Advanced search
Publication Cover
Canadian Metallurgical Quarterly
The Canadian Journal of Metallurgy and Materials Science
Volume 63, 2024 - Issue 2
Submit an article Journal homepage
202
Views
2
CrossRef citations to date
0
Altmetric
Materials Processing, Characterization and Properties

The influence of compressive residual stress on metallurgical and mechanical properties of materials exposed to shot peening: a review

L'influence de la contrainte résiduelle de compression sur les propriétés métallurgiques et mécaniques des matériaux exposés au grenaillage: Une revue

Roshith PSchool of Mechanical Engineering, Vellore Institute of Technology, Vellore, IndiaCorrespondence[email protected] [email protected]
ORCID Iconhttps://orcid.org/0000-0001-9639-3467View further author information
ORCID Icon
Pages 373-413 | Received 24 Jan 2023, Accepted 05 May 2023, Published online: 19 May 2023

References

  • Yin F, Zhang X, Chen F, et al. Understanding the microstructure refinement and mechanical strengthening of dual-phase high entropy alloy during ultrasonic shot peening. Mater Des. 2023;227:111771.
  • Zhang Y, Zhang K, Hu Z, et al. The synergetic effects of shot peening and laser-shot peening on the microstructural evolution and fatigue performance of a medium carbon steel. Int J Fatigue. 2023;166:107246.
  • Wang Z, Xie L, Zhang Q, et al. Surface layer strengthening mechanism of 2060 aluminum-lithium alloy after shot-peening. J Mater Res Technol. 2023;23:4615–4633.
  • Almen JO, Black PH. Residual stresses and fatigue in metals. New York: McGraw-Hill Publ; 1963.
  • Yuan T, Dou M, Liu L, et al. Improving high temperature fretting fatigue performance of nickel-based single crystal superalloy by shot peening. Int J Fatigue. 2023;171:107563.
  • Goulmy JP, Boyer V, Retraint D, et al. Modeling of the shot peening of a nickel alloy with the consideration of both residual stresses and work hardening. Int J Solids Struct. 2023;264:112120.
  • Peral LB, Ebrahimzadeh P, Gutiérrez A, et al. Effect of tempering temperature and grain refinement induced by severe shot peening on the corrosion behavior of a low alloy steel. J Electroanal Chem. 2023;932:117207.
  • Zhou J, Xu X, Sun Z, et al. Predicting gradient mechanical behaviour of a shot-peened structure. Int J Solids Struct. 2023;262:112063.
  • Soady KA. Life assessment methodologies incorporating shot peening process effects: mechanistic consideration of residual stresses and strain hardening part 1 – effect of shot peening on fatigue resistance. Mater Sci Tech. 2013;29:637–651.
  • Almen J, Black JPH. Residual stresses and fatigue in metals. Toronto: McGraw-Hill; 1963. p. 64–69.
  • Hetram LS, Om H, Hetram LS, et al. Shot peening effects on material properties: a review. Int J Innov Res Sci Technol. 2015;1:480–484.
  • Bagherifard S, Ghelichi R, Guagliano M. A numerical model of severe shot peening (SSP) to predict the generation of a nanostructured surface layer of material. Surf Coat Technol. 2010;204:54–61.
  • Majzoobi GH, Ahmadkhani AR. The effects of multiple re-shot peening on fretting fatigue behavior of Al7075-T6. Surf Coat Technol. 2010;205:102–109.
  • Schiffner K, Droste gen. Helling C. Simulation of residual stresses by shot peening. Comput Struct. 1999;72:329–340.
  • Bagherifard S, Guagliano M. Fatigue behavior of a low-alloy steel with nano-structured surface obtained by severe shot peening. Eng Fract Mech. 2012;81:56–68.
  • Dai K, Shaw L. Comparison between shot peening and surface nanocrystallization and hardening processes. Mater Sci Eng A. 2007;463(1–2):46–53.
  • Baughman DL. An overview of peen forming technology. Proceedings of the 2nd International Conference on Shot Peening; 1984. p. 28–33.
  • Jinu GR, Sathiya P, Ravichandran G, et al. Investigation of the fatigue behaviour of butt-welded joints treated by ultrasonic peening process and compared with fatigue life assessment standards. Int J Adv Manuf Technol. 2009;40:74–83.
  • Kulekci MK, Esme U. Critical analysis of processes and apparatus for industrial surface peening technologies. Int J Adv Manuf Technol. 2014;74:1551–1565.
  • Fragoudakis R, Saigal A, Savaidis G, et al. Fatigue assessment and failure analysis of shot-peened leaf springs. Fatigue Fract Eng Mater Struct. 2013;36:92–101.
  • Chang SH, Lee SC, Tang TP. Effect of shot peening treatment on forging die life. Mater T Jim. 2008;49:619–623.
  • Maclejewski K, Ghonem H. Influence of continuum precipitates on intergranular fatigue crack growth of a P/M nickel-based superalloy. Mat Sci Eng A-Struct. 2013;560:439–449.
  • Lee H, Kim D, Jung J, et al. Influence of peening on the corrosion properties of AISI 304 stainless steel. Corros Sci. 2009;51(12):2826–2830.
  • Hao Y, Deng B, Zhong C, et al. Effect of surface mechanical attrition treatment on corrosion behavior of 316 stainless steel. J Iron Steel Res Int. 2009;16(2):68–72.
  • Dorr T, Hilpert M, Beckmerhagan P, et al. Influence of shot peening on fatigue performance of high-strength aluminum-and magnesium alloys. Proceedings of the ICSP-7 conference, Warsaw, Poland, 1999.
  • Obata M, Sudo A. Effect of shot peening on residual stress and stress corrosion cracking for cold worked austenitic stainless steel. Proceedings of the ICSP-5 Conference, Oxford, UK, 1993.
  • Arivarasu M, Roshith P, Padmanaban R, et al. Investigations on metallurgical and mechanical properties of CO2 laser beam welded Alloy 825. Can Metall Q. 2017;56(2):232–244.
  • Roshith P, Arivarasu M, Arivazhagan N, et al. Investigations on induced residual stresses,: mechanical and metallurgical properties of CO2 laser beam and pulse current gas tungsten arc welded SMO 254. J Manuf Processes. 2019;44:81–90.
  • Roshith P, Arivarasu M. Hot corrosion studies on fully austenitic stainless steel in air oxidation and simulated waste heat incinerator environment at 600°C, 650°C and 700°C. Mater Res Express. 2020;6(12):1265d1.
  • Sivamurugan P, Selvam R, Pandian M, et al. Extraction of novel biosilica from finger millet husk and its coconut rachilla-reinforced epoxy biocomposite: mechanical, thermal, and hydrophobic behaviour. Biomass Convers Biorefin. 2022: 1–9.
  • Roshith P. Enhancement of metallurgical and mechanical properties of the materials by performing CO2 Laser beam welding. Weld Int. 2021;35(1–3):59–80.
  • Ramesh B, Vempati S, Roshith P, et al. Comparison of Al2O3-reinforced sintered and extruded AA2014 nano-hybrid composite particle size effects on mechanical and metallurgical characteristics. ECS Trans. 2022;107(1):4077.
  • Roshith P, Arivarasu M. Improvements on hot corrosion behaviour of HVOF coated CO2 laser beam and pulsed gas tungsten arc weldments in 2.5% sulphur gas plus molten salt in industrial waste incinerator environment. Eng Res Express. 2022;4(2):025003.
  • Roshith P, Arivarasu M. Hot corrosion and air oxidation behavior of pulsed current gas tungsten arc welded and CO2 laser beam welded SMO 254 at 800°C. Weld In. 2022;36:394–413.
  • Miao HY, Demers D, Larose S, et al. Experimental study of shot peening and stress peen forming. J Mater Process Technol. 2010;210(15):2089–2102.
  • Kyriacou S. Shot-peening mechanics, a theoretical study. Proceedings of the 6th International Conference on Shot Peening, 1996. p. 505–516.
  • Meguid SA, Shagal G, Stranart JC, et al. Three-dimensional dynamic finite element analysis of shot-peening induced residual stresses. Finite Elem Anal Des. 1999;31:179–191.
