nach oben

Lasers in Manufacturing and Materials Processing

Erschienen in:

23.10.2019

Laser Shock Peening and its Applications: A Review

verfasst von: Sundar R, Ganesh P, Ram Kishor Gupta, Ragvendra G, B. K. Pant, Vivekanand Kain, Ranganathan K, Rakesh Kaul, K. S. Bindra

Erschienen in: Lasers in Manufacturing and Materials Processing | Ausgabe 4/2019

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

In this paper Laser Shock Peening (LSP), as a surface treatment technique for metals and alloys is reviewed. A brief introduction covering LSP process, LSP on various materials and some innovative applications of LSP have been discussed. Critical laser parameters for LSP such as laser energy, pulse width, wavelength, overlap rate, role of sacrificial coating and transparent overlay are presented towards parameter optimization perspective. A small section has been devoted to detail the development of a pulsed Nd:YAG laser that was built in house, exclusively for the LSP applications. Role of LSP in improving the material properties such as fatigue, Stress Corrosion Cracking (SCC), Inter Granular Corrosion (IGC) besides, rejuvenation of fatigue life of pre fatigued specimens and hybrid technique to rejuvenate the SCC damaged components are discussed. Further, results on oblique laser peening along with its successful application to the interior of cylindrical geometry specimens for improving the SCC resistance are also discussed.

Vorheriger Artikel Multi-Objective Optimization of Residual Stress and Cost in Laser Shock Peening Process Using Finite Element Analysis and PSO Algorithm

Nächster Artikel Track-Scale Simulations of Selective Laser Melting to Investigate Development and Mitigation of Thermal Stresses

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Askaryan, G.A., Moroz, E.M.: Pressure of evaporation of matter in a radiation beam. J Exp Theor Phys+. (U.S.S.R.). 43, 2319–2320 (1962)

Skeen, C.H., York, C.M.: Laser induced “blow off” phenomena. Appl Phys Lett. 12, 369 (1968)CrossRef

Gregg, D.W., Thomas, S.J.: Momentum transfer produced by focused laser giant pulses. J Appl Phys. 37(2787), (1966)

Fairand, B.P., Clauer, A.H., Jung, R.G., Wilcox, B.A.: Quantitative assessment of laser induced stress waves generated at confined surfaces. Appl Phys Lett. 25(8), 431–433 (1974)CrossRef

Clauer, A.H., Fairand, B.P., Wilcox, B.A.: Pulsed laser induced deformation in an Fe-3 Wt Pct Si Alloy. Metall. Trans. A. 8A, 119–125 (1977)CrossRef

Allan, H., Clauer, B., Fairand, P., Bena, A.: Wilcox.: laser shcok hardening of weld zones in Aluminium alloys. Metall. Trans. A. 8A, 1871–1876 (1977)

Allan H. Clauer.: A Historical Perspective on Laser Shock Peening, MFN Metal Finishing News, 10, (2009), http://www.mfn.li/archive/issue_view.php?id=648, Accessed 04 Jun 2019

Mannava, S., and Ferrigno, S.J..: Laser shock peening for gas turbine engine vane repair. US patent 5675892A, General Electric Company (1997). https://patents.google.com/patent/US5675892A/en. Accessed 04 Jun 2019

Ganesh, P., Sundar, R., Kumar, H., Kaul, R., Ranganathan, K., Hedaoo, P., Tiwari, P., Kukreja, L.M., Oak, S.M., Dasari, S., Ragvendra, D.: Studies of laser peening on spring steel for automotive applications. Opt Laser Eng. 50, 678–686 (2012)CrossRef

10.

Ganesh, P., Sundar, R., Kumar, H., Kaul, R., Ranganathan, K., Hedaoo, P., Ragvendra, G., Anand Kumar, S., Tiwari, P., Nagpure, D.C., Bindra, K.S., Kukreja, L.M., Oak, S.M.: Studies on fatigue life enhancement of pre-fatigued spring steel specimens using laser shock peening. Mater Des. 54, 734–741 (2014)CrossRef

11.

Pant, B.K., Sundar, R., Kumar, H., Kaul, R., Pavan, A.H.V., Ranganathan, K., Bindra, K.S., Oak, S.M., Kukreja, L.M., Prakash, R., Kamaraj, M., et al.: Mater. Sci. Eng., A. 587, 352–358 (2013)CrossRef

12.

Gupta, R.K., Sundar, R., Sunil Kumar, B., Ganesh, P., Kaul, R., Ranganathan, K., Bindra, K.S., Kain, V., Oak, S.M., Kukreja, L.M.: A hybrid laser surface treatment for refurbishment of stress corrosion cracking damaged 304L stainless steel. J. Mater. Eng. Perform. 24, 2569–2576 (2015)CrossRef

13.

