Abstract
Reciprocating sliding is often present in mechanical systems. This particular sliding condition is called fretting when sliding amplitude is small compared to the contact area. Fretting also commonly refers to the degradation of the fatigue properties of a material due to repeated sliding of two contacting surfaces. The small relative displacement amplitudes range typically between 10-100 μm. Examples of practical situations where cracking or wear induced by fretting influence mechanical integrity include such various applications as bolted and riveted joints, key-way-shaft coupling and shrink-fitted couplings. To prevent fretting damage, fretting wear and fretting fatigue have been widely studied for more than thirty years considering macroscopic and microscopic phenomena.
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Benjamin, J.S. and Volin, T.E. (1974) “The Mechanism of Mechanical Alloying”, Metal Trans. 5, 1929–1934.
Berthier, Y., Vincent, L. and Godet, M. (1988) “Velocity accommodation in fretting”, Wear 125, 25–38.
Blanchard, P. (1991) “Usure induite en petits débattements: Transformation Tribologique Superficielle d’alliages de titane”, PhD Thesis 91–32, Ecole Centrale de Lyon, Ecully, France.
Colombié, C, Berthier, Y., Floquet, A., Vincent, L. and Godet M. (1984), “Fretting: Load-Carrying Capacity of Wear Debris”, J. of Tribology ASME 106, 194–201.
Fouvry, S., Kapsa, Ph. and Vincent, L. (1995) “Wear phenomena quantification of Hard coating under Fretting situation”, International Tribology Conference ITC — Yokohama, Oct. 29-Nov. 2 1995, 277–282.
Fouvry, S., Kapsa, Ph. and Vincent L. (1996) “Quantification of fretting damage”, Wear 200, 186–205.
Fouvry, S., Kapsa, Ph. and Vincent L. (1997) “Tenue et performances d’un dépôt TiN sollicité en Fretting: Quantification de la fissuration et des volumes usés”, Tenue et performances mécaniques des dépôts durs, Rapport CETIM Tome 2.
Fouvry, S., Kapsa, Ph. and Vincent, L. (1999), “A multiaxial fatigue analysis of fretting contact taking into account the size effect”, ASTM STP 1367, 167–182.
Heilmann, P., Don, J., Sun, T.C., Rigney, D.A. and Glaeser, W.A. (1983) “Sliding Wear and Transfer”, Wear.
Johnson, K.L., (1985) Contact Mechanics, Cambridge University Press, Cambridge, UK.
Kalker, J.J. (1990) “Three-dimensional elastic bodies in rolling contact” Kluwer Academic Publishers, Dordrecht, The Netherlands.
Martin, B., Vincent, L., Wright, CS., Eagles, A.E. and Wronski, A.S. (1996) “Wear and cracking of sintered high speed steel matrix composites under fretting conditions”, Powder Metallurgy and Paniculate Materials, Ed. MPIF.
Mindlin, R.D. (1949) Trans. ASME, Series E, Journal of Applied Mechanics 16, 259–268
Mohrbacher, H., Blanpain, B., Celis, J.P., Roos, J.R., Stals, L. and Van Stappen, M. (1995) “Oxidational wear of TiN coating on tool steel and nitrided tool steel in unlubricated fretting”, Wear 188, 130–137.
Nowell, D. and Hills, D.A. (1990), “Crack Initiation criteria in fretting fatigue” Wear 136, 329–343.
Rigney, D.A. (1984), “Wear Processes in Sliding Systems”, Wear 100, 195–219.
Sawa, M. and Rigney, D.A. (1987), “Sliding Behaviour of Dual-Phase Steels in Vacuum and in Air”, Wear 119, 369–391.
Sproles, E.S. and Duquette, D J. (1978), “Interface Temperature Measurements in the Fretting of a Medium Carbon Steel”, Wear 47, 387–396.
Szolwinski, M.P. and Farris, T.N. (1996), “Mechanics of fretting fatigue crack formation”, Wear 198, 93–107.
Vingsbo, O. and Soderberg S. (1988), “On fretting maps”, Wear 126, 131–147.
Vincent, L., Berthier, Y. and Godet M. (1992), “Testing methods in fretting fatigue: a critical appraisal”, ASTM STP 1159, 33–48
Vizintin, J., Podgornik, B., Kalin, M., Pezdirnik, J., and Vodopivec J. (1995), “Three-Body Contact Temperature in Fretting Conditions”, Proc. of the 22th Leeds-Lyon Symposium on Tribology, Lyon.
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Fouvry, S., Kapsa, P. (2001). Surface Damage Under Reciprocating Sliding. In: Bhushan, B. (eds) Fundamentals of Tribology and Bridging the Gap Between the Macro- and Micro/Nanoscales. NATO Science Series, vol 10. Springer, Dordrecht. https://doi.org/10.1007/978-94-010-0736-8_27
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DOI: https://doi.org/10.1007/978-94-010-0736-8_27
Publisher Name: Springer, Dordrecht
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