Page 188 - Dys
P. 188
188
pipeline steels. Eurocorr 2005 : European Corrosion Congress. Lisbon, 2005. Paper
№ 594.
85. Кушнаренко В. М., Репях В. С., Кушнаренко Е. В., Чирков Е. Ю.
Анализ причин отказов оборудования и трубопроводов. ВЕСТНИК ОГУ. 2010.
10. С. 153–159.
86. Parkins R. N. A review of stress corrosion cracking of high pressure gas
pipelines. CORROSION 2000 : Int. Conf. Houston: NACE, 2000. Paper № 00363. 23 р.
87. Chen W. Modeling and prediction of stress corrosion cracking of pipeline
steels. Trends in Oil and Gas Corrosion Research and Technologies. 2017.
P. 707–748.
88. Zvirko O. I., Savula S. F., Tsependa V. M., Gabetta G., Nykyforchyn
H. M. Stress corrosion cracking of gas pipeline steels of different strength. Procedia
Structural Integrity. 2016. 2. P. 509–516.
89. Xue H. B., Cheng Y. F. Characterization of inclusions of X80 pipeline
steel and its correlation with hydrogen-induced cracking. Corrosion Science. 2011.
53. P. 1201–1208.
90. Сунагатов М. Ф., Климов П. В., Гумеров А. К. Влияние водорода на
характер разрушения трубопроводов. Проблемы сбора, подготовки и
транспорта нефти и нефтепродуктов. 2010. 3(81). С. 35–42.
91. Mohtadi-Bonab M. A., Szpunar J. A., Razavi-Tousi S. S. A comparative
study of hydrogen induced cracking behavior in API 5L X60 and X70 pipeline
steels. Engineering Failure Analysis. 2013. 33. P. 163–175.
92. Gyu T. T., Sung U. K., Hwan G. J., Kyoo Y. K. Effect of microstructure
on the hydrogen trapping efficiency and hydrogen induced cracking of linepipe
steel. Corrosion Science. 2008. 50. P. 1865–1871.
93. Venegas V., Caleyo F., Herrera O., Hernández-Sánchez J., Hallen J. M.
Crystallographic texture helps reduce HIC cracking in pipeline steels. International
Journal of Electrochemical Science. 2014. 9. P. 418–425.
94. Mohtadi-Bonab M. A., Eskandari M., Szpunar J. A. Texture, local
misorientation, grain boundary and recrystallization fraction in pipeline steels
