Page 311 - DISS_NYRKOVA
P. 311
311
141. Contreras A., Sosa E., Espinosa-Medina M.A. Cathodic protection
effect on the assessment of SCC Susceptibility of X52 pipeline steel. MRS
Proceedings. 2009. 1242.
142. Albarran J. ., Martinez L., Lopez H. Effect of heat treatment on the
stress corrosion resistance of a microalloyed pipeline steel. Corrosion Science.
1999. Vol. 41. № 6. P. 1037–1049.
143. Zhang X., Yang W., Xu H., Zhang L. Effect of cooling rate on the
formation of nonmetallic inclusions in X80 pipeline steel. Metals. 2019. Vol. 9.
№ 4. 392. Р.1–11.
144. Gu B., Yu W.Z., Luo J.L., Mao X. Transgranular stress corrosion
cracking of X-80 and X-52 pipeline steels in dilute aqueous solution with near-
neutral pH. Corrosion. 1999. Vol. 55. № 3. P. 312–318.
145. Tamehiro H., Takeda T., Matsuda S., Yamamoto K., Okumura N.
Effect of accelerated cooling after controlled rolling on the hydrogen induced
cracking resistance of line pipe steel. Transactions of the Iron and Steel Institute
of Japan. 1985. Vol. 25. № 9. P. 982–988.
146. Mohtadi-Bonab M.A., Szpunar J.A., Razavi-Tousi S.S. Hydrogen
induced cracking susceptibility in different layers of a hot rolled X70 pipeline
steel. International Journal of Hydrogen Energy. 2013. Vol. 38. № 31.
P. 13831–13841.
147. Zhang S., Fan E., Wan J., Liu J., Huang Y., Li X. Effect of Nb on the
hydrogen-induced cracking of high-strength low-alloy steel. Corrosion Science.
2018. Vol. 139. P. 83–96.
148. Hejazi D., Haq A.J., Yazdipour N., Dunne D.P., Calka A., Barbaro
F., Pereloma E.V. Effect of manganese content and microstructure on the
susceptibility of X70 pipeline steel to hydrogen cracking. Materials Science and
Engineering: A. 2012. Vol. 551. P. 40–49.
149. Smirnov M. A., Pyshmintsev I. Y., Maltseva A. N., Mushina O. V.
Effect of ferrite-bainite structure on the properties of high-strength pipe steel.
Metallurgist. 2012. Vol. 56. № 1-2. P. 43–51.
