Abstract
The present study investigates conventional and cryogenically turned specimens of metastable austenitic steel AISI 347 and stable austenitic steel AISI 904L in the VHCF regime. The cryogenic turning process includes cooling by CO2 snow and generates a surface layer on the specimens of metastable austenitic steel, which is characterized by a phase transformation from paramagnetic fcc - austenite to ferromagnetic bcc - martensite and grain refinement. The stable austenitic steel retains its purely austenitic structure after cryogenic turning, but also shows grain refinement in the surface layer. The specimens with different surface morphology were cyclically loaded at ambient temperature using an ultrasonic fatigue testing system developed and built at the authors’ institute. The testing machine operates at frequencies of approx. 20 kHz to achieve high numbers of load cycles within a reasonable time. To avoid self heating of the specimen, the tests were performed in pulse-pause mode. All specimens were tested with a load ratio of R = -1. During cyclic loading, the metastable austenitic steel partially transformed from paramagnetic fcc - austenite to ferromagnetic bcc - martensite, while no phase transformation could be detected in the stable austenitic steel.
Highlights
Investigations in the very high cycle fatigue (VHCF) regime on steels are necessary to characterize fatigue behavior above 107 load cycles [1]
To investigate the influence of surface layers on the VHCF behavior of austenitic steels, this study focused on VHCF tests of stable and metastable austenitic steels with an ultrasonic testing system up to N = 1x109
Influence of cryogenic turning on surface morphology
Summary
Investigations in the very high cycle fatigue (VHCF) regime on steels are necessary to characterize fatigue behavior above 107 load cycles [1]. Persistent slip bands (PSB) can be formed at the surface, if the PSB threshold is exceeded, and can lead to a crack initiation at the surface [3]. This effect shows that the influence of the surface plays a significant role in fatigue behavior even in the VHCF regime. Metastable austenitic steels show a true fatigue limit in the VHCF regime, if bcc martensite is developed during fatigue testing [15]. Some investigations focus on predeformed metastable austenites containing bcc - martensite before testing. Predeformed specimens with bcc - martensite content of 27 vol % show a true fatigue limit as well, whereas predeformed specimens with bcc - martensite content of 54 vol % show a second decrease in the Wöhler-curve in the VHCF regime [16]
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