Effects of Normalizing Temperature on the Precipitation of Fine Particles and Austenite Grain Growth during Carburization of Al- and Nb-Microalloyed Case-Hardening Steel

This paper deals with the precipitation behaviors of AlN and Nb(C, N) particles during normalizing of hot-forged Al- and Nb-microalloyed case-hardening steel, and investigates the effects of the number density and volume fraction of these particles on the grain growth behavior of austenite (gamma) during the subsequent high-temperature carburization. When the sample was cooled from the hot forging temperature at 16 degrees C/min, AlN did not precipitate at all and was completely supersaturated in the matrix, although fine Nb(C, N) particles precipitated during cooling. When reheated to the normalizing temperature, AlN particles started precipitation at approximately 620-640 degrees C on the grain boundaries of the bainitic ferrite matrix and the interfaces between the cementite particles and the matrix, and the AlN particles contained Cr and Mn, and had an NaCl structure and Bain orientation relationship with the matrix. The AlN structure changed from NaCl type into wurtzite type at approximately 800 degrees C. AlN particles grew during reheating to the normalizing temperature and holding at the temperature. Both the number density and volume fraction of the AlN particles were dramatically increased by reducing the normalizing temperature from 1 070 to 900 degrees C. The distribution of these particles strongly affected the. grain structure formed during carburization. As the normalizing temperature was reduced from 1 070 to 950 and 900 degrees C, the. grain structure became finer. Some abnormally large grains were formed near the carburized surface, when normalized at 1 070 degrees C. However, no abnormal grain was found when normalized below 950 degrees C.