Hydrogen-Induced Cracking in CGHAZ of Welded X80 Steel under Tension Load

X80 steel is extensively used in hydrogen environments and is susceptible to hydrogen embrittlement (HE). This paper studied the hydrogen-induced cracking (HIC) behavior in the coarse-grained heat-affected zone (CGHAZ) of X80 steel welds, through applying in situ hydrogen-charging tensile experiments, hydrogen permeation experiments, and various surface analysis techniques. It is shown that a few hydrogen atoms can significantly decrease a material's elongation and reduction of area. When the heat input (HI) was 29.2 kJ/cm, the material had minor sensitivity to hydrogen embrittlement. The tensile fractures were ductile without hydrogen. However, the fracture surface exhibited brittle fracture with hydrogen. With increased HI, the HE fracture showed a transition of intergranular fracture & RARR;intergranular and transgranular mixed fracture & RARR;transgranular fracture. In the presence of hydrogen, the grain boundaries of elongated strips were prone to the formation of intergranular cracks under a tension load, and the hydrogen embrittlement resistance of the bulk lath bainite (LB) was weak. The hydrogen embrittlement susceptibility of pure granular bainite (GB) was lower. Fine LB and GB composite structures could remarkably inhibit intergranular cracks, giving the steel a superior resistance to hydrogen embrittlement.

Automated summary

This paper studied the hydrogen-induced cracking behavior in the coarse-grained heat-affected zone of X80 steel welds. It is shown that hydrogen significantly decreases a material's elongation and reduction of area. The hydrogen embrittlement susceptibility of the steel depends on the heat input, with higher heat inputs leading to increased susceptibility. The presence of hydrogen causes a transition in fracture mode from ductile to brittle, and the resistance to hydrogen embrittlement is influenced by the microstructures present in the steel.