Sundar, R., Ganesh, P., Sunil Kumar, B., Gupta, R.K., Nagpure, D.C., Kaul, R., Ranganathan, K., Bindra, K.S., Kain, V., Oak, S.M., Singh, B.: Mitigation of stress corrosion cracking susceptibility of machined 304L stainless steel through laser peening. J. mater. Eng. Perform. 25, 3710–3724 (2016)CrossRef

14.

Gupta, R.K., Sunil Kumar, B., Sundar, R., Ram Sankar, P., Ganesh, P., Kaul, R., Kain, V., Ranganathan, K., Bindra, K.S., Singh, B.: Enhancement of intergranular corrosion resistance of type 304 stainless steel through laser shock peening. Corros Eng Sci Techn. 52(3), 220–225 (2017)CrossRef

15.

Abdullahi, K., Gujba 1, Medraj, M.: Laser peening process and its impact on materials properties in comparison with shot peening and ultrasonic impact peening. Materials. 7, 7925–7974 (2014)CrossRef

16.

Peyre, P., Berthe, L., Vignal, V., Popa, I., Baudin, T.: Analysis of laser shock waves and resulting surface deformations in an Al–cu–li aluminum alloy. J Phys D Appl Phys. 45(33), 335304 (2012)CrossRef

17.

Peyre, P., Fabbro, R., Merrien, P., Lieurade, H.P., et al.: Mater. Sci. Eng., A. A210, 102–113 (1996)CrossRef

18.

Amarchinta, H.K., Grandhi, R.V., Langer, K., Stargel, D.S.: Material model validation for laser shock peening process simulation. Modelling Simul Mater Sci Eng. 17(1), 015010 (2009)CrossRef

19.

Peyre, P., Berthe, L., Scherpereel, X., Fabbro, R., Bartnicki, E.: Experimental study of laser-driven shock waves in stainless steels. J Appl Phys. 84(11), 5985–5992 (1998)CrossRef

20.

Hong, X., Wang, S., Guo, D., Wu, H., Wang, J., Dai, Y., Xia, X., Xie, Y.: Confining medium and absorptive overlay: Their effects on a laser-induced shock wave. Opt Laser Eng. 29, 447–455 (1998)CrossRef

21.

Massse, J.-E., Barreau, G.: Laser generation of stress waves in metal. Surf. Coat. Techno. 70, 231–234 (1995)CrossRef

22.

Devaux, D., Fabbro, R., Tollier, L., Bartnicki, E.: Generation of shcok waves by laser-induced plasma in confined geometry. JAppl Phy. 74(4), 2268–2273 (1993)CrossRef

23.

Berthe, L., Fabbro, R., Peyre, P., Tollier, L., Bartnicki, E.: Shock waves from a water-confined laser-generated plasma. JAppl Phy. 82(6), 2826–2832 (1997)CrossRef

24.

Fabbro, R., Fournier, J., Ballard, P., Devaux, D., Virmont, J.: Physical study of laser-produced plasma in confined geometry. J Appl Phy. 68, 75–784 (1990)CrossRef

25.

Wu, B., Shin, Y.C.: A self-closed thermal model for laser shock peening under the water confinement regime configuration and comparisons to experiments. J Appl Phys. 97(113517), 113517 (2005)CrossRef

26.

Wu, B., Shin, Y.C.: A one-dimensional hydrodynamic model for pressures induced near the coating-water interface during laser shock peening. J Appl Phys. 101(023510), (2007)

27.

Wu, B., Shin, Y.C.: Two dimensional hydrodynamic simulation of high pressures induced by high power nanosecond laser matter interactions under water. J. Appl. Phys. 101, 103514 (2007)CrossRef

28.

Yunfeng Cao., Yung C. Shin.: Shock wave propagation and spallation study in laser shock peening. J. Eng. Mater. Technol. 132, 041005–1 to 041005–8 (2010),

29.

Wei, X.L., Ling, X.: Numerical modeling of residual stress induced by laser shock processsing. Appl Surf Sci. 301, 557–563 (2014)CrossRef

30.

Ayed, M., Frija, M., Fathallah, R.: Prediction of residual stress profile and optimization of surface conditions induced by laser shock peening process using artificial neural networks. Int J Adv Manuf Technol. 100(9-12), 2455–2471 (2019). https://doi.org/10.1007/s00170-018-2883-z CrossRef

31.

Sobieslaw Stanislaw Gace.: Molecular dynamics simulation of shock waves in laser-material interaction. Ph.D thesis, Iowa State University (2009). https://lib.dr.iastate.edu/cgi/viewcontent.cgi?article=1712&context=etd Accessed on 04 Jun 2019

32.

