Low cycle fatigue behaviour of a Cr–Mo–V matrix-type high-speed steel used for cold forging

► The LCF behaviour of a Cr–Mo–V matrix-type HSS was investigated. ► The strain–stress and strain–life relationships of the steel were established. ► The material exhibited a 3-stage cyclic softening. ► The behaviour of this material is approximate to Masing-type. ► Fractographic and metallographic...

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Bibliographic Details
Published in:Materials in engineering 2013-02, Vol.44, p.612-621
Main Authors: Zhang, Y., Hu, C.L., Zhao, Z., Li, A.P., Xu, X.L., Shi, W.B.
Format: Article
Language:English
Subjects:
Amplitudes
Chromium
Cyclic stress response
Fatigue (materials)
Fatigue behaviour
Fractography
High speed tool steels
Low cycle fatigue
Materials selection
Matrix-type high-speed steel
Softening
Strain
Strain-controlled fatigue test
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Summary:► The LCF behaviour of a Cr–Mo–V matrix-type HSS was investigated. ► The strain–stress and strain–life relationships of the steel were established. ► The material exhibited a 3-stage cyclic softening. ► The behaviour of this material is approximate to Masing-type. ► Fractographic and metallographic analyses were conducted. The low cycle fatigue (LCF) behaviour of a Cr–Mo–V matrix-type high-speed steel (matrix-type HSS), which was used as cold forging tool material, was investigated. Fatigue tests were conducted under strain-controlled cyclic loading conditions with different axial strain amplitude levels at room temperature. The tests indicated that hysteresis loops formed when the total strain amplitude was 1.5%, 1.0% and 0.75%. At total strain amplitudes that were less than 0.7%, there was no cyclic plastic deformation or hysteresis loop observed. The material fatigue behaviour was analysed specifically at the above three strain levels to investigate the cyclic plastic deformation of the material because the low cycle fatigue behaviour was of principal interest in this study. At all selected total strain amplitudes, the cyclic stress responses showed cyclic softening, and reached a “quasi-stabilised” softening state before the material finally ruptured from fatigue. The cyclic strain–stress relationship and the strain–life relationship were obtained through the test results, and related material parameters were calculated. Fractographic and metallographic analyses were also conducted in this study. The metallographic structure of the steel before and after heat treatment was examined. Two types of carbide phases were found in the steel. The fatigue damage process through the crack initiation and propagation was explained by observing the features of the fractures.
ISSN:0261-3069
DOI:10.1016/j.matdes.2012.08.052