Abstract
The flow stress behavior of SCM435 steel was studied by using a MMS-200 thermal simulation machine, under the conditions with deformation temperatures of 1023–1323 K and strain rate of 0.01–10 s−1. The experimental results indicated that the critical strain would get smaller with the increment in temperature and the decrement in strain rate, leaving the dynamic recrystallization easier to occur. The peak stress constitutive equation of SCM435 steel under high temperatures was established by the form of hyperbolic sine, and the activation energy of deformation under high temperature was obtained by regression equation. The critical strain ɛ c for dynamic recrystallization was accurately derived from the θ-σ curve containing strain hardening rate θ and flow stress σ. Then the correlation between peak stress, peak strain, critical stress, critical strain and the parameter Z was further obtained. The Avrami kinetic equation of dynamic recrystallization for SCM435 steel was developed from stress-strain curve, and the Avrami exponent m was abstracted. Observations also indicated that the Avrami constants would decrease with increments in temperature, but increase with increments in strain rate. The Avrami constant took small influence from the deforming temperature, but significant influence from strain rate, and the correlation between Avrami constant and the strain rate was obtained by regression equation.
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Funded by the National Outstanding Young Scientist Foundation of China ( No. 50925415), and the National Natural Science Foundation of China ( No.51004030)
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Xu, D., Zhu, M., Tang, Z. et al. Determination of the dynamic recrystallization kinetics model for SCM435 steel. J. Wuhan Univ. Technol.-Mat. Sci. Edit. 28, 819–824 (2013). https://doi.org/10.1007/s11595-013-0775-5
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DOI: https://doi.org/10.1007/s11595-013-0775-5