Influence of precipitation behavior on mechanical properties and hydrogen induced cracking during tempering of hot-rolled API steel for tubing

Abstract

Precipitation behavior and its effect on hydrogen embrittlement during tempering process of hot-rolled API steel designed with 0.4wt% Cr and 0.25wt% Mo were investigated. The base steel was normalized and then tempered at 650°C for up to 60min. The precipitation behavior of the examined steel was explored using transmission electron microscopy (TEM) analysis, and it was found that the precipitation sequence during tempering at 650°C were as follows: MX+M3C→MX→MX+M7C3+M23C6. The change of particle fraction was measured by electrolytic extraction technique. At the early stage of tempering, the particle fraction greatly decreased due to dissolution of M3C particle, and increased after 10min by the precipitation of M7C3 and M23C6 particles. The particle fraction showed a peak at 30min tempering and decreased again due to the dissolution of M7C3 particle. Vickers hardness tests of base steel and tempered samples were carried out, and then the hardness was changed by accompanying with the change of particle fraction. The sensitivity of hydrogen embrittlement was evaluated through hydrogen induced cracking (HIC) tests, and the results clearly proved that HIC resistance of tempered samples was better than that of base steel due to the formation of tempered martensite, and then the HIC resistance changed depending on the precipitation behavior during tempering, i.e., the precipitation of coarse M23C6 and M7C3 particles deteriorated the HIC resistance.