Compressive residual stresses that improve fatigue strength of material are obtained by peening the surface. Unlike traditional processes, a novel process of oil cavitation jet peening was developed. The process is based on implosion generated by the oil cavitation jet that plastically deforms the surface, imparting compressive residual stresses. The process developed involves injection of a high-speed oil jet through a suitably designed nozzle, into an oil-filled chamber containing the specimen to be peened. The region of cavitation generation, growth, and collapse, at the various cavitation numbers, was recorded using high-speed photography. To optimize the process parameters, a simple erosion test was performed in aluminum alloy, AA 6063-T6, specimens. The impact pressure generated during the implosion of cavitation bubbles causes plastic deformation and erosion of the surface. The surface deformation and cavitation jet erosion in the exposed specimens were characterized using optical and scanning electron microscopies. The standoff distance, which measures jet impact zone of the specimen from nozzle, was optimized at 15 mm in a cavitation number (which is a measure of pressure ratio across the nozzle) of 0.0017. The surface deformation produced by collapse of the oil bubble was similar to impact of oil droplet on the surface. The material removal mechanism during implosion of the bubble is predominately by ductile shear deformation.
Issue Section:
Multiphase Flows
1.
Mutoh
, Y.
, Fair
, G. H.
, Noble
, B.
, and Water House
, R. B.
, 1987, “The Effect of Residual Stresses Induced by Shot Peening on Fatigue Crack Propagation in Two High Strength Aluminum Alloys
,” Fatigue Fract. Eng. Mater. Struct.
8756-758X, 10
, pp. 261
–272
.2.
Benedetti
, M.
, Bortolamedi
, T.
, Fontanari
, V.
, and Frendo
, F.
, 2004, “Bending Fatigue Behavior of Differently Shot Peened Al 6082-T5 Alloy
,” Int. J. Fatigue
0142-1123, 26
, pp. 889
–897
.3.
Tönshoff
, H. K.
, Kroos
, F.
, and Marzenell
, C.
, 1997, “High-Pressure Water Peening—A New Mechanical Surface Strengthening Process
,” CIRP Ann.
0007-8506, 46
(1
), pp. 113
–116
.4.
Daniewicz
, S. R.
, and Cummings
, S. D.
, 1999, “Characterization of a Water Peening Process
,” ASME J. Eng. Mater. Technol.
0094-4289, 121
, pp. 336
–340
.5.
Grinspan
, A. Sahaya
, and Gnanamoorthy
, R.
, 2006, “A Novel Surface Modification Technique for the Introduction Compressive Residual Stress and Preliminary Studies on Aluminum Alloy AA6063
,” Surf. Coat. Technol.
0257-8972, 201
, pp. 1768
–1775
.6.
Grinspan
, A. Sahaya
, and Gnanamoorthy
, R.
, 2006, “Surface Modification by Oil Jet Peening in Aluminum Alloys AA 6063-T6 and AA 6061-T4: Residual Stress and Hardening
,” Appl. Surf. Sci.
0169-4332, 253
, pp. 989
–996
.7.
Grinspan
, A. Sahaya
, and Gnanamoorthy
, R.
, 2006, “Surface Modification by Oil Jet Peening in Aluminum Alloys AA 6063-T6 and AA 6061-T4: Surface Morphology, Erosion and Mass Loss
,” Appl. Surf. Sci.
0169-4332, 253
, pp. 997
–1006
.8.
Grinspan
, A. Sahaya
, and Gnanamoorthy
, R.
, 2007, “Surface Modification and Fatigue Behavior of High-Pressure Oil Jet Peened Medium Carbon Steel, AISI 1040
,” ASME J. Manuf. Sci. Eng.
1087-1357, 129
, pp. 601
–606
.9.
Soyama
, H.
, 2004, “Introduction of Compressive Residual Stress Using a Cavitating Jet in Air
,” ASME J. Eng. Mater. Technol.
0094-4289, 126
, pp. 123
–128
.10.
Soyama
, H.
, and Asahara
, H.
, 1999, “Improvement of Corrosion Resistance of a Carbon Steel Surface by a Cavitation Jet
,” J. Mater. Sci. Lett.
0261-8028, 18
, pp. 1953
–1955
.11.
Soyama
, H.
, 2000, “Improvement in Fatigue Strength of Silicon Manganese Steel SUP7 by Using a Cavitation Jet
,” JSME Int. J., Ser. A
1340-8046, 43
, pp. 173
–178
.12.
Odhiambo
, D.
, and Soyama
, H.
, 2003, “Cavitation Shot Less Peening for Improvement of Fatigue Strength of Carbonized Steel
,” Int. J. Fatigue
0142-1123, 25
, pp. 1217
–1222
.13.
Qin
, M.
, Ju
, D. Y.
, and Oba
, R.
, 2006, “Investigation of Influence of Incident Angle on the Process Capability of Water Cavitation Peening
,” Surf. Coat. Technol.
0257-8972, 201
, pp. 1409
–1413
.14.
Grinspan
, A. Sahaya
, and Gnanamoorthy
, R.