Zhencheng Ren, Chang Ye, Yalin Dong.: Molecular dynamic simulation of surface amorphization of NiTi under dynamic shock peening. Proceedings of the ASME 2015 International Manufacturing Science and Engineering Conference. MSEC2015. June 8–12, (2015), Charlotte, North Carolina, USA https://doi.org/10.1115/MSEC2015-9320

33.

Peyre, P., Fabbro, R., Berthe, L., Dubouchet, C.: Laser shock processing of materials, physical processes involved and examples of applications. J Laser Appl. 8(3), 135–141 (1996)CrossRef

34.

Fournier, J., Ballard, P., Merrien, P., Barralis, J., Castex, L., Fabbro, R.: Mechanical effects induced by shock waves generated by high energy laser pulses, J. Phy III, France. 1(9), 1467–1480 (1991)CrossRef

35.

Peyre, P., Fabbro, R.: Laser shock processing: a review of the physics and applications. Opt Quant Electron. 27, 1213–1229 (1995)

36.

Jiang, X.P., Man, C.-S., Shepard, M.J., Zhai, T.: Effects of shot-peening and re-shot-peening on four-pointbend fatigue behavior of Ti–6Al–4V. Mat Sci and Engg A. 468–470, 137–143 (2007)CrossRef

37.

Paul, S.P., Cammett, J.T.: The influence of surface enhancement by low plasticity burnishing on the corrosion fatigue performance of AA7075-T6. Int J Fatigue. 26(9), 975–982 (2004)CrossRef

38.

Delgado, P., Cuesta, I.I., Alegre, J.M., Díaz, A.: State of the art of deep rolling. Precis Eng. 46, 1–10 (2016)CrossRef

39.

Statnikov, E.S., Korolkov, O.V., Vityazev, V.N.: Physics and mechanism of ultrasonic impact. Ultrasonics. 44, e533–e538 (2006)CrossRef

40.

Srivastava, M., Tripathi, R., Hloch, S., Chattopadhyaya, S., Dixit, A.R.: Potential of using water jet peening as a surface treatment process for welded joints. Procedia Eng. 149, 472–480 (2016)CrossRef

41.

Soyama, H., Sait, K., Saka, M.: Improvement of fatigue strength of aluminium alloy by cavitation shotless peening. J. Eng. Mater. Technol. 124, 135 (2002)CrossRef

42.

Linda Suzanne Clitheroe.: The physical and microstructural properties of peened austenitic stainless steel. Ph.D Thesis. University of Manchester, (2010), https://www.research.manchester.ac.uk/portal/files/54509593/FULL_TEXT.PDF Accessed on 04 Jun 2019

43.

Ding K &Ye L.: Laser shock peening performance and process simulation, WoodHead publishing in materials, Woodhead Publishing Limited and CRC Press LLC, (2006)

44.

Charles S. Montross, Tao Wei., Lin Ye., Graham Clark., Yiu-wing Mai.: Laser shock processing and its effects on microstructure and properties of metal alloys: a review, Int J Fatigue 24, 1021–1036 (2002)

45.

Prevey, P.S.: The effect of cold work on the thermal stability of residual compression in surface enhanced IN718, 20th ASM heat treating society conference proceedings 9–12, Oct 2000, St.Louis, MO http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.513.2788&rep=rep1&type=pdf Accessed on 16 Jun 2019

46.

Sano, Y., Akita, K., Masaki, K., Ochi, Y., Altenberger, I., Scholtes, B.: Laser peening without coating as a surface enhancement technology. J Laser Micro Nanoen. 1, 161–166 (2006)CrossRef

47.

Sano, Y., Mukai, N., Okazak, K., Obata, M.: Residual stress improvement in metal surface by underwater laser irradiation. Nucl. Instr. Meth. Phys. Res. B. 121, 432–436 (1997)CrossRef

48.

Zhu, J., Jiao, X., Zhou, C., Gao, H.: Applications of underwater laser peening in nuclear power plant maintenance. Energy Procedia. 16, 153–158 (2012)CrossRef

49.

Kalainathan, S., Prabhakaran, S.: Recent development and future perspectives of low energy laser shock peening: review. Opt Laser Technol. 81, 137–144 (2016)CrossRef

50.

Yoda, M., Mukai, N., Sano, Y., Ogawa, K., Kimura, M., Sato, K., Uehara, T., Sudo, A., and Suezono, N.: Fiber-delivered laser peening system to improve mechanical properties of metal surface. Transactions on Engineering Sciences. ISSN 1743–3533, 33, 233–242 WIT Press, (2001)

51.

Karthik, D., Kalainathan, S., Swaroop, S.: Surface modification of 17-4 PH stainless steel by laser peening without protective coating process. Surf Coat Technol. 278, 138–145 (2015)CrossRef

52.

Liao, Y., Ye, C., Cheng, G.J., et al.: Opt Laser Technol. 78, 15–24 (2016)CrossRef

53.

