Numerical study on groove formation of rails for various materials

Author

Hsieh, Kuo-Ta

Author_Institution

Inst. for Adv. Technol., Univ. of Texas, Austin, TX, USA

Volume

41

Issue

1

fYear

2005

Firstpage

380

Lastpage

382

Abstract

Recovered rails exhibit groove formation along the outer edge of the armature/rail contact surface in many experiments. Different causes are hypothesized, such as local melting resulting from the concentration of current density, material yielding due to high contact pressure, and material softening at elevated temperatures. Numerical simulations using the hybrid finite-element/boundary-element code EMAP3D were conducted to identify the cause of this damage. Various rail materials such as chrome copper, 7055 aluminum alloy, beryllium copper, and dispersion-strengthened copper are investigated. The results are presented And they show that groove formation is due to the effect of both material softening at high local temperature and material yielding.

Keywords

aluminium alloys; beryllium alloys; boundary-elements methods; copper alloys; electromagnetic launchers; finite element analysis; materials testing; rails; 7055 aluminum alloy; armature surface; beryllium copper; chrome copper; current density; dispersion-strengthened copper; groove formation; high contact pressure; hybrid finite-element-boundary-element code EMAP3D; local melting; magnetic sawing; material softening; material yielding; numerical study; rail contact surface; recovered rails; Aluminum alloys; Conducting materials; Copper; History; Material properties; Numerical simulation; Rails; Softening; Temperature; Thermal stresses;

fLanguage

English

Journal_Title

Magnetics, IEEE Transactions on

Publisher

ieee

ISSN

0018-9464

Type

jour

DOI

10.1109/TMAG.2004.839287

Filename

1381574