Page 159 - Дисертаця Венгринюк
P. 159
159
9. Alam T., Islam M. A. Assessing hydrogen embrittlement in pipeline
steels for natural gas-hydrogen blends: Implications for existing infrastructure.
Solids. 2024. Vol. 5. P. 375–393.
10. Doroshenko Y., Karpash M., Stetsiuk S. et al. Prospects and problematic
issues of formation and development of hydrogen energy in Ukraine. Prospecting
and Development of Oil and Gas Fields. 2022. Vol. 22, No. 1. Р. 7–33.
11. Dadfarnia M., Sofronis P., Brouwer J. et al. Assessment of resistance to
fatigue crack growth of natural gas line pipe steels carrying gas mixed with
hydrogen. International Journal of Hydrogen Energy. 2019. Vol. 44.
P. 10808–10822.
12. Nykyforchyn H., Unigovskyi L., Zvirko O. et al. Pipeline durability and
integrity issues at hydrogen transport via natural gas distribution network. Procedia
Structural Integrity. 2021. Vol. 33. Р. 646–651.
13. Campari A., Ustolin F., Alvaro A., Paltrinieri N. A review on hydrogen
embrittlement and risk-based inspection of hydrogen technologies. International
Journal of Hydrogen Energy. 2023. Vol. 48, No. 90. P. 35316–35346.
14. San Marchi C., Somerday B. P. Technical reference on hydrogen
compatibility of materials. Sandia Report SAND2012-7321. 2012. 292 p.
15. Laureys A., Depover T., Petrov R. et al. Influence of sample geometry
and microstructure on the hydrogen induced cracking characteristics under uniaxial
load. Materials Science and Engineering A. 2017. Vol. 690. P. 88–95.
16. Hardie D., Liu S. The effect of stress concentration on hydrogen
embrittlement of a low alloy steel. Corrosion Science. 1996. Vol. 38, No. 5.
P. 721–733.
17. Messaoudani Z. L., Rigas F., Hamid M. D. et al. Hazards, safety and
knowledge gaps on hydrogen transmission via natural gas grid: A critical review.
International Journal of Hydrogen Energy. 2016. Vol. 41, No. 39. P. 17511–17525.
18. Sun B., Wang D., Lu X. et al. Current challenges and opportunities
toward understanding hydrogen embrittlement mechanisms in advanced high-