  • Karuppanan S, Romero JS, de los Rios ER, et al. A theoretical and experimental investigation into the development of coverage in shot peening. Proceedings of the 8th International Conference on Shot Peening; 2002. p. 101–107.
  • Kirk D, Abyaneh MY. (1993). Theoretical basis of shot peening coverage control. Proceedings of the 5th International Conference on Shot Peening, pp. 183–190.
  • Sharp PK, Clayton JQ, Clark G. The fatigue resistance of peened 7050-T7451 aluminum alloy-repair and re-treatment of a component surface. Fatigue Fract Eng Mater Struct. 1994;17(3):243–252.
  • Curtis S, de los Rios ER, Rodopoulos CA, et al. Analysis of the effects of controlled shot peening on fatigue damage of high strength aluminum alloys. Int J Fatigue. 2003;25:59–66.
  • Bagherifard S, Ghelichi R, Guagliano MA. numerical model of severe shot peening (SSP) to predict the generation of a nanostructured surface layer of material. Surf Coat Technol. 2010;204(24):4081–4090.
  • Kuba P, Sedláček V. Some theoretical problems of shot peening. Surf Eng. 1990: 393–403. Springer, Dordrecht.
  • Rykovskij BP, Smirnov VA, Scetinin GM. Mestnoje uprocnenije detalej poverchnostnym naklepom. Moskva: Masinostrojenije; 1985.
  • Al-Hassani STS. An engineering approach to shot peening mechanics.Proc. Of the second. Int. Conf. On Shot peening.1984. p. 275–282.
  • Mehmood A, Hammouda MMI. Effect of shot peening on the fatigue life of 2024 aluminum alloy Fatigue Fract Eng Mater Struct; 2007.
  • Gariépy A, Bridier F, Hoseini M, et al. Experimental and numerical investigation of material heterogeneity in shot peened aluminium alloy AA2024-T351. Surf Coat Technol. 2013;219:15–30.
  • Oguri K. Fatigue life enhancement of aluminum alloy for aircraft by Fine Particle Shot Peening (FPSP). J Mater Process Technol. 2011;211(8):1395–1399.
  • Rodopoulos CA, Curtis SA, De los Rios ER, et al. Optimisation of the fatigue resistance of 2024-T351 aluminium alloys by controlled shot peening—methodology, results and analysis. Int J Fatigue. 2004;26(8):849–856.
  • Gao YK, Wu XR. Experimental investigation and fatigue life prediction for 7475-T7351 aluminum alloy with and without shot peening-induced residual stresses. Acta Mater. 2011;59(9):3737–3747.
  • Was GS, Pelloux RM. The effect of shot peening on the fatigue behavior of alloy 7075-T6. Metall Trans A. 1979;10:656–658.
  • Benedetti M, Fontanari V, Bandini M, et al. Multiaxial fatigue resistance of shot peened high-strength aluminum alloys. Int J Fatigue. 2014;61:271–282.
  • Benedetti M, Fontanari V, Santus C, et al. Notch fatigue behaviour of shot peened high-strength aluminium alloys: experiments and predictions using a critical distance method. Int J Fatigue. 2010;32(10):1600–1611.
  • Benedetti M, Fontanari V, Scardi P, et al. Reverse bending fatigue of shot peened 7075-T651 aluminium alloy: The role of residual stress relaxation. Int J Fatigue. 2009;31(8–9):1225–1236.
  • Pandey V, Singh JK, Chattopadhyay K, et al. Influence of ultrasonic shot peening on corrosion behavior of 7075 aluminum alloy. J Alloys Compd. 2017;723:826–840.
  • Palacios M, Bagherifard SA, Guagliano MA, et al. Influence of severe shot peening on wear behaviour of an aluminium alloy. Fatigue Fract Eng Mater Struct. 2014;37(7):821–829.
  • Benedetti M, Fontanari V, Bandini M, et al. High-and very high-cycle plain fatigue resistance of shot peened high-strength aluminum alloys: the role of surface morphology. Int J Fatigue. 2015;70:451–462.
  • Trško L, Guagliano M, Bokůvka O, et al. Influence of severe shot peening on the surface state and ultra-high-cycle fatigue behavior of an AW 7075 aluminum alloy. J Mater Eng Perform. 2017;26(6):2784–2797.
  • Sharp PK, Clark G. The effect of peening on the fatigue life of aluminium alloys. Advances in Fracture Research. ICF9. Vol. 3. Fatigue of Met & Non Met Mater Struct ; Sydney; Australia; 1997. p. 1491–1499.
  • Farrahi GH, Jafarzadeh H. Esmaeili MA. Experimental analysis on the material properties of A356. 0 aluminum alloy surface nanostructured by severe shot peening. J Mater Eng Perform. 2020;29(1):143–154.
  • González J, Bagherifard S, Guagliano M, et al. Influence of different shot peening treatments on surface state and fatigue behaviour of Al 6063 alloy. Eng Fract Mech. 2017;185:72–81.
  • Nasiłowska B, Bogusz P, Skrzeczanowski W. The influence of shot peening on structure and mechanical properties of 5754 aluminium alloy joints welded with TIG method. Procedia Struct Integrity. 2019;23:583–588.
  • Martín V, Vázquez J, Navarro C, et al. Effect of shot peening residual stresses and surface roughness on fretting fatigue strength of Al 7075-T651. Tribol Int. 2020;142:106004.
  • Liu H, Chen M, Wang L, et al. Investigation on microstructure and properties of Al18B4O33 whisker reinforced AlMgSi matrix composite after shot peening. Vac. 2019;160:303–310.
  • Nie L, Wu Y, Gong H, et al. Effect of shot peening on redistribution of residual stress field in friction stir welding of 2219 aluminum alloy. Mater. 2020;13(14):3169.
  • Wu Q, Xie DJ, Jia ZM, et al. Effect of shot peening on surface residual stress distribution of SiCp/2024Al. Compos Part B Eng. 2018;2(154):382–387.
  • Trško L, Fintová S, Nový F, et al. Study of relation between shot peening parameters and fatigue fracture surface character of an AW 7075 aluminium alloy. Met. 2018;8(2):111.
  • Shareef MNM. Effect of shot peening on mechanical properties and endurance limit of composite materials [M.Sc thesis]. Mechanical Engineering Department, University of Technology, Baghdad, Iraq; 2014.
  • Al-Khazraji AN, Shareef MN. Comparison of fatigue life behavior between two different composite materials subjected to shot peening at different times. Al-Khawarizmi Eng J. 2014;10(3):1–12.
  • Becker A. The effect of laser shock peening and shot peening on the fatigue performance of aluminium alloy 7075 [M.Sc thesis]. Center of Materials Engineering Department, University of Cape Town, South Africa; 2017.
  • Locke JE, Kumar B, Salah L 2007 Effect of shot peening on the fatigue endurance and fatigue crack growth rate of 7050 & 7075 aluminum alloys. Wichita, KA: National Institute of Aviation Research, Wichita State University, USA.
  • Bae H, Diep H, Ramulu M. Influence of shot peening coverage on residual stresses induced in aluminum alloy 7050-T7 45. Proc. 12th Int. Conf. of Shot Peening ICSP-12; 2014.
  • Yan FJ, Wang XG, Wang XM, et al. Effect of shot peening and pre-oxidation duplex treatment on electrochemical corrosion behavior of Al alloy in alkaline soil. Int J Electrochem Sci. 2017;12:11212–11223.
  • Zupanc U, Grum J. Effect of pitting corrosion on fatigue performance of shot-peened aluminium alloy 7075-T651 J. Mater Process Technol. 2010;210(9):1197–1202.
  • Mhaede M. Influence of surface treatments on surface layer properties,: fatigue and corrosion fatigue performance of AA7075 T73. Mater Des. 2012;41:61–66.
  • Honda T, Ramulu M, Kobayashi AS. Fatigue of shot peened 7075-T7351 SENB specimen—a 3-D analysis. Fatigue Fract Eng Mater Struct. 2006;29(6):416–424.
  • Rajesh A, Varthanan PA. Investigation of fatigue strength of aluminium 2024-T3 subjected to shot peening process by Ni shots. Mater Res Express. 2020;7(1):016593.
  • Carvalho ALM, Voorwald HJC. Influence of shot peening and hard chromium electroplating on the fatigue strength of 7050-T7451 aluminum alloy. Int J Fatigue. 2007;29:1282–1291.
