Issues concerned with self-arrest of fretting fatigue cracks at small initial lengths are discussed for a range of well-defined contact geometries. The conditions under which self-arrest will occur are given, together with the maximum tolerable initial flaw size, beyond which self-arrest may not be anticipated.
NowellD.HillsD.A.DaiD. N.Energy dissipation and crack initiation in fretting fatigue. In Proceedings of 20th Leeds-Lyon Symposium onTribology, 1993 (Elsevier, Amsterdam).
2.
NowellD.HillsD. A.Crack initiation criteria in fretting fatigue. Wear, 1990, 136, pp. 329–343.
3.
KingR. N.LindleyT. C.Fretting fatigue in a 3.5NiCr-MoV rotor steel. Report RD/L/N75/80 CERL, Central Electricity Generating Board, 1980.
4.
GrecoE.BessonJ. M.Fretting fatigue: The Eurocopter France industrial approach. In Euromech 346, pp. 20–22 March 1996.
5.
O'ConnorJ. J.HillsD. A.A fracture mechanics correlation of fretting fatigue experiments. InMechanisms and Surface Distress, Proceedings of 12th Leeds-Lyon Symposium on Tribology (Ed. DowsonD.), 1986, pp. 55–63 (Butter-worths, Oxford).
6.
KunoM.WaterhouseR. B.NowellD.HillsD. A.Initiation and growth of fretting fatigue cracks in the partial slip regime. Fatigue and Fracture of Engng Mater. and Structs, 1989, 12 (5), pp. 387–398.
7.
HillsD. A.NowellD.Mechanics of Fretting Fatigue, 1994 (Kluwer Academic Publishers, Dordrecht).
8.
BramhallR.Studies in fretting fatigue. DPhil thesis, University of Oxford, 1973.
9.
EndoK.GotoH.Initiation and propagation of fretting fatigue cracks. Wear, 1976, 38, pp. 311–324.
10.
NowellD.An analysis of fretting fatigue. DPhil thesis, University of Oxford, 1988.
11.
HillsD. A.NowellD.SackfieldA.Mechanics of Elastic Contacts, 1993 (Butterworth-Heinemann, Oxford).
12.
MindlinR. D.Compliance of elastic bodies in contact. J. Appl. Mechanics, 1949, 16, pp. 259–268.
13.
CattaneoC.Sul contatto di due corpi elastici: Distribuzion locale degli sforzi. Rendiconti dell’ Accademia nazionale dei Lincei, 1938, 27, pp. 342–348, pp. 434–436, pp. 474–478.
14.
FaanesS.Distribution of contact stresses along a worn fretting surface. Int. J. Solids Structs, 1996, 23, pp. 3477–3489.
15.
TrumanC. E.SackfieldA.HillsD. A.Contact mechanics of wedge and cone indenters. Int. J. Mech. Sci., 1995, 37 (3), pp. 261–275.
16.
NowellD.HillsD. A.Open cracks at or near free edges. J. Strain Analysis, 1987, 22 (3), pp. 177–185.
17.
BuecknerH. F.The propagation of cracks and the energy of elastic deformation. Trans. ASME, 1958, 80, pp. 1225–1230.
18.
ErdoganF.GuptaG. D.CookT. S.Numerical solutions of singular integral equations. In Methods of Analysis and Solutions of Crack Problems (Ed. SihG. C.), 1973, pp. 368–425 (Noordhoff, Leyden).
19.
FellowsL. J.NowellD.HillsD. A.Fretting fatigue tests carried out on a chromium/molybdenum/vanadium steel (Fe 3Cr IMo 0.2V). Report 65, University of Oxford Technology Centre for Solid Mechanics, 1995.
20.
HillsD. A.NowellD.SackfieldA.Surface fatigue considerations in fretting. InInterface Dynamics, Proceedings of 14th Leeds-Lyon Symposium on Tribology (Eds DowsonD.TaylorC. M.GodetM.BertheD.), 1988 (Elsevier, Amsterdam).
21.
HillsD. A.NowellD.O'ConnorJ. J.On the mechanics of fretting fatigue. Wear, 1988, 125, pp. 129–146.
