2D and 3D characterization of rolling contact fatigue cracks in manganese steel wing rails from a crossing

Rail wheel contact at switches and crossings (S&Cs) induces impact stresses along with rolling contact stresses, resulting in plastic deformation and eventually crack formation. Damaged and deformed wing rails of a manganese steel crossing are studied and the microstructure, hardness and 3D crac...

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Bibliographic Details
Published in:Wear 2019-10, Vol.436-437, p.202959, Article 202959
Main Authors: Dhar, S., Danielsen, H.K., Fæster, S., Rasmussen, C.J., Juul Jensen, D.
Format: Article
Language:English
Subjects:
2D & 3D crack network
3D X-Ray tomography
Contact stresses
Crack propagation
Deformation
Dislocation density
Fatigue cracks
Fatigue failure
Fracture mechanics
Manganese steel
Manganese steels
Metal fatigue
Microstructure
Plastic deformation
Rails
Rolling contact
Rolling contact fatigue (RCF)
Structural steels
Switches
Switches and crossings (S&Cs)
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Summary:Rail wheel contact at switches and crossings (S&Cs) induces impact stresses along with rolling contact stresses, resulting in plastic deformation and eventually crack formation. Damaged and deformed wing rails of a manganese steel crossing are studied and the microstructure, hardness and 3D crack network within the steel are characterized. It is found that the surface of the rail receives the maximum deformation resulting in a hardened top layer. The deformation is manifested by a high density of twins and dislocation boundaries in the microstructure. A complex crack network is revealed in high resolution by X-ray tomography. •For Manganese steel, damage in the wing rail is similar to that in the nose rail.•The depth of work hardening reaches a depth of 10 mm and 600Hv at the surface.•It can be assumed the impact from the wheel causes the crack formation.•3D mapping of the crack network reveal presence of surface and sub-surface cracks.•The crack network appears similar to that of normal straight track pearlitic steel.
ISSN:0043-1648
1873-2577
DOI:10.1016/j.wear.2019.202959