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Investigation of the effect of electrolytic hydrogen charging of X70 steel: I. The effect of microstructure on hydrogen-induced cold cracking and blistering

journal contribution
posted on 2024-11-16, 08:49 authored by Druce DunneDruce Dunne, Daniel Hejazi, Ahmed Saleh, Ayesha Haq, Andrzej CalkaAndrzej Calka, Elena PerelomaElena Pereloma
By using electrolytic hydrogen charging, differences in hydrogen pick-up, trapping, hydrogen-induced cold cracking (HICC) and blistering were investigated for an X70 steel for a range of processing and microstructural conditions: as-rolled strip (banded ferritepearlite, BFP); transfer bar (ferrite-granular bainite, FGB); normalised and annealed transfer bar (equiaxed ferrite-pearlite, EFP); and a simulated grain coarsened heat affected zone (GCHAZ) (bainitic ferrite, BF). The microstructure was found to have a profound effect on the response to electrolytic hydrogen charging, with the BFP structure being the most susceptible to HICC and the development of surface blisters. In contrast, the simulated GCHAZ structure did not show any blistering for the maximum charging time of 24 h. These trends are consistent with the ratios of residual to total hydrogen content obtained for the same charging conditions (charging time; electrolyte, current density and sample geometry). The ratio decreased in the order BFP (46%), EFP (34%), FGB (33%), and BF (14%), reflecting the relative capacities of the different microstructures for strong trapping of hydrogen and the related susceptibility to HICC.

Funding

Advanced Testing and Structural Analysis for Assessment and Control of Hydrogen Damage in Structural Steels

Australian Research Council

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History

Citation

Dunne, D. P., Hejazi, D., Saleh, A. A., Haq, A. J., Calka, A. & Pereloma, E. V. (2016). Investigation of the effect of electrolytic hydrogen charging of X70 steel: I. The effect of microstructure on hydrogen-induced cold cracking and blistering. International Journal of Hydrogen Energy, 41 (28), 12411-12423.

Journal title

International Journal of Hydrogen Energy

Volume

41

Issue

28

Pagination

12411-12423

Language

English

RIS ID

108560

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