Characterization and mapping of rolling contact fatigue in rail-axle bearings
Characterization and mapping of rolling contact fatigue in rail-axle bearings
This paper presents a new stage of on-going research to fully characterize the rolling contact fatigue (RCF) damage observed in rail axle Compact Tapered roller Bearing Units (CTBUs). The bearings examined in this work have been removed from service, following the identification of degradation using on-board condition monitoring techniques.
The running surfaces of the bearings were examined and the damage fully characterized using a mixture of metallographic, surface profilometry and high-resolution micro-Computed Tomography (μ-CT) techniques. In this manner the RCF was categorised by initiation mechanism: sub-surface or surface. This work has led to an increased understanding of the propagation of sub-surface and surface initiated RCF and its implications for life and condition of the bearing once failure has initiated. It was determined that the sub-surface initiated RCF damage was the first to occur in service and produced large craters on the bearing running surface. Once material had been lost in this primary manner, further secondary surface-initiating RCF grew from the edges of the large craters. It was deemed that the deep primary sub-surface RCF craters were more life limiting than the secondary surface damage. Therefore maps of the damage were created allowing the two mechanisms to be examined separately, both visually and by quantitative parameters such as volume loss, area, depth, roughness etc.
Bearing failure, cracks, vibrations, non-destructive testing, metallography
617-630
Corni, Ilaria
f3279082-7093-4a67-b1d7-9ab8bac75b8b
Symonds, Nicola
cc8585b0-89f5-471c-84fd-969176516829
Birrell, Christopher
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Katsamenis, Orestis L.
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Wasenczuk, Adam
c37fe0d5-546e-4cea-b539-adcd3e21b89e
Vincent, David
946a309d-fe3b-4250-9282-c9a7a7846611
December 2017
Corni, Ilaria
f3279082-7093-4a67-b1d7-9ab8bac75b8b
Symonds, Nicola
cc8585b0-89f5-471c-84fd-969176516829
Birrell, Christopher
d939d395-3c39-4c5d-adf2-ec7ebebf8c96
Katsamenis, Orestis L.
8553e7c3-d860-4b7a-a883-abf6c0c4b438
Wasenczuk, Adam
c37fe0d5-546e-4cea-b539-adcd3e21b89e
Vincent, David
946a309d-fe3b-4250-9282-c9a7a7846611
Corni, Ilaria, Symonds, Nicola, Birrell, Christopher, Katsamenis, Orestis L., Wasenczuk, Adam and Vincent, David
(2017)
Characterization and mapping of rolling contact fatigue in rail-axle bearings.
Engineering Failure Analysis, 82, .
(doi:10.1016/j.engfailanal.2017.04.012).
Abstract
This paper presents a new stage of on-going research to fully characterize the rolling contact fatigue (RCF) damage observed in rail axle Compact Tapered roller Bearing Units (CTBUs). The bearings examined in this work have been removed from service, following the identification of degradation using on-board condition monitoring techniques.
The running surfaces of the bearings were examined and the damage fully characterized using a mixture of metallographic, surface profilometry and high-resolution micro-Computed Tomography (μ-CT) techniques. In this manner the RCF was categorised by initiation mechanism: sub-surface or surface. This work has led to an increased understanding of the propagation of sub-surface and surface initiated RCF and its implications for life and condition of the bearing once failure has initiated. It was determined that the sub-surface initiated RCF damage was the first to occur in service and produced large craters on the bearing running surface. Once material had been lost in this primary manner, further secondary surface-initiating RCF grew from the edges of the large craters. It was deemed that the deep primary sub-surface RCF craters were more life limiting than the secondary surface damage. Therefore maps of the damage were created allowing the two mechanisms to be examined separately, both visually and by quantitative parameters such as volume loss, area, depth, roughness etc.
Text
Mapping of RCF v27 revised_NSAW_IC_final_acknoledgement
- Accepted Manuscript
More information
Accepted/In Press date: 19 April 2017
e-pub ahead of print date: 28 April 2017
Published date: December 2017
Additional Information:
further grants / projects associated with this output: WARNTRAK 672265, and Horizon 2020-SMEINST-2-2014 - won by industrial partner company Perpetuum
Keywords:
Bearing failure, cracks, vibrations, non-destructive testing, metallography
Organisations:
Engineering Mats & Surface Engineerg Gp, Enterprise
Identifiers
Local EPrints ID: 408424
URI: http://eprints.soton.ac.uk/id/eprint/408424
ISSN: 1350-6307
PURE UUID: da83a450-21ad-4c8d-b5ac-940274409276
Catalogue record
Date deposited: 20 May 2017 04:03
Last modified: 16 Mar 2024 05:18
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Contributors
Author:
Christopher Birrell
Author:
Adam Wasenczuk
Author:
David Vincent
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