  • Cho KT, Song K, Oh SH, et al. Surface hardening of aluminum alloy by shot peening treatment with Zn based ball Mater. Sci Eng A. 2012;543:44–49.
  • He Y-z, Wang D-p, Wang Y, et al. Correction of buckling distortion by ultrasonic shot peening treatment for 5A06 aluminum alloy welded structure. T Nonferr Metal Soc. 2016;26:1531–1537.
  • Atieh A M, Allaf R M, AlHazaa A, et al. Effect of pre-and post-weld shot peening on the mechanical & tribological properties of tig welded aluminum 6061-T6 alloy. Trans Can Soc Mech Eng. 2017;41(2):197–209.
  • Yan FJ, Wang XG, Wang XM, et al. Effect of shot peening and Pre-Oxidation duplex treatment on electrochemical corrosion behavior of Al alloy in alkaline soil. Int J Electrochem Sci. 2017;12:11212–11223.
  • Tao WXN, Hong Y, Xu B, et al. Microstrueture and evolution of mechanieaily-induced ultra. Fine grain in surface layer of M-alloy subjected to USSP. Acta Mater. 2002;50:2075–2084.
  • Trško L, Fintová S, Nový F, et al. Study of relation between shot peening parameters and fatigue fracture surface character of an AW 7075 aluminium alloy. Met. 2018;8(2):111.
  • Sun Q, Han Q, Liu X, et al. The effect of surface contamination on corrosion performance of ultrasonic shot peened 7150 Al alloy. Surf Coat Technol. 2017;328:469–479.
  • Sun Q, Han Q, Xu R, et al. Localized corrosion behaviour of AA7150 after ultrasonic shot peening: corrosion depth vs. impact energy. Corros Sci. 2018;130:218–230.
  • Mai J, Jie X-H, Liu L-L, et al. Thermal stability of nanocrystalline layers fabricated by surface nanocrystallization. Appl Surf Sci. 2010;256(7):1972–1975.
  • Pandey V, Chattopadhyay K, Srinivas NS, et al. Role of ultrasonic shot peening on low cycle fatigue behavior of 7075 aluminium alloy. Int J Fatigue. 2017;103:426–435.
  • Rodopoulos CA, Romero JS, Curtis SA, et al. Effect of controlled shot peening and laser shock peening on the fatigue performance of 2024-T351 aluminum alloy. J Mater Eng Perform. 2003;12(4):414–419.
  • Luong H, Hill MR. The effects of laser peening and shot peening on high cycle fatigue in 7050-T7451 aluminum alloy. Mater Sci Eng A. 2010;527(3):699–707.
  • Gao YK. Improvement of fatigue property in 7050–T7451 aluminum alloy by laser peening and shot peening. Mater Sci Eng A. 2011;528(10–11):3823–3828.
  • Vázquez J, Navarro C, Domínguez J. Experimental results in fretting fatigue with shot and laser peened Al 7075-T651 specimens. Int J Fatigue. 2012;40:143–153.
  • Asquith DT, Yerokhin AL, Yates JR, et al. Effect of combined shot-peening and PEO treatment on fatigue life of 2024 Al alloy. Thin Solid Films. 2006;515(3):1187–1191.
  • Carvalho AL, Voorwald HJ. Influence of shot peening and hard chromium electroplating on the fatigue strength of 7050-T7451 aluminum alloy. Int J Fatigue. 2007;29(7):1282–1291.
  • Majzoobi G, Azadikhah K, Nemati J. The effects of deep rolling and shot peening on fretting fatigue resistance of aluminum-7075-T6. Mater Sci Eng A. 2009;516:235–247.
  • Majzoobi G, Nemati J, Novin Rooz A, et al. Modification of fretting fatigue behavior of AL7075–T6 alloy by the application of titanium coating using IBED technique and shot peening. Tribol Int. 2009;42:121–129.
  • Hadzima B, Nový F, Trško L, et al. Shot peening as a pre-treatment to anodic oxidation coating process of AW 6082 aluminum for fatigue life improvement. Int J Adv Manuf Technol. 2017;93(9-12):3315–3323.
  • Voorwald CA. Influence of anodization on the fatigue strength of 7050-T7451 aluminium alloy. Fatigue Fract Eng Mater Struct. 2007;30:993–1007.
  • Bagherifard S, Beretta N, Monti S, et al. On the fatigue strength enhancement of additive manufactured AlSi10Mg parts by mechanical and thermal post-processing. Mater Des. 2018;145:28–41.
  • Huang Y, Liu WC, Dong J. Surface characteristics and fatigue performance of warm shot peened wrought magnesium alloy Mg–9Gd–2Y. Mater Sci Technol Oct 1. 2014;30(12):1481–1487.
  • Bastos YC, Fernandes MF, de Oliveira Velloso VM, et al. Plasma immersion ion implantation and shot peening influence on the fatigue strength of AA 7050-T7451 aluminum alloy. Eng Res Express. 2020;2(1):015015.
  • Bianchetti C, Lévesque M, Brochu M. Probabilistic analysis of the effect of shot peening on the high and low cycle fatigue behaviors of AA 7050-T7451. Int J Fatigue. 2018;111:289–298.
  • Pathak A, Munjadas K. Parameter optimization of shot peening process of PMG AL2024 alloy cover. IOSR J Mech Civ Eng. 2017;14(1):60–69.
  • Curtis SA, de los Rios ER, Rodopoulos CA, et al. Investigating the benefits of controlled shot peening on corrosion fatigue of aluminium alloy 2024 T351. Shot Peening. 2003;T351:264–270.
  • De Los Rios ER, Trull M, Levers A. Modelling fatigue crack growth in shot-peened components of Al 2024-T351. Fatigue Fract Eng Mater Struct. 2000;8:709–716.
  • Pathak A, Munjadas K. Fatigue life prediction & enhancement of PMG cover Al 2024 alloy. Int J Adv Eng Res Sci. 2017;6(1):16.
  • Ferreira N, Antunes PV, Ferreira JA, et al. Effects of shot-peening and stress ratio on the fatigue crack propagation of AL 7475-T7351 specimens. Appl Sci. 2018;3:375.
  • Alkan Z, Selver R, Varol R. Investigation of shot peening effect on mechanical and physical properties of aluminum alloys. J Miner Metal Mater Eng. 2016;2:47–52.
  • Hatamleh O, Lyons J, Forman R. Laser peening and shot peening effects on fatigue life and surface roughness of friction stir welded 7075-T7351 aluminum. Fatigue Fract Eng Mater Struct. 2007;2:115–130.
  • Honda T, Ramulu M, Kobayshi AS. Shot peening and fatigue crack growth in 7075-T7351 aluminum. Key Eng Mater. 2005;297:72–77. Trans Tech Publications Ltd.
  • Karuppanan S, Romero JS, de los Rios ER, et al. theoretical and experimental investigation into the development of coverage in shot peening. Shot Peening. 2003: 101–107.
  • Lavrentyev AI, Veronesi WA. Ultrasonic measurement of residual stress in shot peened aluminum alloy. AIP Conference Proceedings. American Institute of Physics; 2001;557(1):1472–1479.
  • Sabelkin V, Martinez SA, Mall S, et al. Effects of shot-peening intensity on fretting fatigue crack-initiation behaviour of Ti-6Al-4 V. Fatigue Fract Eng Mater Struct. 2005;28:321–332.
  • Drechsler A, Dörr T, Wagner L. Mechanical surface treatments on Ti-10V-2Fe-3Al for improved fatigue resistance. Mater Sci Eng A. 1998;243:217–220.
  • Sridhar BR, Nafde WG, Padmanabhan KA. Effect of shot peening on the residual stress distribution in two commercial titanium alloys. J Mater Sci. 1992;27(21):5783–5788.
  • Sridhar BR, Ramachandra K, Padmanabhan KA. Effect of shot peening on the fatigue and fracture behaviour of two titanium alloys. J Mater Sci. 1996;31(22):5953–5960.
  • Lee H, Jin O, Mall S. Fretting fatigue behaviour of shot-peened Ti-6Al-4 V at room and elevated temperatures. Fatigue Fract Eng Mater Struct. 2003;9:767–778.