Liao, Y., Ye, C., Kim, B.-J., Suslov, S., Stach, E.A., Cheng, G.J.: Nucleation of highly dense nanoscale precipitates based on warm laser shock peening. J. Appl. Phys. 108, 063518–1–063518-8 (2010)

54.

Hackel, L., Rankin, J.R., Rubenchik, A., King, W.E., Matthews, M.: Laser peening: A tool for additive manufacturing post-processing. Addit. Manuf. 24, 67–75 (2018)CrossRef

55.

Kalentics, N., Boillat, E., Peyre, P., Gorny, C., Kenel, C., Leinenbach, C., Jhabvala, J., Logé, R.E.: 3D laser shock peening – A new method for 3D control of residual stresses in selective laser melting. Mater. Des. 130, 350–356 (2017)CrossRef

56.

Sihai Luo., Liucheng Zhou., Xuede Wang., Xin Cao., Xiangfan Nie and Weifeng He.: Surface nanocrystallization and amorphization of dual-phase TC11 titanium alloys under laser induced ultrahigh strain-rate plastic deformation. Materials. 11; 563 (2018)

57.

Samuel Adu-Gyamfi., Ren, X.D., Enoch Asuako Larson., Yunpeng Ren., Zhaopong Tong.: The effects of laser shock peening scanning patterns on residual stress distribution and fatigue life of AA2024 aluminium alloy. Opt. Laser. Technol. 108, 177–185 (2018)

58.

Correa, C., Ruiz de Lara, L., Díaz, M., Gil-Santos, A., Porro, J.A., Ocaña, J.L.: Effect of advancing direction on fatigue life of 316L stainless steel specimens treated by double-sided laser shock peening. Int. J. Fatigue. 79, 1–9, (2015)

59.

Qiao Hongchao., Sun Boyu., Zhao Jibin., Lu Ying., Cao Zhihe.: Numerical modeling of residual stress field for linear polarized laser oblique shock peening. Optik (2019), https://doi.org/10.1016/j.ijleo.2019.04.083

60.

Fabbro, R., Peyre, P., Berthe, L., Scherpereel, X.: Physics and applications of laser-shock processing. J Laser Appl. 10(6), 265–279 (1998)CrossRef

61.

Berthe, L., Fabbro, R., Peyre, P., Bartnicki, E.: Wavelength dependent of laser shock-wave generation in the water-confinement regime. J. Appl. Phys. 85, 7552 (1999)CrossRef

62.

Liu, X., Du, D., Mourou, G.: Laser ablation and micromachining with ultrashort laser pulses. IEEE J Quantum Electron. 33(10), 1706–1716 (1997)CrossRef

63.

Noack, J., Vogel, A., et al.: IEEE J. Quantum Electron. 35, 1156–1167 (1999)CrossRef

64.

Benxin, W., Tao, S., Lei, S.: Numerical modeling of laser shock peening with femtosecond laser pulses and comparisons to experiments, app. Surf Sci. 256, 4376–4382 (2010)CrossRef

65.

Dongkyun Lee and Elijah Kannatey-Asibu, Jr.: Experimental investigation of laser shock peening using femtosecond laser pulses, J. Laser Appl. 23, 022004–1 to 022004–9(2011)

66.

Petan, L., Cana, J.L.O., Grum, J.: Influence of laser shock peening pulse density and spot size on the surface integrity of X2NiCoMo18–9-5 maraging steel. Surf. Coat. Technol. 307, 262–270 (2016)CrossRef

67.

Hu, Y., Yao, Z.: Overlapping rate effect on laser shock processing of 1045 steel by small spots with Nd:YAG pulsed laser. Surf Coat Techol. 202(1517–1525), 1517–1525 (2008)CrossRef

68.

Hu, Y., Yao, Z.: Retardation of crack initiation and growth in austenitic stainless steels by laser peening without protective coating. Mater Sci Eng. A417(334–340), (2006)

69.

Walter Koechner.: Solid State Laser Engineering” Springer Series in Optical Sciences, Sixth revised and updated edition, USA (2006)

70.

Carthy, N.M., Lavigne, P.: Large-size Gaussian mode in unstable resonators using Gaussian mirrors. Opt. Lett. 10, 553–555 (1985)CrossRef

71.

Silvestri, S.D., Laporta, P., Magni, V.S., O.: Unstable laser resonators with super-Gaussian mirrors. Opt Lett. 13(3), 201–203 (1988)CrossRef

72.

Sundar, R., Kumar, H., Kaul, R., Ranganathan, K., Tiwari, P., Kukreja, L.M., Oak, S.M.: Studies on laser peening using different sacrificial coatings. Surf Eng. 28(8), 564–568 (2012)CrossRef

73.

74.

