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Experimental-numerical study of laser-shock-peening-induced retardation of fatigue crack propagation in Ti-17 titanium alloy

Rujian Sun, Sören Keller, Ying Zhu, Wei Guo, Nikolai Kashaev, Benjamin Klusemann

2020International Journal of Fatigue60 citationsDOIOpen Access PDF

Abstract

Residual stresses induced by laser shock peening in Ti-17 titanium specimens were experimentally and numerically investigated to identify the mechanisms and generation conditions of the retardation of fatigue crack propagation (FCP). The retardation was experimentally observed with fatigue life prolonged by 150%. A multi-step simulation strategy for fatigue life prediction is applied, which successfully predicts the experimentally observed FCP behavior. The fractographic observations and numerical simulation indicate that crack closure, as opposed to other microstructural influences, is the dominant effect on retardation. The studies of multi-FCP aspects show that significant retardation occurs in specimens at high values of residual stresses, small peening gap distances, and lower externally applied loads.

Topics & Concepts

Materials sciencePeeningResidual stressShock (circulatory)Laser peeningTitanium alloyTitaniumCrack closureFracture mechanicsFatigue testingStructural engineeringComposite materialAlloyMetallurgyEngineeringInternal medicineMedicineSurface Treatment and Residual StressHigh-Velocity Impact and Material BehaviorFatigue and fracture mechanics
Experimental-numerical study of laser-shock-peening-induced retardation of fatigue crack propagation in Ti-17 titanium alloy | Litcius