  • Drechsler A, Kiese J, Wagner L. Effects of shot peening and roller-burnishing on fatigue performance of various titanium alloys. Warsaw, Poland: Shot Peening, Institute of Precision Mechanics; 1999. p. 145–152.
  • Tang C-B, Liu D-X, Tang B, et al. Influence of plasma molybdenizing and shot-peening on fretting damage behavior of titanium alloy. Appl Surf Sci. 2016;390:946–958.
  • Jiang XP, Man CS, Shepard MJ, et al. Effects of shot-peening and re-shot-peening on four-point bend fatigue behavior of Ti–6Al–4 V. Mater Sci Eng A. 2007;15(468):137–143.
  • Lindemann J, Buque C, Appel F. Effect of shot peening on fatigue performance of a lamellar titanium aluminide alloy. Acta Mater. 2006;54(4):1155–1164.
  • Liu D, Tang B, Zhu X, et al. Improvement of the fretting fatigue and fretting wear of Ti6Al4V by duplex surface modification. Surface and coatings Technology. 1999;116:234–238.
  • Martinez S, Sathish S, Blodgett M, et al. Effects of fretting fatigue on the residual stress of shot peened Ti–6Al–4 V samples. Mater Sci Eng A. 2005;399(1–2):58–63.
  • Wagner L, Luetjering G. Influence of shot peening on the fatigue behavior of titanium alloys. Proc. of the First Int. Conf. on Shot Peening, Paris. France. 1996: 453–460.
  • Kumar RK, SampathKumaran P, Seetharamu S, et al. Investigation of shot peening effect on titanium alloy affecting surface residual stress and roughness for aerospace applications. Procedia Struct Integrity. 2019;14:134–141.
  • Zhang Z, Ming LI, Seng DH, et al. Fatigue life enhancement in Alpha/Beta Ti-6Al-4 V after shot peening: an EBSD and TEM crystallographic orientation mapping study of surface layer. Mater. 2020;12:100813.
  • Song Y, Zhao Z, Lu F. Experimental study of the influence of shot peening on the microstructure and properties of surface layer of a TC21 titanium alloy. Atlas J Mater Sci. 2014;1(1):17–23.
  • Żebrowski R, Walczak M, Klepka T, et al. Effect of the shot peening on surface properties of Ti-6Al-4 V alloy produced by means of DMLS technology. Eksploatacja i Niezawodność. 2019;21:46–53.
  • Ganesh BKC, Sha W, Ramanaiah N, et al. Effect of shotpeening on sliding wear and tensile behavior of titanium implant alloys. Mater Des. 2014;56:480–486. https://doi.org/10.1016/j.matdes.2013.11.052.
  • Żebrowski R, Walczak M, Korga A, et al. Effect of shot peening on the mechanical properties and cytotoxicity behaviour of titanium implants produced by 3D printing technology. J Healthcare Eng. 2019;2019:11.
  • Ahmed AA, Mhaede M, Wollmann M, et al. Effect of micro shot peening on the mechanical properties and corrosion behavior of two microstructure Ti–6Al–4 V alloy. Appl Surf Sci. 2016;363:50–58.
  • Jia W, Hong Q, Zhao H, et al. Effect of laser shock peening on the mechanical properties of a near-α titanium alloy. Mater Sci Eng A. 2014;606:354–359.
  • Xie L, Wen Y, Zhan K, et al. Characterization on surface mechanical properties of Ti–6Al–4 V after shot peening. J Alloys Compd. 2016;666:65–70.
  • Tsuji N, Tanaka S, Takasugi T. Effects of combined plasma-carburizing and shot-peening on fatigue and wear properties of Ti–6Al–4 V alloy. Surf Coat Technol. 2009;203(10–11):1400–1405.
  • Yu S, Liu D, Zhang X, et al. Effects of combined plasma chromizing and shot peening on the fatigue properties of a Ti6Al4V alloy. Appl Surf Sci. 2015;353:995–1002.
  • Ahmed AA, Mhaede M, Wollmann M, et al. Effect of micro shot peening on the mechanical properties and corrosion behavior of two microstructure Ti–6Al–4 V alloy. Appl Surf Sci. 2016;363:50–58.
  • Oshida Y, Sachdeva R, Miyazaki S, et al. Effects of shot-peening on surface contact angles of biomaterials. J Mater Sci Mater Med. 1993;4(5):443–447.
  • Chakravarty S, Andrews RG, Painaik PC, et al. The effect of surface modification on fretting fatigue in Ti alloy turbine components. Jom. 1995;47(4):31–35.
  • Fridrici V, Fouvry S, Kapsa P. Effect of shot peening on the fretting wear of Ti–6Al–4 V. Wear. 2001;250(1–12):642–649.
  • Lee H, Mall S, Allen WY. Fretting fatigue behavior of shot-peened Ti–6Al–4 V under seawater environment. Mater Sci Eng A. 2006;420(1–2):72–78.
  • Lainé SJ, Knowles KM, Doorbar PJ, et al. Microstructural characterisation of metallic shot peened and laser shock peened Ti–6Al–4 V. Acta Mater. 2017;123:350–361.
  • Zhang X, Liu D. Effect of shot peening on fretting fatigue of Ti811 alloy at elevated temperature. Int J Fatigue. 2009;31(5):889–893.
  • Yao C, Wu D, Ma L, et al. Surface integrity evolution and fatigue evaluation after milling mode, shot-peening and polishing mode for TB6 titanium alloy. Appl Surf Sci. 2016;387:1257–1264.
  • Stráský J, Havlíková J, Bačáková L, et al. Characterization of electric discharge machining, subsequent etching and shot-peening as a surface treatment for orthopedic implants. Appl Surf Sci. 2013;281:73–78.
  • Yang Q, Zhou W, Gai P, et al. Investigation on the fretting fatigue behaviors of Ti-6Al-4 V dovetail joint specimens treated with shot-peening. Wear. 2017;372:81–90.
  • Yang Q, Zhou W, Zhong Y, et al. Effect of shot-peening on the fretting wear and crack initiation behavior of Ti-6Al-4 V dovetail joint specimens. Int J Fatigue. 2018;107:83–95.
  • Aparicio C, Gil FJ, Fonseca C, et al. Corrosion behaviour of commercially pure titanium shot blasted with different materials and sizes of shot particles for dental implant applications. Bio Mater. 2003;24(2):263–273.
  • Yu ZL, Li SX, Liu YY, et al. Effect of surface treatments on fatigue life of Ti-6-22-22 alloy at room and high temperatures. Mater Sci Eng A. 2004;383(2):283–288.
  • Thomas M, Lindley T, Jackson M. The microstructural response of a peened near-α titanium alloy to thermal exposure. Scr Mater. 2009;60(2):108–111.
  • Thomas M, Jackson M. The role of temperature and alloy chemistry on subsurface deformation mechanisms during shot peening of titanium alloys. Scr Mater. 2012;66:1065–1068.
  • Gao YK. Influence of shot peening on fatigue property of Ti-60 high temperature titanium alloy. Surface engineering. 2007;23(6):431–433.
  • Kanjer A, Lavisse L, Optasanu V, et al. Effect of laser shock peening on the high temperature oxidation resistance of titanium. Surf Coat Technol. 2017;326:146–155.
  • Kumar SA, Raman SGS, Narayanan TS, et al. Influence of counterbody material on fretting wear behaviour of surface mechanical attrition treated Ti–6Al–4 V. Tribol Int. 2013;57:107–114.
  • Chen G-Q, Yan J, Tian T-Y, et al. Effect of wet shot peening on Ti-6Al-4 V alloy treated by ceramic beads. Trans Nonferrous Met Soc China. 2014;24(3):690–696.
  • Liu YG, Li HM, Li MQ. Characterization of surface layer in TC17 alloy treated by air blast shot peening. Mater Des (1980–2015). 2015;65:120–126.
  • Zhao W, Liu Y, Liu L, et al. Surface recrystallization of a gamma-TiAl alloy induced by shot peening and subsequent annealing treatments. Appl Surf Sci. 2013;270:690–696.
  • Yao Q, Sun J, Zhang G, et al. Influence of ultrafine-grained layer on gaseous nitriding of large-sized titanium plate. Adv Eng Mater. 2018;20(1):1700455.
