An extensive study of hydrogen-induced cracking susceptibility in an {API} {X60} sour service pipeline steel

By Mohtadi-Bonab, M. A.; Eskandari, M.; Rahman, K. M. M.; Ouellet, R.; Szpunar, J. A.
Published in International Journal of Hydrogen Energy NULL 2016

Abstract

Abstract {API} {X60} sour service (X60SS) pipeline steel was subjected to electrochemical hydrogen-charging for different durations in order to evaluate its hydrogen-induced cracking (HIC) susceptibility. {SEM} observations of the hydrogen-charged specimens documented that no {HIC} cracks appeared at the cross section of steel, which is strong evidence of a high resistance to HIC. However, hydrogen-discharging results show that a considerable amount of hydrogen can enter the {X60SS} steel through its hydrogen traps. Moreover, a hydrogen-permeation test proved that the trapping behavior was almost identical at the center and surface layers of the cross section in this steel. However, the density of hydrogen traps at the center of the cross section was slightly higher than at the surface. Tensile and fatigue experiments were carried out in the air and in a hydrogen-charging environment using a newly constructed experimental setup. Tensile results show that the ductility dropped by 83% in the hydrogen-charging environment. Electron backscatter diffraction (EBSD) technique was used to analyze the {HIC} cracks in the {X60SS} steel. {HIC} cracks appeared after charging under tensile/fatigue tests. Therefore, high HIC-resistant steel showed susceptibility to {HIC} when charging and tensile stresses were applied simultaneously. The effects of different factors on {HIC} crack propagation such as micro-texture, type of grain boundaries, Kernel Average Misorientation (KAM), special coincidence site lattice (CSL) boundaries and recrystallization fraction, were discussed.

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