Microstructural evolution in 0.1%C5%Mn steel after intercritical annealing depending on temperature and cooling rate
K. Steineder, R. Schneider, D. Krizan, C. Béal, C. Sommitsch - Microstructural evolution in 0.1%C5%Mn steel after intercritical annealing depending on temperature and cooling rate - Proceedings of European Conference on Heat Treatment and 21st IFHTSE Congress, München, Germany, 2014, pp. 301-308
TRansformation Induced Plasticity (TRIP)-assisted Medium-Mn steels, with Mn-contents in the range of 4-10 wt.-%, have recently gained a lot of interest due to their promising mechanical properties. This steel group contains a considerable amount of retained austenite, which is stabilized by C and mainly Mn during intercritical annealing. The present work investigated the influence of annealing temperature and cooling rate on the microstructural evolution by means of dilatometry. Two thermodynamical models for the prediction of optimal annealing temperature and maximum retained austenite content have also been thoroughly evaluated. For further characterization, microstructural observations, EBSD, micro-hardness testing and X-ray diffraction were carried out. The investigations manifested a pronounced influence of both annealing temperature and cooling rate, on the phase fractions of ferrite, austenite and martensite, which must be taken into account by design of batch annealing route for Medium-Mn TRIP steels in order to obtain superior combination of strength and ductility.