PSI - Issue 41

Peter Zobec et al. / Procedia Structural Integrity 41 (2022) 208–214 Peter Zobec / Structural Integrity Procedia 00 (2022) 000–000

214

7

process. Engineering Failure Analysis , 16(1):503–511, 2009. [14] Giovanni Pio Pucillo, Alessandro Carrabs, Stefano Cuomo, Adam Elliott, and Michele Meo. Cold expansion of rail-end-bolt holes: Finite element predictions and experimental validation by dic and strain gauges. International Journal of Fatigue , 149:106275, 2021. [15] B Zuccarello and G Di Franco. Numerical-experimental method for the analysis of residual stresses in cold-expanded holes. Experimental Mechanics , 53(4):673–686, 2013. [16] WV Vaidya, P Staron, and M Horstmann. Fatigue crack propagation into the residual stress field along and perpendicular to laser beam butt-weld in aluminium alloy aa6056. Fatigue & Fracture of Engineering Materials & Structures , 35(5):399–411, 2012. [17] KW Jones and ML Dunn. Fatigue crack growth through a residual stress field introduced by plastic beam bending. Fatigue & Fracture of Engineering Materials & Structures , 31(10):863–875, 2008. [18] ME Fitzpatrick and L Edwards. Fatigue crack / residual stress field interactions and their implications for damage-tolerant design. Journal of materials engineering and performance , 7(2):190–198, 1998. [19] CDM Liljedahl, O Zanellato, L Edwards, and ME Fitzpatrick. Evolution of residual stresses with fatigue crack growth in a variable polarity plasma arc–welded aluminum alloy compact tension specimen. Metallurgical and Materials Transactions A , 39(10):2370–2377, 2008. [20] Peter Zobec and Jernej Klemenc. Application of a nonlinear kinematic-isotropic material model for the prediction of residual stress relaxation under a cyclic load. International Journal of Fatigue , 150:106290, 2021. [21] Peter Zobec and Jernej Klemenc. Yet another approach to fatigue crack growth simulation. Metals , 12(4):539, 2022.