Pineault, J.A, Belassel, M., Brauss, M.E.: X-ray diffraction residual stress measurement in failure analysis. in: William T Becker., Roch J Shipley (Eds.), Failure analysis and prevention, ASM International. 11, 484–497. https://doi.org/10.31399/asm.hb.v11.a0003528

75.

Noyan, I.C and Cohen, J.B.: in Iischner, B., amd Grant, N.J.: Residual Stress-measurement by diffraction and interpretation. Springer series on materials research and engineering New York (1987),

76.

Rossini, N.S., Dassisti, M., Benyounis, K.Y., Olabi, A.G.: Methods of measuring residual stresses in components. Mater Des. 35, 572–588 (2012)CrossRef

77.

Chu, J.P., Rigsbee, J.M., Banas, G., Elsayed-Ali, H.E.: Laser-shock processing effects on surface microstructure and mechanical properties of low carbon steel. Mater Sci Eng A. 260, 260–268 (1999)CrossRef

78.

Paul Prevey., Jayaraman, N., Ravi Ravindranath.: Introduction of Residual Stresses to Enhance Fatigue Performance in the Initial Design. GT2004–53971, 231–239; doi:https://doi.org/10.1115/GT2004-53971

79.

Ferreira, J.A.M., Boorrego, L.F.P., Costa, J.D.M.: Effects of surface treatments on the fatigue of notched bend specimens. Fatigue Fract. Eng. Mater. Struct. 19, 111 (1996)CrossRef

80.

Hammersley, G., Hackel, L.A., Harris, F.: Surface prestressing to improve fatigue strength of components by laser shot peening. Opt Laser Eng. 34, 327–337 (2000)CrossRef

81.

Kirk D.: External characteristics of shot peened surfaces, The Shot Peener; 24–32, (2008) https://www.shotpeener.com/library/pdf/2008037.pdf Accessed on 04 Jun 2019

82.

Ludian, T., Wagner, L.: Coverage effects in shot peening of Al2024-T4.In: Proceedings 9th international conference on shot peening (ICSP9),296–301, Sept.6–9 (2005)Paris, France. https://www.shotpeener.com/library/pdf/2005100.pdf Accessed on 04 Jun 2019

83.

Kailash Chaudhary.: Importance of controlling parameters in shot peening process. JETIR ISSN-2349–5162, 4, 220–223, (2017)

84.

Dieter, G.E.: Mechanical metallurgy. McGraw Hill Book Co Singapore. ISBN-0071004068, (1988)

85.

Lu, J.Z., Luo, K.Y., Zhang, Y.K., Cui, C.Y., Sun, G.F., Zhou, J.Z., Zhang, L., You, J., Chen, K.M., Zhong, J.W.: Grain refinement of LY2 aluminum alloy induced by ultra-high plastic strain during multiple laser shock processing impacts. Acta Mater. 58(11), 3984–3994 (2010)CrossRef

86.

Luo, K.Y., Lu, J.Z., Zhang, Y.K., Zhou, J.Z., Zhang, L.F., Dai, F.Z., Zhang, L., Zhong, J.W., Cui, C.Y.: Effects of laser shock processing on mechanical properties and micro-structure of ANSI 304 austenitic stainless steel. Mater Sci Eng A. 528(13-14), 4783–4788 (2011)CrossRef

87.

Clauer, A.H.: Laser shock peening for fatigue resistance. In: Gregory, J.K., Rack, H.J., Eylon, D. (eds.) Surface Performance of Titanium, pp. 217–230. TMS, Warrendale, PA (1996)

88.

Hill, M.R., Dewald, A.T., Dema, A.G., Hackel, L.A., Chen, H.-L., Brent Dane, C., Specht, R.C., Harris, F.B.: Laser peening technology. Adv Mater Processes. 161, 65–67 (2003)

89.

Stephens, R.I.: Effect of shot and laser peening on SAE1010 steel tube with a transverse center weld subjected to constant and variable amplitude loading, www.shotpeener.com/library/pdf/2009031.pdf, Accessed on 04 Jun 2019

90.

Farhangi, H., Moghadam, A.A.F.: Fractographic investigation of the failure of second stage gas turbine blades, Proceedings of the 8th International Fracture Conference, 577–584, Istanbul, Turkey, Nov.7–9, (2007) http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.505.3140&rep=rep1&type=pdf, Accessed on 04 Jun 2019

91.

Fathallah, R., Laamouri, A., Sidhom, H., Braham, C.: High cycle fatigue behavior prediction of shot-peened parts. Int J Fatigue. 26(10), 1053–1067 (2004)CrossRef

92.

Jie Dong., Wencai Liu., Wenjiang Ding., and Jianxin Zou.: Surface characteristics and high cycle fatigue performance of shot peened magnesium alloy ZK60, JOM. 2011, 682191 (2011)

93.

