Akademik Veri Yönetim Sistemi
MATERIALS RESEARCH EXPRESS, cilt.2053, sa.1591, ss.1-17, 2024 (SCI-Expanded)
ABSTRACT Die steels used in metal forming processes require resilience in harsh conditions. Therefore, it becomes crucial to convert retained austenite into martensite and uniformly distribute fine carbide phases in these steels. Cobalt is known for its ability to enhance carbide formation in tool steels. In the present work, DIN 1.2888, a hot work tool steel characterized by high cobalt content, was subjected to the conventional HT and CT processes at -100, -140, and -180 °C for 6 h, then double-tempered. The properties of samples were investigated by XRD, SEM-EDS, and Microhardness analyses. The wear mechanism was investigated by a pin-on-disc wear testing device and the impact toughness of the samples was examined both at room temperature and the working temperature of the dies (350 °C). It was observed that decrease of the cryogenic treatment temperature resulted with a slight change on the hardness values of the samples from 507 HV to 529 HV, while impact toughness increased from 12.35 J to 23.44 J at 350 °C. Also, the wear rates of the samples exhibited a ~50% decrease. It can be deduced that cryogenic treatment had positive effect on the properties of steel, depending on the retained austenite decrement and homogenous fine carbide density increment with the decreasing cryogenic treatment temperature. Key Words: Cryogenic treatment, DIN 1.2888 steel, Carbide distribution, Mechanical properties, Wear