Differential scanning calorimetry study of diffusional and martensitic phase transformations in some 9 wt-%Cr low carbon ferritic steels

Abstract

The results of a comprehensive characterisation study of different phase transformations that take place upon heating and cooling in some low carbon, 9?wt?%Cr steels with varying concentrations of microalloying additions are presented in this paper. The steels investigated include: standard 9Cr?1Mo grade, V and Nb added modified 9Cr variety, controlled silicon added versions of plain 9Cr variety, (Ni+Mn) content controlled modified 9Cr welding consumables and one composition of W, Ta added reduced activation steel. The various on?heating diffusional phase changes up to the melting range and subsequent rapid cooling induced martensitic transformations are investigated in a controlled manner using differential scanning calorimetry under different heating and cooling rates, in the range 1?100?K?min?1. In addition to the accurate determination of Ac1, Ac3, M23C6, MX carbide dissolution and ??ferrite formation temperatures upon heating, the melting range and the associated fusion enthalpy have also been established for these steels. The effect of prolonged thermal aging at temperatures of 823?873?K on austenite formation characteristics has also been investigated for standard and modified 9Cr?1Mo steels. The critical cooling rate for the formation of martensite on cooling from single phase austenite region is estimated to be about 4?5?K?min?1 for all 9Cr steels investigated in this study. The effect of holding at 1273?K in the austenite region on martensite start temperature Ms, has also been evaluated as a part of this study. The experimental results are discussed in the light of the prevailing understanding of the physical metallurgy of high chromium low carbon steels.