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Tensile mechanical properties, deformation mechanisms, fatigue behaviour and fatigue life of 316H austenitic stainless steel: Effects of grain size

Lei Zhao, Xueyan Qi, Lianyong Xu, Yongdian Han, Hongyang Jing, Kai Song

2020Fatigue & Fracture of Engineering Materials & Structures16 citationsDOI

Abstract

Abstract To explore the effect of grain size on the tensile behaviour, symmetrical strain control fatigue behaviour and ratcheting fatigue behaviour of the new austenitic steel 316H, a series of tensile tests, symmetrical strain control fatigue tests and ratcheting fatigue tests were conducted at 25°C within an average grain size range from 14 to 122 μm. The average dislocation free path, forest dislocation density and mobile dislocation density of 316H steel with different grain sizes under tension were obtained. Moreover, the decrease of grain size led to saturation of mobile dislocations at lower strains. The decrease of grain size led to the increase of the cyclic stress and affected softening and secondary hardening process. In addition, under the same stress control conditions, the reduction in grain size caused a reduction in ratcheting strain under the same cycle. The grain refinement of 316H steel contributed to the improvement of ratcheting fatigue life.

Topics & Concepts

Materials scienceGrain sizeUltimate tensile strengthStrain hardening exponentMetallurgyDislocationComposite materialHardening (computing)SofteningAustenitic stainless steelLayer (electronics)CorrosionHigh Temperature Alloys and CreepMicrostructure and Mechanical Properties of SteelsMetallurgy and Material Forming
Tensile mechanical properties, deformation mechanisms, fatigue behaviour and fatigue life of 316H austenitic stainless steel: Effects of grain size | Litcius