Laser peening technology used on power generation components, http://www.curtisswright.com/news/press-releases/news-release-details/2007/Curtiss-Wright-Laser-Peening-Technology-Utilized-by-Siemens-Power-Generation/default.aspx, Accessed on 04 Jun 2019

94.

Prévey, P., Hornbach, D., Mason, D.: Thermal residual stress relaxation and distortion in surface enhanced gas turbine components, in: D.L.Milam, etal. (Eds.), Proceedings of the 17th Heat Treating Society Conference and 1st International Induction Heat Treating Symposium, ASM International, Materials Park, OH,3–12 (1998) https://pdfs.semanticscholar.org/72be/98c1a74dbf0cf0c97acf7a6e02d7dc4f8b7e.pdf Accessed on 16 Jun 2019

95.

Mochizuki, M.: Control of welding residual stress for ensuring integrity against fatigue and stress-corrosion cracking. Nucl Eng Des. 237(2), 107–123 (2007)CrossRef

96.

Khatak, H.S and Raj, B., Ed.: Corrosion of Austenitic Stainless Steels: Mechanism, Mitigation and Monitoring, Woodhead Publishing, Cambridge, 74–139, (2002)

97.

Fe’ron, D and Olive, J.-M, Ed.: Corrosion issues in light water reactors—stress corrosion cracking. 1st ed., Woodhead Publishing, Cambridge, (2007)

98.

Stress corrosion cracking in light water reactors: good practices and lessons learned, IAEA Nuclear Energy Series”, NP-T-3.13, 2011, International Atomic Energy Agency, Vienna, https://www-pub.iaea.org/MTCD/Publications/PDF/P1522_web.pdf, Accessed on 05 Jun 2019

99.

Nakahara, M.: Preventing stress corrosion cracking of austenitic stainless steels in chemical plants. NiDi technical series 10066, Nickel Development Institute, https://www.nickelinstitute.org/media/1766/preventingstress_corrosioncrackingofausteniticstainlesssteelsinchemicalplants_10066_.pdf, Accessed on 05 Jun 2019

100.

Esmacher, J.: Stress corrosion cracking in boilers and cooling water systems, stress corrosion cracking—theory and practice, V.S. Raja and T. Shoji, Ed., Woodhead Publishing, Philadelphia, 537–607 (2011) https://doi.org/10.1533/9780857093769.4.539

101.

Jerome Isselin., Akira Kai., Kazuhiko Sakaguchi., and Tetsuo Shoji.: Assessment of the effects of cold work on crack initiation in a light water environment using the small-punch test, Metall. Mater. Trans. A. 39(A), p 1099–1108 (2008)

102.

Andresen, P.L., Morra, M.M.: IGSCC of non-sensitized stainless steels in high temperature water. J Nucl Mater. 383, 97–111 (2008)CrossRef

103.

Litao Chang, M., Grace Burke, M., Scenini, F.: Understanding the effect of surface finish on stress corrosion crack initiation in warm-forged stainless steel 304L in high-temperature water. Scripta Mater. 164, 1–5 (2019)CrossRef

104.

Sueishi, Y., Kohyama, A., Kinoshita, H., Narui, M., Fukumoto, K.: Microstructure and nano-hardness analyses of stress corrosion cracking utilizing 316L core shroud of BWR power reactors. Fusion Eng Des. 81(8-14), 1099–1103 (2006)CrossRef

105.

Lyon, K.N., Marrow, T.J., Lyon, S.G.: Influence of milling on the development of stress corrosion cracks in austenitic stainless steel. J Mater Process Technol. 218, 32–37 (2015)CrossRef

106.

Ghosh, S., Rana, V.P.S., Kain, V., Mittal, V., Baveja, S.K.: Role of residual stresses induced by industrial fabrication on stress corrosion cracking susceptibility of austenitic stainless steel. Mater Des. 32(7), 3823–3831 (2011)CrossRef

107.

Trethewey, K.R.: Some observations on the current status in the understanding of stress-corrosion cracking of stainless steels. Mater Des. 29(2), 501–507 (2008)CrossRef

108.

Suzuki, S., Takamori, K., Kumagai, K., Sakashita, A., Yamashita, N., Shitara, C., and Okamura, Y.: Stress corrosion cracking in low carbon stainless steel components in BWRs, E-J. Adv. Maint, 1, 1–29 (2009) http://www.jsm.or.jp/ejam/Vol.1.No.1/AP/EJAMVol.1(2009)1-29_S_SUZUKI_et_al.pdf Accessed on 16 Jun 2019

109.

Ghosh, S., Kain, V.: Microstructural changes in AISI, 304 stainless steel due to surface machining: effect on its susceptibility to chloride stress corrosion cracking. J Nucl Mater. 402, 62–67 (2010)CrossRef

110.