  • Byrne GD, O’Neill L, Twomey B, et al. Comparison between shot peening and abrasive blasting processes as deposition methods for hydroxyapatite coatings onto a titanium alloy. Surf Coat Technol. 2013;216:224–231.
  • Miková K, Bagherifard S, Bokuvka O, et al. Fatigue behavior of X70 microalloyed steel after severe shot peening. Int J Fatigue. 2013;55:33–42.
  • Unal O, Varol R. Surface severe plastic deformation of AISI 304 via conventional shot peening,: severe shot peening and repeening. Appl Surf Sci. 2015;351:289–295.
  • Bagherifard S, Fernandez-Pariente I, Ghelichi R, et al. Effect of severe shot peening on microstructure and fatigue strength of cast iron. Int J Fatigue. 2014;65:64–70.
  • Bagherifard S, Slawik S, Fernández-Pariente I, et al. Nanoscale surface modification of AISI 316L stainless steel by severe shot peening. Mater Des. 2016;102:68–77.
  • Fu P, Zhan K, Jiang C. Micro-structure and surface layer properties of 18CrNiMo7-6 steel after multistep shot peening. Mater Des. 2013;51:309–314.
  • Kämmler J, Wielki N, Guba N, et al. Shot peening using spherical micro specimens generated in high-throughput processes. Materialwiss Werkstofftech. 2019;50(1):5–13.
  • Benchouia S, Merakeb N, Adjel S, et al. Fatigue life enhancement of TIG-welded 304L stainless steels by shot peening. Int J Adv Manuf Technol. 2019;100(9–12):2885–2893.
  • Selvabharathi R, Muralikannan R. Influence of shot peening and plasma ion nitriding on tensile strength of 2205 duplex stainless steel using A-PAW. Mater Sci Eng A. 2018;709:232–240.
  • Kirk D, Payne NJ. Transformations induced in austenitic stainless steels by shot peening. Proc ICSP. 1999;7:15–22.
  • Singh L, Khan RA, Aggarwal ML. Influence of residual stress on fatigue design of AISI 304 stainless steel. J Eng Res TJER. 2011;8(1):44–52.
  • Yan W, Fang L, Zheng Z, et al. Effect of surface nanocrystallization on abrasive wear properties in hadfifield steel. Tribol Int. 2009;42(5):634–641.
  • Miková K, Bagherifard S, Bokuvka O, et al. Fatigue behavior of X70 microalloyed steel after severe shot peening. Int J Fatigue. 2013;55:33–42.
  • Fernández-Pariente I, Bagherifard S, Guagliano M, et al. Short crack fatigue threshold of a nitrided and shot peened low alloy steel. Procedia Eng. 2011;10:3588–3595.
  • Akyıldız HK, Kulekci MK, Esme U. Influence of shot peening parameters on high-cycle fatigue strength of steel produced by powder metallurgy process. Fatigue Fract Eng Mater Struct. 2015;238(10):1246–1254.
  • Wu X, Qi Z, Zhou Z, et al. Surface grain refinement of 304L stainless steel by combined severe shot peening and reversion annealing treatment. Coat. 2020;5:470.
  • Lu Z, Shi L, Zhu S, et al. Effect of high energy shot peening pressure on the stress corrosion cracking of the weld joint of 304 austenitic stainless steel. Mater Sci Eng A. 2015;637:170–174.
  • Brass AM, Chene J. Role of shot-peening on hydrogen embrittlement of a low-carbon steel and a 304 stainless steel. J Mater Sci. 1991;26:4517–4526.
  • Wang Y, Xie H, Zhou Z, et al. Effect of shot peening coverage on hydrogen embrittlement of a ferrite-pearlite steel. Int J Hydrogen Energy. 2020;45:7169–7184.
  • Chen M, Liu H, Wang L, et al. Residual stress and microstructure evolutions of SAF 2507 duplex stainless steel after shot peening. Appl Surf Sci. 2018;459:155–163.
  • Hussain J, Murdhi SS. Effect of shot peening time on fatigue properties of stainless steel shaft turbine. J Eng Sust De. 2012;16(4):411–424.
  • Masaki K, Ochi Y, Matsumura T, et al. Effects of laser peening treatment on high cycle fatigue properties of degassing-processed cast aluminum alloy. Mater Sci Eng A. 2007;468:171–175.
  • Everett RA, Mathews W, Prabhakaran R, et al. The effect of shot and laser peening on fatigue life and crack growth in 2024 aluminum alloy and 4340 steel. NASA/TM-2001-210843 ARL-TR-2363; 2001.
  • Singh L, Khan RA, Aggarwal AL. Effect of shot peening on hardening and surface roughness of nitrogen austenitic stainless steel. Eng Sci Technol an Int J. 2010;2(5):818–826.
  • Obata M, Sudo A. (1991). Effect of shot peening on residual stress and stress corrosion cracking for cold worked austenitic stainless steel. Proceedings of the ICSP-5 Conference, Oxford, UK.
  • Gilioli A, Braconi D, Bagherifard S, et al. The role of shot peening in the design of an innovative twin engine pack system (TEPS) for helicopters.
  • Wang C, Wang C, Wang L, et al. A dislocation density–based comparative study of grain refinement,: residual stresses, and surface roughness induced by shot peening and surface mechanical attrition treatment. Int J Adv Manuf Technol. 2020;108:505–525.
  • Everett R A, Matthews W T, Prabhakaran R, et al. The effects of shot and laser peening on crack growth and fatigue life in 2024 aluminium alloy and 4340 steel. Virginia: Nasa Centre for Aero Space Information (CASI). National Technical Information Service (NTIS); 1993.
  • Ahmed AA, Mhaede M, Basha M, et al. The effect of shot peening parameters and hydroxyapatite coating on surface properties and corrosion behavior of medical grade AISI 316L stainless steel. Surf Coat Technol. 2015;280:347–358.
  • AlMangour B, Yang JM. Improving the surface quality and mechanical properties by shot-peening of 17-4 stainless steel fabricated by additive manufacturing. Mater Des. 2016;110:914–924.
  • Al-Turaihi A, Mehmanparast A, Brennan F. The influence of partial surface shot peening on fatigue crack growth behaviour of a high-strength ferritic steel. Fatigue Fract Eng Mater Struct. 2018;3:663–674.
  • Gan J, Sun D, Wang Z, et al. The effect of shot peening on fatigue life of Q345D T-welded joint. J Constr Steel Res. 2016;126:74–82.
  • Pyttel B, Varfolomeyev I, Luke M, et al. FKM guideline ‘fracture mechanics proof of strength for engineering components’—overview and extension topics. Weld World. 2013;51(5–6):85–93.
  • Giannakis E, Savaidis G. Fatigue assessment of high strength leaf springs based on the FKM guideline. Materwiss Werksttech. 2016;47(10):897–903.
  • Mahmoudi AH, Ghasemi A, Farrahi GH, et al. A comprehensive experimental and numerical study on redistribution of residual stresses by shot peening. Mater Des. 2016;90:478–487.
  • Bag A, Delbergue D, Bocher P, et al. Statistical analysis of high cycle fatigue life and inclusion size distribution in shot peened 300M steel. Int J Fatigue. 2019;118:126–138.
  • Bagherifard S, Guagliano M. Fatigue behavior of a low-alloy steel with nanostructured surface obtained by severe shot peening. Eng Fract Mech. 2012;81:56–68.
  • Bagherifard S, Ghelichi R, Guagliano M. On the shot peening surface coverage and its assessment by means of finite element simulation: a critical review and some original developments. Appl Surf Sci. 2012;259:186–194.
  • Adachi A. Fatigue strength of gear steels shot peened in extremely high intensity conditions. Proceeding of 4th International Conference on Shot Peening, Tokyo, Japan; 1990. p. 363–372.
  • Bagherifard S, Hickey DJ, de Luca AC, et al. The influence of nanostructured features on bacterial adhesion and bone cell functions on severely shot peened 316L stainless steel. Bio Mater. 2015;73:185–197.
  • Chaib M, Belhamiani M, Megueni A, et al. Experimental study of shot peening effect on the surface of austenitic stainless steels: roughness, residual stresses and workhardening. 7th African Conference on Non Destructive Testing ACNDT 2016 & the 5th International Conference on NDT and Materials Industry and Alloys (IC-WNDT-MI); 2016.
