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Tribology Transactions Volume 60, 2017 - Issue 4
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Articles

Experimental Depiction of the Hypothesis of Flake-Like Wear Debris Generation in Rolling Contact Fatigue of the Rail–Wheel Contact Interface

Asitha AthukoralaQueensland University of Technology, School of Chemistry, Physics and Mechanical Engineering, Brisbane, AustraliaCorrespondence[email protected]
&
Dennis V. De PellegrinQueensland University of Technology, School of Chemistry, Physics and Mechanical Engineering, Brisbane, Australia
Pages 581-591 | Received 16 Dec 2015, Accepted 05 May 2016, Published online: 07 Oct 2016

References

  • Athukorala, A., De Pellegrin, D., and Wickramasinghe, I. U. (2015), “Effect of Different Surface Profile on Wear of Rail Steel (AS1085. 1) Used in Australian Heavy-Haul Railways,” International Journal of Materials Engineering Innovation, 6(4), pp 225–242.
  • Pombo, J., Ambrosio, J., Pereira, M., Lewis, R., Dwyer-Joyce, R., Ariaudo, C., and Kuka, N. (2011), “Development of a Wear Prediction Tool for Steel Railway Wheels Using Three Alternative Wear Functions,” Wear, 271(1–2), pp 238–245.
  • Stock, R., Eadie, D. T., Elvidge, D., and Oldknow, K. (2011), “Influencing Rolling Contact Fatigue through Top of Rail Friction Modifier Application—A Full Scale Wheel–Rail Test Rig Study,” Wear, 271(1–2), pp 134–142.
  • Cocks, M. (1962), “Interaction of Sliding Metal Surfaces,” Journal of Applied Physics, 33(7), pp 2152–2161.
  • Nathan, G. and Jones, W. (1966), “The Empirical Relationship between Abrasive Wear and the Applied Conditions,” Wear, 9(4), pp 300–309.
  • Rabinowicz, E. and Mutis, A. (1965), “Effect of Abrasive Particle Size on Wear,” Wear, 8(5), pp 381–390.
  • Wang, J. and Wang, X. (2013), “A Wear Particle Identification Method by Combining Principal Component Analysis and Grey Relational Analysis,” Wear, 304(1), pp 96–102.
  • Raadnui, S. (2005), “Wear Particle Analysis—Utilization of Quantitative Computer Image Analysis: A Review,” Tribology International, 38(10), pp 871–878.
  • Lim, S. and Ashby, M. (1987), “Overview No. 55 Wear-Mechanism Maps,” Acta Metallurgica, 35(1), pp 1–24.
  • Lim, S., Ashby, M., and Brunton, J. (1987), “Wear-Rate Transitions and Their Relationship to Wear Mechanisms,” Acta Metallurgica, 35(6), pp 1343–1348.
  • Hutchings, I. M. (1992), Tribology: Friction and Wear of Engineering Materials, Amsterdam, The Netherlands: Elsevier Science & Technology.
  • Sasada, T. (1984), “Future Direction of Research in Wear and Wear Resistant Materials. Status of Understanding,” Tribology in the 80's, NASA Lewis Research Center, 1, pp 197–218.
  • Suh, N. P. (1973), “The Delamination Theory of Wear,” Wear, 25(1), pp 111–124.
  • Ayasse, J. and Chollet, H. (2006), “Wheel–Rail Contact,” Handbook of Railway Vehicle Dynamics, Iwnicki, S. (Ed.), pp 85–120, Boca Raton, FL: CRC Press.
  • Barbinta, C.-I., Ulianov, C., Franklin, F., and Cretu, S. (2014), “Wheel–Rail Contact Modelling and Analysis, Considering Profiles Types and Lateral Displacement,” Transport Research Arena (TRA) 5th Conference: Transport Solutions from Research to Deployment; 14–17 April, Paris, France.
  • Enblom, R. and Berg, M. (2008), “Impact of Non-Elliptic Contact Modelling in Wheel Wear Simulation,” Wear, 265(9), pp 1532–1541.
  • Australian Standard. (2002), “Railway Track Materials. Part 1: Steel Rails,” AS1085.1-2002.
  • Kayaba, T. and Kato, K. (1979), “Theoretical Representation of the Coefficient of Friction for Multiple Contact Points,” Wear, 52(1), pp 117–132.
  • Nélias, D., Champiot, F., Girodin, D., Fougéres, R., Flamand, L., Vincent, A., and Dumont, M. (1999), “Role of Inclusions, Surface Roughness and Operating Conditions on Rolling Contact Fatigue,” Journal of Tribology, 121(2), pp 240–251.
  • Nélias, D., Antaluca, E., Boucly, V., and Cretu, S. (2007), “A Three-Dimensional Semianalytical Model for Elastic–Plastic Sliding Contacts,” Journal of Tribology, 129(4), pp 761–771.
  • Fleming, J. and Suh, N. (1977), “Mechanics of Crack Propagation in Delamination Wear,” Wear, 44(1), pp 39–56.
  • Suh, N. P. (1977), “An Overview of the Delamination Theory of Wear,” Wear, 44(1), pp 1–16.
  • Kapoor, A., Beynon, J. H., Fletcher, D. I., and Loo-Morrey, M. (2004), “Computer Simulation of Strain Accumulation and Hardening for Pearlitic Rail Steel Undergoing Repeated Contact,” The Journal of Strain Analysis for Engineering Design, 39(4), pp 383–396.
  • Ringsberg, J. W. (2001), “Life Prediction of Rolling Contact Fatigue Crack Initiation,” International Journal of Fatigue, 23(7), pp 575–586.
  • Bandula-Heva, T., Dhanasekar, M., and Boyd, P. (2013), “Experimental Investigation of Wheel/Rail Rolling Contact at Railhead Edge,” Experimental Mechanics, 53(6), pp 943–957.
  • Sadeghi, F., Jalalahmadi, B., Slack, T. S., Raje, N., and Arakere, N. K. (2009), “A Review of Rolling Contact Fatigue,” Journal of Tribology, 131(4), pp 041403.

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