Ghosh, S., Kain, V.: Effect of surface machining and cold working on the ambient temperature chloride stress corrosion cracking susceptibility of AISI, 304L stainless steel. Mater Sci Eng A. 527(3), 679–683 (2010)CrossRef

111.

Lyon, K.N., Marrow, T.J., Lyon, S.B.: Influence of milling on the development of stress corrosion cracks in austenitic stainless steel. J Mater Process Technol. 218, 32–37 (2015)CrossRef

112.

Acharyya, S.G., Khandelwal, A., Kain, V., Samajdar, I.: Surface working of 304L stainless steel: impact on microstructure, electrochemical behaviour and SCC resistance. Mater Charact. 72, 68–76 (2012)CrossRef

113.

Lu, J.Z., Luo, K.Y., Yang, D.K., Cheng, X.N., Hu, J.L., Dai, F.Z., Qi, H., Zhang, L., Zhong, J.S., Wang, Q.W and Zhang, Y.K.: Effects of laser peening on stress corrosion cracking (SCC) of ANSI, 304 austenitic stainless steel, Corros Sci 60, p 145–152 (2012)

114.

ASTM: G36 94(2018), Standard Practice for Evaluating Stress-Corrosion-Cracking Resistance of Metals and Alloys in a Boiling Magnesium Chloride Solution. ASTM International, West Conshohocken, PA (2018). https://doi.org/10.1520/G0036-94R18 CrossRef

115.

Dayal, R.K, Parvathavarthini, N., Raj, B.: Influence of metallurgical variables on sensitization kinetics in austenitic stainless steel. Int Mater Rev 50, 129–155 (2005)

116.

Ganesh, P.: Vinod kumar a, Thinaharan C, Nanda Gopala Krishna, George R P, Parvathavarthini N, rai S K, Rakesh Kaul, Kamachi Mudali U, Kukreja L M.: enhancement of intergranular corrosion resistance of type 304 stainless steel through a novel surface e thermos-mechanical treatment, surf. Coat. Techol. 232, 920–927 (2013)

117.

Akgun, O.V., Inal, O.T.: Desensitization of sensitized 304 stainless steel by laser surface melting. J Mater Sci. 29, 2147–2153 (1992)CrossRef

118.

Kain, V., Chandra, K., Adhe, K.N., De, P.K.: Effect of cold work on low temperature sensitization behavior of austenitic stainless steel. J Nucl Mater. 334(2-3), 115–132 (2004)CrossRef

119.

Lu, J.Z., Luo, K.Y., Zhang, Y.K., Sun, G.F., Gu, Y.Y., Zhou, J.Z., Ren, X.D., Zhang, X.C., Zhang, L.F., Chen, K.M., Cui, C.Y., Jiang, Y.F., Feng, A.X., Zhang, L.: Grain refinement mechanism of multiple laser shock processing impacts on ANSI 304 stainless steel. Acta Mater. 58(16), 5354–5362 (2010)CrossRef

120.

Zhou, L., He, W., Luo, S., Long, C., Wang, C., Nie, X., He, G., Shen, X.J., Li, Y.: Laser shock peening induced surface nanocrystallization and martensite transformation in austenitic stainless steel. J. Alloys Compd. 655, 66–70 (2016)CrossRef

121.

Jang, D.Y., Watkins, T.R., Kozaczek, K.J., Hubbard, C.R., Cavin, O.B.: Surface residual stresses in machined austenitic stainless steel. Wear. 194(1-2), 168–173 (1996)CrossRef

122.

Su, C.Y., Chou, C.P., Wu, B.C., Lih, W.C.: Plasma transferred arc welding of the nickel-base superalloy IN-738LC. J Mater Eng Perform. 6(5), 619–627 (1997)CrossRef

123.

Bhaduri, A.K, Gil, T.P.S., Albert, S.K, Shanmugam, K., and Iyer, D.R.: Repair welding of cracked steam turbine blades using austenitic and martensitic stainless steel consumables. Nucl Eng Des 206, 249–259 (2001)

124.

Henderson, M.B., Arrell, D., Larsson, R., Heobel, M., Merchant, G.: Practices for industrial gas turbine applications. Sci Technol Weld Join. 9(1), 13–21 (2004)CrossRef

125.

Kumar, A., Boy, J., Zatorski, R., Stephenson, J.D.: Thermal Spray and Weld Repair Alloy in the repair of Cavitation Damage in Turbines and Pumps:A Technical Note. J. Therm. Spray Technol. 14, 177–182 (2005)CrossRef

126.

Steen, W.M., Mazumdar, J.: Laser Material Processing, 4th edn. Springer, London, UK (2010)CrossRef

127.

Liu, Q., Janardhana, M., Hinton, B., Brandt, M., Sharp, K.: Laser cladding as potential repair technology for damaged aircraft components. Int J Struct Integr. 2(3), 314–321 (2011)CrossRef

128.

