Analysis of fretting fatigue

• Autorzy: Upul F.
• Konferencja: The First European Summer School of Fatique and Fracture (ESSFF1) and The Ninth Polish-Ukrainian-German Summer of Fracture Mechanics (SSFM9) on NEW RESULTS IN FATIGUE AND FRACTURE. Vol.2 (1,9;19-26.06.2005;Zakopane;Polska)
• Języki publikacji: EN

Abstrakty

EN

Fretting induced failure is commonly observed in industrial components that are in contact and are subjected to small oscillatory movements. Microcracks nucleated by fretting may grow rapidly under dynamic loading to catastrophic failure and fretting fatigue is a classic case of multiaxial fatigue which results in a considerable reduction in fatigue strength. This lecture outlines; basic introduction, influencing factors and a fracture mechanics concept that have been developed for the analysis of fretting crack growth and fatigue life prediction.

Słowa kluczowe

EN

fretting induced failure; industrial components; basic introduction; influencing factors

• Wydawca: Oficyna Wydawnicza Politechniki Opolskiej
• Czasopismo: Zeszyty Naukowe. Mechanika / Politechnika Opolska
• Rocznik: 2005
• Tom: z. 84
• Strony: 93--109
• Opis fizyczny: Bibliogr. 15 poz., wykr.

Twórcy

autor

Upul F.

• Materials and Engineering Research Institute Sgeffield Hallam University

Bibliografia

• [1] WATERHOUSE R. B., (1993), Fretting Fatigue, International Materials Reviews, The Inst. of Materials, vol. 37, No. 2.
• [2] HOEPPNER D. W., (1994), Mechanisms of Fretting Fatigue, ESIS Publication No. 18, MEP, London, pp3-20.
• [3] MILLER K. J., (2004), Fretting Fatigue: A review and Futurę PerspectWes, Proc. Inst. Of Marinę Eng. Sci & Tech., Part B, No. B7, ppll-30
• [4] WATERHOUSE R. B., (1972), Fretting Corrosion, Pergamon Press, USA
• [5] WATERHOUSE R. B., LINDLEY T. C, (1994), Fretting Fatigue, ESIS No. 18, MEP, London
• [6] BROWN M. W., MILLER K. J., (1973), A New Theoiy for Multiaxial Fatigue, Proc. Instn. Mech. Eng., 187, pp745-755
• [7] EDWARDS P. R., RYMAŃ R. J., (1975), Studies in Fretting fatigue, RAE Technical Report No. 75132.
• [8] VINGSBOW O., SODERBERG D., (1988), On Fretting Maps, Wear, 126, pp 131-147
• [9] ENDO K., GOTO H., (1976), Initiation and propagation of Fretting Fatigue Cracks, Wear, 38, pp 311-324
• [10] FERNANDO U. S., FARRAHI G. H., BROWN M. W., (1993), Fretting fatigue crack growth behaviour of BS L65 4% copper aluminium alloy under constant normal load, ESIS Publication No. 18, MEP, London, ppl83-197
• [11] GREEN R. G„ (2001), An analysis of fretting fatigue of sharp corner contacts, PhD Thesis, Sheffield Hallam University, UK
• [12] SHEIKH M. A., FERNANDO U. S., BROWN M. W., MILLER K. J., (1993), Elastic stress intensity factors for fretting cracks using the Finite Element method, ESIS Publication No. 18, MEP, London, pp83-102
• [13] FAANES S„ FERNANDO U. S., (1993) Life prediction in fretting fatigue using fracture mechanics, ESIS Publication No. 18, MEP, London, ppl49- 160
• [14] EL HADDAD M. H., SMITH K. N., TOPPER T. H., (1979) Fatigue Crack Propagation of Short Cracks, J. of Eng. Mater. Tech., Trans. ASME, 101, pp42-46
• [15] FAANES S., HAERKEGAARD G., (1993) Simplified Stress Intensity Factors in Fretting Fatigue, ESIS Publication No. 18, MEP, London, pp73-82