The effects of laser peening and shot peening on fretting fatigue in Ti-6Al-4V coupons

Tribology International

Volumn 42, Issue 9, 2009, Pages 1250-1262

  Liu, Kevin K ^a   Hill, Michael R ^a  

^a University of California Davis   (United States)

Author keywords

Fretting fatigue; Laser peening; Residual stress; Shot peening; Ti 6Al 4V

Indexed keywords

BRIDGE-TYPE; COMPRESSIVE RESIDUAL STRESS; CRACK GROWTH; CYCLIC FATIGUE; FATIGUE CRACK GROWTH; FATIGUE STRESS; FRACTOGRAPHIC; FRETTING FATIGUE; FRETTING FATIGUES; FRETTING LOADS; INDUCED CRACK; LASER PEENING; LINEAR ELASTIC FRACTURE MECHANICS; LOW STRESS; MEASURED DEPTHS; MECHANICAL SURFACE TREATMENT; NEAR-SURFACE; PROVING RING; ROUGH SURFACES; SURFACE CONDITIONS; TENSILE RESIDUAL STRESS; TENSION-TENSION; TI-6AL-4V; WAVY SURFACE;

ALUMINUM; AMPLITUDE MODULATION; BRITTLE FRACTURE; CRACKING (CHEMICAL); FATIGUE CRACK PROPAGATION; FATIGUE OF MATERIALS; FATIGUE TESTING; FRACTURE MECHANICS; FRETTING CORROSION; LASERS; RESIDUAL STRESSES; SHOT PEENING; STRENGTH OF MATERIALS; SURFACE TESTING; TITANIUM ALLOYS;

CRACKS;

EID: 67649807474     PISSN: 0301679X     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.triboint.2009.04.005     Document Type: Article

References (34)

