[1]
F.R. Hutchings and P.M. Unterweiser, Ed., Failure Analysis: The British Engine Technical Reports, American Society for Metals, (1981).
Google Scholar
[2]
MJ. O' Brien, RG. Metcalfe High strength engineering fasteners: design for fatigue resistance. J. Failure Analysis and Prevention 9 (2009), 171-181.
DOI: 10.1007/s11668-009-9213-6
Google Scholar
[3]
I. Altenberger. Deep rolling – the past, the present and the future. In the proc. ff the ICSP 9: shot peening. (2005), 144.
Google Scholar
[4]
B. Bhuvaraghan, O. Prakash, Sivakumar M.S. , Y. Potdar, B. Maffeo, P. Doma. Overview of the effects of surface enhancement processes on plastic strain, work hardening and residual stresses. In the proc. of ICSP-6, San Francisco, California, USA. (1996).
Google Scholar
[5]
D. Wierzchowski, A. Ostertag, L. Wagner. Fatigue Performance of the Mechanically Surface Treated Steels 42CrMo4 and 54SiCr6: Shot Peening vs. Roller-Burnishing. In the proc. of ICSP-8, (2002), 468-434.
DOI: 10.1002/3527606580.ch60
Google Scholar
[6]
I. Altenberger. Alternative Mechanical Surface Treatments: Microstructures, Residual Stresses & Fatigue Behavior. In the proc. of ICSP-8, (2002), 421-434.
DOI: 10.1002/3527606580.ch54
Google Scholar
[7]
I. Fernández-Pariente, S. Bagherifard, M. Guagliano, R. Ghelichi, Fatigue behavior of nitrided and shot peened steel with artificial small surface defects, Eng. Fract. Mech. 103 (2013) 2-9.
DOI: 10.1016/j.engfracmech.2012.09.014
Google Scholar
[8]
G. Olmi, A. Freddi, A new method for modelling the support effect under rotating bending fatigue: application to Ti-6Al-4V alloy, with and without shot peening, Fatigue Fract. Eng. Mater. Struct. 36 (2013) 981-993.
DOI: 10.1111/ffe.12051
Google Scholar
[9]
D. Croccolo, M. De Agostinis, S. Fini, G. Olmi, F. Robusto, S. Ciric-Kostic, A. Vranic, N. Bogojevic, Fatigue Response of As-Built DMLS Maraging Steel and Effects of Aging, Machining, and Peening Treatments, Metals 8 (7), article ID: 505 (2018) 1-21.
DOI: 10.3390/met8070505
Google Scholar
[10]
G. Çevik, Z. Tuncali, ET. Duran. A Study on the Diesel Engine Crankshaft Fatigue Performance Optimization. SAE International (2009), 145-157.
DOI: 10.4271/2009-01-0261
Google Scholar
[11]
IM. Quraishi M. Harne. Fatigue Strength and residual stress analysis of deep rolled crankshafts. Int. J. Eng. Tech 4(6), (2012), 466-473.
Google Scholar
[12]
W Li. SY. Zhang, S. Kabra, A. Tremsin, B. Abbey, H. Kirkwood, D. Terret, S. Ndoye, E. McDevitt, Characterisation of Residual Stress due to Fillet Rolling on Bolts Made of a Nickel Base Superalloy, In the proc of the 9th European Conference on Residual Stress, (2014).
DOI: 10.4028/www.scientific.net/amr.996.670
Google Scholar
[13]
Kloss KH, Kaiser B, Jung U. 1995. Einflusse der Verfahrensparameter des Festwalzens auf die Schwingfestigkeit bautelahnlicher proben. Konsutruction 47, pp.97-101.
Google Scholar
[14]
S. Mitrovic, D. Adamovic, F. Zivic, D. Dzunic, M. Pantic, Friction and wear behavior of shot peened surfaces of 36CrNiMo4 and 36NiCrMo16 alloyed steels under dry and lubricated contact conditions, Appl. Surf. Sci. 290 (2014) 223-232.
DOI: 10.1016/j.apsusc.2013.11.050
Google Scholar
[15]
M. Matsui, H. Kakishima, Improvement of tribological performance of steel by solid lubricant shot-peening in dry rolling/sliding contact wear tests, Wear 260 (2006) 669-673.
DOI: 10.1016/j.wear.2005.03.030
Google Scholar
[16]
S. Kedziora. Optimal Design of Cap Screw Thread Runout for Transversal and Axial loads. Journal of applied Mechanical Engineering 6: 250.
DOI: 10.4172/2168-9873.1000250
Google Scholar
[17]
International organization for standardization ISO 12107:2012, Metallic Materials – Fatigue Testing – Statistical Planning and Analysis of Data, Geneva, Switzerland, (2012).
Google Scholar
[18]
W.J. Dixon, F. Jr. Massey, Introduction to Statistical Analysis. New York, United States, McGraw‐Hill, (1983).
Google Scholar