Van Rooyen, C., Berger, H., and Theron, M.: Laser cladding crack repair of austenitic stainless steel, Proc. 5th Int. Conf. WLT-Conf. on Lasers in Manufacturing, Munich, (2009)

129.

Sexton, S., Lavin, S., Byrne, G., Kennedy, A.: Laser cladding of aerospace materials. J Mater Process Technol. 122(1), 63–68 (2002)CrossRef

130.

Capello, E., Colombo, D., and Previtali, B.: Repairing of sintered tools using laser cladding by wire, J Mater Process Technol 164–165, 990–1000 (2005), 164-165

131.

Stewart, J., Wells, D.B., Scott, P.M., Bransden, A.S.: The prevention of IGSCC in sensitized stainless steel by laser surface melting. Corrosion. 46(8), 618–620 (1990)CrossRef

132.

Anthony, T.R., Cline, H.E.: Surface normalization of sensitized stainless steel by laser surface melting. J Appl Phys. 49(3), 1248–1255 (1978)CrossRef

133.

Mudali, U.K., Dayal, R.K.: Improving intergranular corrosion resistance of sensitized type 316 stainless steel by laser surface melting. J. Mater. Eng. Perform. 341–3465 (1992)

134.

Kwok, C.T., Lo, K.H., Chan, W.K., Cheng, F.T., Man, H.C.: Effect of laser surface melting on intergranular corrosion behavior of aged austenitic and duplex stainless steels. Corros Sci. 53(4), 1581–1591 (2011)CrossRef

135.

Bao, G., Shinozaki, K., Iguro, S., Inkyo, M., Yamamoto, M., Mahara, Y., Watanabe, H.: Stress corrosion cracking sealing in overlaying of Inconel 182 of by laser surface melting. J Mater Process Technol. 173(3), 330–336 (2006)CrossRef

136.

Zhang, Y.K., Ren, X.D., Zhou, J.Z., Lu, J.Z., Zhou, L.C.: Investigation of stress intensity factor changing on the hole crack subject to laser shock processing. Mater Des. 30(7), 2769–2773 (2009)CrossRef

137.

Tumbull, A., Mingard, K., Lord, J.D., Roebuck, B., Tice, D.R., Mottershead, K.J., Fairweather, N.D., Bradbury, A.K.: Sensitivity of stress corrosion cracking of stainless steel to surface machining and grinding procedure. Corros Sci. 53(10), 3398–3415 (2011)CrossRef

138.

Suryanarayana, C., and Norton, M.G.: X-ray Diffraction—A Practical Approach, Plenum Press, New York, 63–98(1998)

139.

ASM Handbook, Vol 6, Welding Brazing and Soldering, ASM international, 1993 http://www.asminternational.org: ISBN 0–87170–377-7(V.1)

140.

Stamm, H., Holzwarth, U., Boerman, D.J., Dos Santos, M.F., Olchini, A., Zausch, R.: Effect of laser surface treatment on high cycle fatigue of AISI, 316L stainless steel. Fatigue Fract Eng Mater Struct. 19(8), 985–995 (1996)CrossRef

Titel: Laser Shock Peening and its Applications: A Review
verfasst von: Sundar R
Ganesh P
Ram Kishor Gupta
Ragvendra G
B. K. Pant
Vivekanand Kain
Ranganathan K
Rakesh Kaul
K. S. Bindra
Publikationsdatum: 23.10.2019
Verlag: Springer US
Erschienen in: Lasers in Manufacturing and Materials Processing / Ausgabe 4/2019
Print ISSN: 2196-7229
Elektronische ISSN: 2196-7237
DOI: https://doi.org/10.1007/s40516-019-00098-8

Premium Partner

Marktübersichten

Die im Laufe eines Jahres in der „adhäsion“ veröffentlichten Marktübersichten helfen Anwendern verschiedenster Branchen, sich einen gezielten Überblick über Lieferantenangebote zu verschaffen.

Zur Marktübersicht

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Weitere Artikel der Ausgabe 4/2019

Multi-Objective Optimization of Residual Stress and Cost in Laser Shock Peening Process Using Finite Element Analysis and PSO Algorithm

Evaluation of Distortion and Residual Stresses in Dissimilar Metal Laser Welds

Modeling and Optimization of Process Parameters for Laser Powder Bed Fusion of AlSi10Mg Alloy

Track-Scale Simulations of Selective Laser Melting to Investigate Development and Mitigation of Thermal Stresses

The Influence of Shielding Gases on Solidification Structures and Grain Size of AISI 304 Stainless Steel Fiber Laser Welds

Systematic Comparison of Thermal Annealing and Laser Treatment of TiO2 Thin Films Prepared by Sol-Gel Processing

Premium Partner

Marktübersichten