Abstract
The effect of a strain rate varying from ∼10−3 to ∼10−5s−1 at a strain amplitude ranging from ±0.2% to ±0.6% on the low cycle fatigue (LCF) behavior and the microstructure of a 10%Cr-2%W-0.7%Mo-3%Co-NbV steel with 0.008wt.% B and 0.003wt.% N additions was studied at a temperature of 650°C. Decreasing the strain rate and increasing the strain amplitude was demonstrated to reduce the resistance of the 10%Cr steel to cyclic softening due to facilitating the transformation of the tempered martensite lath structure (TMLS) to a subgrain structure. The strong effect of the strain rate on the LCF behavior was attributed to the dynamic strain aging phenomenon that was represented by the stress serrations on the hysteresis loops, the positive temperature dependence of the cyclic strain hardening exponent n′ and the cyclic strength coefficient K′ in the Morrow equation. The fatigue lifetime curves at all tested strain rates and strain amplitudes could be described using the Basquin-Manson-Coffin relationship.
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