, 2007, “Effect of Nozzle Traveling Velocity on Oil Cavitation Jet Peening of Aluminum Alloy, AA6063-T6
,” ASME J. Eng. Mater. Technol.
0094-4289, 129
, pp. 609
–614
.15.
Yamuchi
, Y.
, Soyama
, H.
, Adachi
, Y.
, Sato
, K.
, Shindo
, T.
, Oba
, R.
, Oshima
, R.
, and Yamabe
, M.
, 1995, “Suitable Regions of High Speed Submerged Water Jets for Cutting and Peening
,” JSME Int. J., Ser. B
1340-8054, 38
, pp. 31
–38
.16.
Chen
, Y. M.
, and Mongs
, J.
, 2005, “Cavitation Wear in Plain Bearing: Case Study
,” Mecanique & Industries
, 6
, pp. 195
–201
.17.
Tomita
, Y.
, and Shima
, A.
, 1986, “Mechanism of Impulse Pressure Generation and Damage Pit Formation by Bubble Collapse
,” J. Fluid Mech.
0022-1120, 169
, pp. 535
–564
.18.
Vyas
, B.
, and Preece
, C. M.
, 1976, “Stress Produced in a Solid by Cavitation
,” J. Appl. Phys.
0021-8979, 47
, pp. 5133
–5138
.19.
Dular
, M.
, Stoffel
, B.
, and Sirok
, B.
, 2006, “Development of a Cavitation Erosion Model
,” Wear
0043-1648, 261
, pp. 642
–655
.20.
2006, “
Standard Test Method for Erosion of Solid Materials by a Cavitation Liquid Jet
,” Annual Book of ASTM Standard 03.02, ASTM G 134-95, Philadelphia, PA.21.
Koilvula
, T.
, 2000, “On Cavitation in Fluid Power
” Proceedings of the First FPNI-PhD Symposium
, Hamburg, pp. 371
–382
.22.
Bansal
, R. K.
, 1996, Fluid Mechanics and Hydraulic Machines
, 5th ed., Laxmi
, New Delhi, India
, Chap. 7.23.
Preece
, C. M.
, and Brunton
, J. H.
, 1980, “A Comparison of Liquid Impact Erosion and Cavitation Erosion
,” Wear
0043-1648, 60
, pp. 269
–284
.24.
Pai
, R.
, and Hargreaves
, D. J.
, 2002, “Performance of Environment-Friendly Hydraulic Fluids and Material Wear in Cavitation Conditions
,” Wear
0043-1648, 252
, pp. 970
–978
.25.
Talks
, M. G.
, and Moreton
, G.
, 1981, “Cavitation Erosion of Fire Resistant Hydraulic Fluids
,” Proceedings of the ASME Symposium on Cavitation Erosion Fluid System
, pp. 139
–152
.26.
Tsujino
, T.
, Shima
, A.
, and Oikawa
, Y.
, 1990, “Cavitation Damage and Generated Noise in High Water Base Fluids
,” Trans. Jpn. Soc. Mech. Eng., Ser. B
0387-5016, 56
, pp. 3592
–3596
.27.
Yamaguchi
, A.
, and Shimizu
, S.
, 1987, “Erosion Due to Impingement of Cavitation Jet
,” ASME Trans. J. Fluids Eng.
0098-2202, 109
, pp. 442
–447
.28.
Soyama
, H.
, Yanauchi
, Y.
, Saito
, K.
, Ikohagi
, T.
, Oba
, R.
, and Oshima
, R.
, 1996, “High Speed Observation of Ultrahigh-Speed Submerged Water Jets
,” Exp. Therm. Fluid Sci.
0894-1777, 12
, pp. 411
–416
.29.
Rao
, P. V.
, and Buckley
, D. H.
, 1987, “Unfield Empirical Relations for the Cavitation and Liquid Impingement Erosion Processes
,” Wear
0043-1648, 120
, pp. 253
–288
.30.
Rao
, B. C. S.
, and Buckley
, D. H.
, 1984, “Deformation and Erosion of FCC Metals and Alloys Under Cavitation Attack
,” Mater. Sci. Eng.
0025-5416, 67
, pp. 55
–67
.31.
Sun
, Z.
, Kang
, X. Q.
, and Wang
, X. H.
, 2005, “Experimental System of Cavitation Erosion with Water Jet
,” Mater. Des.
0264-1275, 26
, pp. 59
–63
.32.
Field
, J. E.
, 1999, “ELSI Conference: Invited Lecture Liquid Impact: Theory, Experiment, Applications
,” Wear
0043-1648, 233–235
, pp. 1
–12
.33.
Haymann
, F. J.
, 1992, “Liquid Impingement Erosion
,” ASM HandBook
, Vol. 18
, Friction, Lubrication, and Wear Technology, ASM International
, Materials Park, OH
, pp. 221
–232
.34.
Karimi
, A.
, and Avellan
, F.
, 1986, “Comparison of Erosion Mechanisms in Different Types of Cavitation
,” Wear
0043-1648, 113
, pp. 305
–322
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