Effect of mechanical activation on jell boronizing treatment of the AISI 4140

Abstract

The article presents the effect of mechanical activation on the growth kinetics of boride layer of boronized AISI 4140 steel. The samples were boronized by ferroboron+(SiO2–Na2O) powders for 873–1173K temperature and 2, 4, 6 and 8h times, respectively. The morphology and types of borides formed on the surface of AISI 4140 steel substrate were analyzed. Layer growth kinetics were analyzed by measuring the extent of penetration of FeB and Fe2B sublayers as function of treatment time and temperature in the range of 873–1173K. High diffusivity was obtained by creating a large number of defects through mechanical activation in the form of nanometer sized crystalline particles through the repeated fracturing and cold-welding of the powder particles, and a depth of 100μm was found in the specimen borided by the 2h MA powders, for 4h and 1073K, where 2000–2350 HV were measured. Consequently, the application conditions of boronizing were improved by usage of mechanical activation. The preferred Fe2B boride without FeB could be formed in the boride layer under 973K boronizing temperature by mechanically activated by ferroboron+sodium silicate powder mixture due to the decrease of the activation energy.