1. Shaffer SJ, Glaeser WA. Fretting fatigue. ASM handbook, vol. 8; 2000.
2. Waterhouse R.B. Fretting fatigue. Mater Sci Eng 26 (1976) 201-206
3. Namjoshi S.A., Jain V.K., and Mall S. Effects of shot-peening on fretting fatigue behavior of Ti-6Al-4V. J Eng Mater Technol Trans ASME 124 (2002) 222-228
4. Sabelkin V., Martinez S.A., Mall S., Sathish S., and Blodgett M.P. Effects of shot peening intensity on fretting fatigue crack initiation behavior of Ti-6Al-4V. Fatigue Fract Eng Mater Struct 28 (2004) 321-332
5. Lee H., Jin O., and Mall S. Fretting fatigue behavior of shot-peened Ti-6Al-4V at room and elevated temperatures. Fatigue Fract Eng Mater Struct 26 (2003) 767-778
6. Montross C.S., Wei T., Ye L., Clark G., and Mai Y. Laser shock processing and its effects on microstructure and properties of metal alloys: a review. Int J Fatigue 24 (2002) 1021-1036
7. Lee H., and Mall S. Stress relaxation behavior of shot-peened Ti-6Al-4V under fretting fatigue at elevated temperature. Mater Sci Eng A366 (2004) 412-420
8. Lee H., Mall S., and Sathish S. Investigation into effects of re-shot peening on fretting fatigue behavior of Ti-6Al-4V. Mater Sci Eng A390 (2005) 227-232
9. Suresh S. Fatigue of materials. 2nd ed. (1998), Cambridge University Press, Cambridge, UK
10. Waterhouse R.B., and Trowsdale A.J. Residual stress and surface roughness in fretting fatigue. J Phys D Appl Phys 25 (1992) 236-239
11. Waterhouse R.B. Effect of material and surface condition on fretting fatigue. In: Waterhouse R.B., and Lindley T.C. (Eds). Fretting fatigue ESIS 18 (1994), Mechanical Engineering Publication, London 339-349
12. Smith P.R., Shepard M.J., Prevey P.S., and Clauer A.H. Effect of power density and pulse repetition on laser shock peening of Ti-6Al-4V. J Mater Eng Perform 9 1 (2000) 33-37
13. Sokol DW, Clauer AH, Ravindranath R. Applications of laser peening to titanium alloys. In: Proceedings of ASME/JSME conference, pressure vessels and piping division, San Diego, CA, 2004.
14. Shepard MJ, Prevey PS, Jayaraman N. Effects of surface treatment on fretting fatigue performance of Ti-6Al-4V. In: Proceedings of the eighth national turbine engine high cycle fatigue conference, Monterey, CA, 2003.
15. Ruschau J.J., John R., Thompson S.R., and Nicholas T. Fatigue crack nucleation and growth rate behavior of laser shock peened titanium. Int J Fatigue 21 (1999) 199-209
16. Rankin J.E., Hill M.R., and Hackel L.A. The effects of process variations on residual stress in laser peened 7049-T73 aluminum alloy. Mater Sci Eng A349 (2003) 279-291
17. Hammersley G., Hackel L.A., and Harris F. Surface prestressing to improve the strength of components by laser shock peening. Opt Laser Eng 34 (2000) 327-337
18. Yakimets Y., Richards C., Beranger G., and Peyre P. Laser peening processing effect on mechanical and tribological properties of rolling steel 100Cr6. Wear 256 (2004) 311-320
19. Tan Y., Wu G., Yang J.M., and Pan T. Laser shock peening on fatigue crack growth behavior of aluminum alloy. Fatigue Fract Eng Mater Struct 27 (2003) 649-656
20. Prevey PS. The effect of cold work on the thermal stability of residual compression in surface enhanced IN718. In: Proceedings of 20th ASM materials solutions conference and exposition, St. Louis, Missouri, 2000.
21. DeWald A.T., Rankin J.E., Hill M.R., Lee M.J., and Chen H. Assessment of tensile residual stress mitigation in alloy 22 welds due to laser peening. J Eng Mater Technol Trans ASME 126 (2004) 465-473
22. ASTM E466-96. Standard practice for conducting force controlled constant amplitude axial fatigue tests of metallic materials. ASTM Standards. Pennsylvania: ASTM; 1999.
23. Prime M.B. Residual stress measurement by successive extension of a slot: the crack compliance method. Appl Mech Rev 52 (1999) 75-96
24. Prime M.B. Cross-sectional mapping of residual stresses by measuring the surface contour after a cut. J Eng Mater Technol 123 (2001) 162-168
25. Lindley T.C., and Nix K.J. Fretting fatigue in the power generation industry: experiments, analysis, and intergrity assessment. In: Attia M.H., and Waterhouse R.B. (Eds). Standardization of fretting fatigue testing methods and equipment ASTM STP 1159 (1992), American Society for Testing and Materials, West Conshohocken, PA 153-169
26. Pape J.A., and Neu R.W. Influence of contact configuration in fretting fatigue testing. Wear 225-229 (1999) 1205-1214
27. Rayaprolu D.B., and Cook R. A critical review of fretting fatigue investigations at the royal aerospace establishment. In: Attia M.H., and Waterhouse R.B. (Eds). Standardization of fretting fatigue test methods and equipment ASTM STP 1159 (1992), American Society of Testing and Materials, West Conshohocken, PA 129-152
28. Nakazawa K., Sumita M., and Maruyama N. Effect of contact pressure on fretting fatigue of high strength steel and titanium alloy. In: Attia M.H., and Waterhouse R.B. (Eds). Standardization of fretting fatigue test methods and equipment ASTM STP (1992), American Society of Testing and Materials, West Conshohocken, PA 115-125
29. Goss G.L., and Hoeppner D.W. Normal load effects in fretting fatigue of titanium and aluminum alloys. Wear 27 (1974) 153-159
30. Hoeppner D.W., Taylor A.M., and Chandrasekaran V. Fretting fatigue behavior of titanium alloys. In: Mutoh K., Kinyon S.E., and Hoeppner D.W. (Eds). Fretting fatigue: advances of basic understanding and application ASTM STP 1425 (2003), American Society for Testing and Materials, West Conshohocken, PA 353-365
31. Hills DA, Nowell D. A critical analysis of fretting fatigue experiments. Fretting fatigue ESIS 18. In: Waterhouse RB, Lindley TC, editors. Mechanical Engineering Publications. London; 1994. p. 171-81.
32. Giannakopoulos A.E., Lindley T.C., and Suresh S. Aspects of equivalence between contact mechanics and fracture mechanics: theoretical connections and a life-prediction methodology for fretting fatigue. Acta Mater 46 (1998) 2955-2968
33. Shen G., and Glinka G. Weight functions for a surface semi-elliptical crack in a finite thickness plate. Theoret Appl Fract Mech 15 (1991) 247-255
34. Gallagher JP. Improved high-cycle fatigue (HCF) life prediction. Technical Report AFRL-ML-WP-TR-2001-4159, University of Dayton Research Institute, Air Force Research Laboratory, Wright-Patterson Air Force Base, OH; 2001.