Estimation of Flow Stress by the Kocks-Mecking Model at Strain Rate of 10³/s for an Ultra Low Carbon Steel

Abstract

Tensile flow stress of an ultra low carbon steel was investigated at temperatures between 77K and 293K with strain rates from 2×10^-2/s to 2×10³/s. Stress-strain curves were described by using the Kocks-Mecking model in which several parameters were determined from the experimental data obtained by conventional tensile tests with lower strain rates less than 2×10⁰/s. It is found that the flow stress at 2×10³/s estimated by the Kocks-Mecking model agrees well with the stress measured by Hopkinson-bar method. The decrease in work-hardening rate at 2×10³/s was discussed from the viewpoints of temperature rise and microstructural evolution during high speed tensile deformation, leading to a conclusion that the former was a main reason.