  • Chen M, Liu H, Wang L, et al. Residual stress and microstructure evolutions of SAF 2507 duplex stainless steel after shot peening. Appl Surf Sci. 2018;459:155–163.
  • Chen M, Jiang C, Xu Z, et al. Experimental study on macro-and microstress state,: microstructural evolution of austenitic and ferritic steel processed by shot peening. Surf Coat Technol. 2019;359:511–519.
  • Dalaei K, Karlsson B. Influence of shot peening on fatigue durability of normalized steel subjected to variable amplitude loading. Int J Fatigue. 2012;38:75–83.
  • De los Rios ER, Mercier P, El-Sehily BM. Short crack growth behaviour under variable amplitude loading of shot peened surfaces. Fatigue Fract Eng Mater Struct. 1996;19(2–3):175–184.
  • Jung JS, Pyoun Y, Cho I. Effect of ultrasonic and air blast shot peening on the microstructural evolution and mechanical properties of SUS304. J Korean Phys Soc. 2009;54(3):1161–1166.
  • Menezes MR, Godoy C, Buono VT, et al. Effect of shot peening and treatment temperature on wear and corrosion resistance of sequentially plasma treated AISI 316L steel. Surf Coat Technol. 2017;309:651–662.
  • Fargas G, Roa JJ, Mateo A. Effect of shot peening on metastable austenitic stainless steels. Mater Sci Eng A. 2015;641:290–296.
  • Fragoudakis R, Saigal A, Savaidis G, et al. Fatigue assessment and failure analysis of shot-peened leaf springs. Fatigue Fract Eng Mater Struct. 2013;36(2):92–101.
  • Fu P, Chu R, Xu Z, et al. Relation of hardness with FWHM and residual stress of GCr15 steel after shot peening. Appl Surf Sci. 2018;431:165–169.
  • Gerin B, Pessard E, Morel F, et al. A non-local approach to model the combined effects of forging defects and shot-peening on the fatigue strength of a pearlitic steel. Theor Appl Fract Mech. 2018;93:19–32.
  • Habibi NH, Gangaraj SM, Farrahi GH, et al. The effect of shot peening on fatigue life of welded tubular joint in offshore structure. Mater Des (1980–2015). 2012;36:250–257.
  • Harada Y, Kosaka H, Ishihara M. Effect of shot peening on fatigue strength of high-T oughness spring steel. Steel Res Int. 2013;84(12):1333–1339.
  • Hashemi B, Yazdi MR, Azar V. The wear and corrosion resistance of shot peened–nitrided 316L austenitic stainless steel. Mater Des. 2011;32(6):3287–3292.
  • Hassani-Gangaraj SM, Moridi A, Guagliano M, et al. The effect of nitriding, severe shot peening and their combination on the fatigue behavior and micro-structure of a low-alloy steel. Int J Fatigue. 2014;62:67–76.
  • Guiheux R, Berveiller S, Kubler R, et al. Martensitic transformation induced by single shot peening in a metastable austenitic stainless steel 301LN: experiments and numerical simulation. J Mater Process Technol. 2017;249:339–349.
  • He BY, Soady KA, Mellor BG, et al. Effects of shot peening on short crack growth rate and resulting low cycle fatigue behaviour in low pressure turbine blade material. Mater Sci Technol. 2013;29(7):788–796.
  • Hensel J, Eslami H, Nitschke-Pagel T, et al. Fatigue strength enhancement of butt welds by means of shot peening and clean blasting. Met. 2019;9(7):744.
  • Jayalakshmi M, Huilgol P, Bhat BR, et al. Microstructural characterization of low temperature plasma-nitrided 316L stainless steel surface with prior severe shot peening. Mater Des. 2016;108:448–454.
  • Wei YH, Liu BS, Hou LF, et al. Characterization and properties of nanocrystalline surface layer in Mg alloy induced by surface mechanical attrition treatment. J Alloys Compd. 2008;452(2):336–342.
  • Zhang P, Lindemann J. Influence of shot peening on high cycle fatigue properties of the high-strength wrought magnesium alloy AZ80. Scr Mater. 2005;52(6):485.
  • Zinn W, Scholtes B. Mechanical surface treatments of lightweight materials—effects on fatigue strength and near-surface microstructures. J Mater Eng Perform. 1999;8(2):145–151.
  • Barry N, Hainsworth SV, Fitzpatrick ME. Effect of shot peening on the fatigue behaviour of cast magnesium A8. Mater Sci Eng A. 2009;507:50–57.
  • Wagner L. Mechanical surface treatments on titanium, aluminum and magnesium alloys. Mater Sci Eng A. 1999;263(2):210–216.
  • Hilpert M, Wagner L. Corrosion fatigue behavior of the high-strength magnesium alloy AZ 80. J Mater Eng Perform. 2000;9(4):402–407.
  • Khan SA, Bhuiyan MS, Miyashita Y, et al. Corrosion fatigue behavior of die-cast and shot-blasted AM60 magnesium alloy. Mater Sci Eng A. 2011;528(4-5):1961–1966.
  • Liu WC, Dong J, Zhang P, et al. Improvement of fatigue properties by shot peening for Mg–10Gd–3Y alloys under different conditions. Mater Sci Eng A. 2011;528(18):5935–5944.
  • Liu W, Dong J, Zhang P, et al. Effect of shot peening on surface characteristics and fatigue properties of T5-treated ZK60 alloy. Mater Trans. 2009;50(4):791–798.
  • Liu WC, Dong J, Zhang P, et al. Smooth and notched fatigue performance of aging treated and shot peened ZK60 magnesium alloy. J Mater Res. 2010;7:1375–1387.
  • Zhang P, Lindemann J, Leyens C. Influence of shot peening on notched fatigue strength of the high-strength wrought magnesium alloy AZ80. J Alloys Compd. 2010;497(1–2):380–385.
  • Zhang P, Lindemann J, Leyens C. Shot peening on the high-strength wrought magnesium alloy AZ80—effect of peening media. J Mater Process Technol. 2010;210(3):445–450.
  • Fouad Y, Mhaede M, Wagner L. Effects of mechanical surface treatments on fatigue performance of extruded ZK60 alloy. Fatigue Fract Eng Mater Struct. 2011;34(6):403–407.
  • Dong J, Liu W, Ding W, et al.. Surface characteristics and high cycle fatigue performance of shot peened magnesium alloy ZK60. J Metall. 2011;2011:9.
  • Liu W, Dong J, Zheng X, et al. Mater Sci Technol. 2014;27:201.
  • Song X, Liu WC, Belnoue JP, et al. An eigenstrain-based finite element model and the evolution of shot peening residual stresses during fatigue of GW103 magnesium alloy. Int J Fatigue. 2012;42:284–295.
  • Bhuiyan MS, Mutoh Y, McEvily AJ. The influence of mechanical surface treatments on fatigue behavior of extruded AZ61 magnesium alloy. Mater Sci Eng A. 2012;549:69–75.
  • Liu W, Wu G, Zhai C, et al. Grain refinement and fatigue strengthening mechanisms in as-extruded Mg–6Zn–0.5 Zr and Mg–10Gd–3Y–0.5 Zr magnesium alloys by shot peening. Int J Plast. 2013;49:16–35.
  • Mhaede M, Pastorek F, Hadzima B. Influence of shot peening on corrosion properties of biocompatible magnesium alloy AZ31 coated by dicalcium phosphate dihydrate (DCPD). Mater Sci Eng C. 2014;39:330–335.
  • Jamalian M, Field DP. Effects of shot peening parameters on gradient microstructure and mechanical properties of TRC AZ31. Mater Charact. 2019;148:9–16.
  • Bagherifard S. Nanoscale surface modification of biodegradable materials by severe shot peening.
  • Bagherifard S, Hickey DJ, Fintová S, et al. Effects of nanofeatures induced by severe shot peening (SSP) on mechanical, corrosion and cytocompatibility properties of magnesium alloy AZ31. Acta Biomater. 2018;66:93–108.
  • Patil T. Effect of shot peening on stress corrosion behavior of biodegradable magnesium WE43; 2018.
