressed concrete sleepers and fastening systems , 2016 .

[5] Joseph LoPresti,et al. Improving Performance of Crossties and Fasteners , 2013 .

[6] Sakdirat Kaewunruen,et al. Modelling Railway Prestressed Concrete Sleepers (Crossties) With Holes and Web Openings , 2016 .

[7] Ryan G. Kernes,et al. Improved Concrete Crosstie and Fastening Systems for US High Speed Passenger Rail and Joint Corridors : Volume 1, Project Summary Report , 2017 .

[8] P. G.. The Mechanical Properties of Wood , 1915, Nature.

[9] H. Matlock. Correlation for Design of Laterally Loaded Piles in Soft Clay , 1970 .

[10] Zhe Chen,et al. A mechanistic model of lateral rail head deflection based on fastening system parameters , 2017 .

[12] Bassem O Andrawes,et al. Finite element modeling and validation of the fastening systems and concrete sleepers used in North America , 2014 .