Title of article
A quantitative description on fracture toughness of steels in hydrogen gas
Author/Authors
Wang، نويسنده , , Yanfei and Gong، نويسنده , , Jianming and Jiang، نويسنده , , Wenchun، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2013
Pages
6
From page
12503
To page
12508
Abstract
Fracture toughness or critical stress intensity factor of many steels can be reduced by hydrogen gas. In this paper, a simple quantitative model to predict the fracture toughness of steels in gaseous hydrogen is proposed. This model is based on the assumption that fracture of a cracked body occurs when the maximum principal stress ahead of the crack tip reaches the critical cohesive stress for crack initiation. The critical stress is inversely proportional to the accumulated hydrogen concentration. The notion is that the crack will initiate at the elastic-plastic boundary ahead of the crack tip when hydrogen concentration reaches a maximum value after a long-term hydrogen diffusion assisted by the hydrostatic stress. The model describes the dependence of fracture toughness on hydrogen pressure, temperature and yield strength of steels. It can be used to quantitatively predict fracture toughness of steels in hydrogen gas, particularly in high pressure. Some experimental data reported in literature were used to validate the model, and a good agreement was obtained.
Keywords
fracture toughness , hydrogen embrittlement , Critical stress intensity factor , Hydrogen gas
Journal title
International Journal of Hydrogen Energy
Serial Year
2013
Journal title
International Journal of Hydrogen Energy
Record number
1864888
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