  • Liu C, Zheng H, Gu X, et al. Effect of severe shot peening on corrosion behavior of AZ31 and AZ91 magnesium alloys. J Alloys Compd. 2019;770:500–506.
  • Altinkurt G, Fèvre M, Geandier G, et al. Local strain redistribution in a coarse-grained nickel-based superalloy subjected to shot-peening,: fatigue or thermal exposure investigated using synchrotron X-ray Laue microdiffraction. J Mater Sci. 2018;53(11):8567–8589.
  • Karaoglanli AC, Doleker KM, Demirel B, et al. Effect of shot peening on the oxidation behavior of thermal barrier coatings. Appl Surf Sci. 2015;354:314–322.
  • Chaise T, Li J, Nélias D, et al. Modelling of multiple impacts for the prediction of distortions and residual stresses induced by ultrasonic shot peening (USP). J Mater Process Technol. 2012;212(10):2080–2090.
  • Chandrasekar R, Frishman AM, Larson BF, et al. Effects of microstructure on eddy current residual stress characterization of shot-peened Inconel 718. JOM. 2012;64(2):257–264.
  • Klotz T, Miao HY, Bianchetti C, et al. Analytical fatigue life prediction of shot peened Inconel 718. Int J Fatigue. 2018;113:204–221.
  • Lindemann J, Grossmann K, Raczek T, et al. Influence of shot peening and deep rolling on high temperature fatigue of the Ni-superalloy udimet 720 LI. Shot Peening. 2003: 454–460.
  • Fleury RMN, Salvati E, Nowell D, et al. The effect of surface damage and residual stresses on the fatigue life of nickel super alloys at high temperature. Int J Fatigue. 2019;119:34–42.
  • Salvati E, Lunt AJ, Heason CP, et al. An analysis of fatigue failure mechanisms in an additively manufactured and shot peened IN 718 nickel superalloy. Mater Des. 2020;191:108605.
  • Zaleski K, Skoczylas A, Brzozowska M. The effect of the conditions of shot peening the Inconel 718 nickel alloy on the geometrical structure of the surface. Adv Sci Tecnol Res J. 2017;11(2):205–211.
  • Zeng W, Yang J. Quantitative representation of mechanical behavior of the surface hardening layer in shot-peened nickel-based superalloy. Mater. 2020;6:1437.
  • Zhou Z, Shang J, Chen Y, et al. Synchronous shot peening applied on HVOF for improvement on wear resistance of Fe-based amorphous coating. Coat. 2020;10(2):187.
  • Zhang L, Zhang Y, Wu H, et al. Structure and corrosion behavior of cold-sprayed Cu/Ni composite coating post-treated by ultrasonic shot peening. SN Appl Sci. 2020;2(2):201.
  • Zhao B, Lv Y, Ding Y, et al. The grain refinement mechanisms of various phases in shot-peened nickel-aluminum bronze (NAB) alloy. Mater Charact. 2018;144:77–85.
  • Zhu S, Hu Y, Zhang X, et al. Experimental investigation on ultrasonic shot peening of WC-Co alloy. Mater Manuf Processes. 2020;35(14):1576–1583.
  • Kang X, Wang T, Platts J. Multiple impact modelling for shot peening and peen forming. Proc IMechE Part B: J Eng Manufact. 2010;224:689–697.
  • Miao HY, Larose S, Perron C, et al. On the potential applications of a 3D random finite element model for the simulation of shot peening. Adv Eng Softw. 2009;40:1023–1038.
  • Bhuvaraghan B, Srinivasan SM, Maffeo B, et al. Shot peening simulation using discrete and finite element methods. Adv Eng Softw. 2010;41:1266–1276.
  • Klemenz M, Schulze V, Rohr I, et al. Application of the FEM for the prediction of the surface layer characteristics after shot peening. J Mater Process Tech. 2009;209:4093–4102.
  • Shivpuri R, Cheng XM, Mao YN. Elasto-plastic pseudo-dynamic numerical model for the design of shot peening process parameters. Mater Design. 2009;30:3112–3120.
  • Kim T, Lee JH, Lee H, et al. An area-average approach to peening residual stress under multi-impacts using a three-dimensional symmetry-cell finite element model with plastic shots. Mater Design. 2010;31:50–59.
  • Miao HY, Larose S, Perron C, et al. Numerical simulation of the stress peen forming process and experimental validation. Adv Eng Software. 2011;42:963–975.
  • Gariepy A, Larose S, Perron C, et al. Shot peening and peen forming finite element modelling – towards a quantitative method. Int J Solids Struct. 2011;48:2859–2877.
  • Mylonas GI, Labeas G. Numerical modelling of shot peening process and corresponding products: residual stress,: surface roughness and cold work prediction. Surf Coat Tech. 2011;205:4480–4494.
  • Kim T, Lee H, Hyun HC, et al. A simple but effective FE model with plastic shot for evaluation of peening residual stress and its experimental validation. Mat Sci Eng A: Struct. 2011;528:5945–5954.
  • Kim T, Lee H, Jung S, et al. A 3D FE model with plastic shot for evaluation of equi-biaxial peening residual stress due to multi-impacts. Surf Coat Tech. 2012;206:3125–3136.
  • Kim T, Lee H, Hong CH, et al. Effects of Rayleigh damping, friction and rate-dependency on 3D residual stress simulation of angled shot peening. Mater Design. 2013;46:26–37.
  • Kim T, Lee H, Kim M, et al. A 3DFEmodel for evaluation of peening residual stress under angled multi-shot impacts. Surf Coat Technol. 2012;206:3981–3988.
  • Romero-Ángeles B, Urriolagoitia-Sosa G, Torres-San Miguel CR, et al. Numerical simulation of the shot peening process under previous loading conditions. J Phys Conf Series. 2015;582(1):012004, IOP Publishing.
  • Wang C, Wang C, Wang L, et al. A dislocation density–based comparative study of grain refinement,: residual stresses, and surface roughness induced by shot peening and surface mechanical attrition treatment. Int J Adv Manuf Technol. 2020;108(1):505–525.
  • Gariépy A, Miao HY, Lévesque M. Simulation of the shot peening process with variable shot diameters and impacting velocities. Adv Eng Software. 2017;114:121–133.
  • Karataş C, Sozen A, Dulek E. Modelling of residual stresses in the shot peened material C-1020 by artificial neural network. Expert Syst Appl. 2009;36(2):3514–3521.
  • Wang C, Lai Y, Wang L, et al. Dislocation-based study on the influences of shot peening on fatigue resistance. Surf Coat Technol. 2020;383:125247.
  • Astaraee AH, Bagherifard S, Bradanini A, et al. Application of shot peening to case-hardened steel gears: the effect of gradient material properties and component geometry. Surface and Coatings Technology. 2020;398:126084.
  • Zhang Y, Lai F, Qu S, et al. Effect of shot peening on residual stress distribution and tribological behaviors of 17Cr2Ni2MoVNb steel. Surf Coat Technol. 2020;386:125497.
  • Zhou F, Jiang W, Du Y, et al. A comprehensive numerical approach for analyzing the residual stresses in AISI 301LN stainless steel induced by shot peening. Mater. 2019;12:3338.
  • Gonzales MA, Barrios DB, De Lima NB, et al. Importance of considering a material microfailure criterion in the numerical modeling of the shot peening process applied to parabolic leaf springs. Lat Am J Solids Struct. 2010;7(1):21–40.
  • Schubnell J, Maciolek A, Lefevre P, et al. Numerical simulation of shot dynamics and the material surface condition of IN718 after ultrasonic shot peening; 2017.
  • Mo S, Zhu S, Jin G, et al. Lubrication characteristics of gear after shot peening base on 25-pellet model. Adv. Mech Eng. 2018;10(7):1687814018790655.
  • Dimitrov L, Michalopoulos D, Apostolopoulos CA, et al. Investigation of contact fatigue of high strength steel gears subjected to surface treatment. J Mater Eng Perform. 2009;18:939–946.
  • Li S, Anisetti A. A tribodynamic contact fatigue model for spur gear pairs. Int J Fatigue. 2017;98:81–91.
  • Lv Y, Lei L, Sun L. Effect of microshot peened treatment on the fatigue behavior of laser-melted W6Mo5Cr4V2 steel gear. Int J Fatigue. 2017;98:121–130.
  • Terrin A, Dengob C, Meneghetti G. Experimental analysis of contact fatigue damage in case hardened gears for off-highway axles. Eng Fail Anal. 2017;76:10–26.
  • Pu W, Wang J, Yang R, et al. Mixed elastohydrodynamic lubrication with three-dimensional machined roughness in spiral bevel and hypoid gears. J Tribol. 2015;137:041503.
  • Voorwald HJC, Silva MP, Costa MYP, et al. Improvement in the fatigue strength of chromium electroplated AISI 4340 steel by shot peening. Fatigue Fract Eng Mater Struct. 2009;32(2):97–104.
  • You C, Achintha M, Soady KA, et al. Low cycle fatigue life prediction in shot-peened components of different geometries—part I: residual stress relaxation. Fatigue Fract Eng Mater Struct. 2017;40:761–775.
  • Singh L, Khan RA, Aggarwal ML. Multi performance characteristic optimization of shot peening process for AISI 304 austenitic stainless steel using grey relational analysis with principal component analysis and Taguchi method. Am J Eng Res. 2013;2(10):160–172.
  • Gariépy A, Larose S, Perron C, et al. On the effect of the peening trajectory in shot peen forming Finite Elem. Anal Des. 2013;69:48–61.
  • Badreddine J, Rouhaud E, Micoulaut M, et al. Simulation and experimental approach for shot velocity evaluation in ultrasonic shot peening. Mec Ind. 2011;12(3):223–229.
  • Bae H, Ramulu M, Hossain A. Microscale modeling to study shot peening effects on aluminum alloy. ASME International Mechanical Engineering Congress and Exposition (Vol. 50640, p. V010T13A010). American Society of Mechanical Engineers; 2016.
  • Al-Hassani STS. Numerical simulation of multiple shot impact. Seventh Int’l. Conf. on Shot Peening; 1999.
  • Bagherifard S, Guagliano M. RETRACTED: influence of mesh parameters on FE simulation of severe shot peening (SSP) aimed at generating nanocrystallized surface layer.
  • Bagherifard S, Ghelichi R, Guagliano M. Numerical and experimental analysis of surface roughness generated by shot peening. Appl Surf Sci. 2012;258(18):6831–6840.
  • Elbella A, Rami V, Hogirala J. A sensitivity analysis of shot peening parameters. International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. 2006;4255:1003–1010.
  • Eltobgy MS, Ng E, Elbestawi MA. Three-dimensional elastoplastic finite element model for residual stresses in the shot peening process. Proc Inst Mech Eng Part B: J Eng Manuf. 2004;218(11):1471–1481.
  • Ghasemi A, Hassani-Gangaraj SM, Mahmoudi AH, et al. Shot peening coverage effect on residual stress profile by FE random impact analysis. Surf Eng. 2016;32(11):861–870.
  • Hassani-Gangaraj SM, Guagliano M, Farrahi GH. Finite element simulation of shot peening coverage with the special attention on surface nanocrystallization. Procedia Eng. 2011;10:2464–2471.
  • Hong T, Ooi JY, Shaw BA. A numerical study of the residual stress pattern from single shot impacting on a metallic component. Adv Eng Software. 2008;39(9):743–756.
  • Huang CK, Torng CC, Chang HM. Relationship between saturation curve and peening parameters for aerospace shot peening process. Mater Sci Forum. 2007;561:965–968. Trans Tech Publications Ltd.
  • Huang M, Potdar YK, Akkaram S. Analytical model to predict thermomechanical relaxation of shot peening induced residual stresses. J Eng Gas Turbines Power. 2010;132(9):092505.
  • Kubler RF, Berveiller S, Bouscaud D, et al. Shot peening of TRIP780 steel: experimental analysis and numerical simulation. J Mater Process Technol. 2019;270:182–194.
  • Lin Q, Liu H, Zhu C, et al. Effects of different shot peening parameters on residual stress, surface roughness and cell size. Surf Coat Technol. 2020;398:126054.
  • Liu J, Pang M. Fatigue life prediction of shot-peened steel. Int J Fatigue. 2012;43:134–141.
  • Maleki E, Unal O. Shot peening process effects on metallurgical and mechanical properties of 316 L steel via: experimental and neural network modeling. Met Mater Int. 2019;27:262–276.
  • Manchoul S, Seddik R, Ben Sghaeir R, et al. Finite element modeling of ultrasonic and conventional shot peening: a comparison of the effect of both processes on surface conditions. Proc Inst Mech Eng Part L: J Mater: Des Appl. 2019;233(5):930–941.
  • Manouchehrifar A, Rezvani K. Simulation and research on shotpeening process parameters with considering spring back effect. 2010 2nd International Conference on Mechanical and Electronics Engineering.
  • Frija M, Hassine T, Fathallah R, et al. Finite element modeling of shot peening process: prediction of the compressive residual stresses,: the plastic deformations and the surface integrity. Mater Sci Eng A. 2006;426:173–180.
  • Meguid SA, Maricic LA. Finite element modeling of shot peening residual stress relaxation in turbine disk assemblies. J Eng Mater Technol. 2015;137(3):031003.
  • Newby M, James MN, Hattingh DG. Finite element modelling of residual stresses in shot-peened steam turbine blades. Fatigue Fract Eng Mater Struct. 2014;37(7):707–716.
  • Nguyen VB, Poh HJ, Zhang YW. Predicting shot peening coverage using multiphase computational fluid dynamics simulations. Powder Technol. 2014;256:100–112.
  • Bagherifard S, Ghelichi R, Guagliano M. Numerical model of severe shot peening aimed to estimate surface nanocrystallization of Al material. 11th International Conference on Shot Peening. South Bend (USA); 2011. p. 243–248.
  • Olmi G, Comandini M, Freddi A. Fatigue on shot-peened gears: experimentation,: simulation and sensitivity analyses. Strain. 2010;46(4):382–395.
  • Pham TQ, Khun NW, Butler DL. New approach to estimate coverage parameter in 3D FEM shot peening simulation. Surf Eng. 2017;33(9):687–695.
  • Shahid L, Janabi-Sharifi F. A neural network-based method for coverage measurement of shot-peened panels. Neural Comput Appl. 2019;31(9):4829–4836.
  • Zaid AI, Medraj MA. Investigation of the effect of shot peening parameters on peening intensity. 5 th International Symposium on Advanced Materials; 1997. p. 744–749.
  • Sidhom N, Braham C, Lieurade HP. Fatigue life evaluation of shot peened al-alloys 5083 H11 T-welded joints by experimental and numerical approaches. Weld World. 2007;51(1-2):50–57.
  • Starman B, Hallberg H, Wallin M, et al. Modelling of the mechanical response in 304 austenitic steel during laser shock peening and conventional shot peening. Procedia Manuf. 2020;47:450–457.
  • Unal O. Optimization of shot peening parameters by response surface methodology. Surf Coat Technol. 2016;305:99–109.
  • Wang Y, Shi J, Wang X. Molecular dynamics simulation of shot peening process and residual stress generation: effects of particle impact speed and impinging angle. ASME International Mechanical Engineering Congress and Exposition (Vol. 46438, p. V02AT02A056). American Society of Mechanical Engineers; 2014.
  • Wang C, Wang L, Wang X, et al. Numerical study of grain refinement induced by severe shot peening. Int J Mech Sci. 2018;146:280–294.
  • Wu XQ, Wang X, Wei YP, et al. Parametric study on single shot peening by dimensional analysis method incorporated with finite element method. Acta Mech Sin. 2012;28(3):825–837.
  • Wu J, Liu H, Wei P, et al. Effect of shot peening coverage on residual stress and surface roughness of 18CrNiMo7-6 steel. Int J Mech Sci. 2020;183:105785.
  • Xiang Y, Liu Y. Mechanism modelling of shot peening effect on fatigue life prediction. Fatigue Fract Eng Mater Struct. 2010;33(2):116–125.
  • Xu J, Koch WJ. Finite-element analysis of the influence of edge geometry on shot peening process. J Aerosp Eng. 2009;22(2):153–159.
  • You C, Achintha M, Soady KA, et al. Low cycle fatigue life prediction in shot-peened components of different geometries–part II: life prediction. Fatigue Fract Eng Mater Struct. 2017;40(5):749–760.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.