PSI - Issue 28

Jesús Toribio et al. / Procedia Structural Integrity 28 (2020) 2390–2395 Jesús Toribio et al. / Procedia Structural Integrity 00 (2020) 000–000

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Acknowledgements The authors wish to kindly acknowledge the financial support provided by the following Spanish Institutions: Ministry for Science and Technology (MICYT; Grant MAT2002-01831), Ministry for Education and Science (MEC; Grant BIA2005-08965), Ministry for Science and Innovation (MICINN; Grant BIA2008-06810), Ministry for Economy and Competitiveness (MINECO; Grant BIA2011-27870) and Junta de Castilla y León (JCyL; Grants SA067A05, SA111A07 and SA039A08). References Gamboa, E., Atrens, A. 2003. Environmental influence on the stress corrosion cracking of rock bolts. Engineering Failure Analysis 10, 521–558. Guo, N., Luan, B., Wang, B., Liu, Q. 2013. Microstructure and texture evolution in fully pearlitic steel during wire drawing. Science China Technological Sciences 56, 1139–1146. Krom, A.H.M., Koers, R.W.J., Bakker, A. 1999. Hydrogen transport near a blunting crack tip. Journal of the Mechanics and Physics of Solids 47, 971–992. Nam, W.J., Bae, Ch.M. 1995. Void initiation and microstructural changes during wire drawing of pearlitic steels. Materials Science and Engineering 203, 278–285. Nanninga, N., Grochowsi, J., Heldt, L., Rundman, K. 2010. Role of microstructure, composition and hardness in resisting hydrogen embrittlement of fastener grade steels. Corrosion Science 52, 1237–1246. Mallick, A., Das, S., Mathur, J., Bhattacharyya, T., Dey, A. 2013. Internal reversible hydrogen embrittlement leads to engineering failure of cold drawn wire. Case Studies in Engineering Failure Analysis 1, 139–143. Parkins, R.N., Elices, M., Sánchez-Gálvez, V., Caballero, L. 1982. Environment sensitive cracking of pre-stressing steels. Corrosion Science 22, 379–405. Perrin, M., Gaillet, L., Tessier, C., Idrissi, H. 2010. Hydrogen embrittlement of prestressing cables. Corrosion Science 52, 915–926. Ramadan, S., Gaillet, L., Tessier, C., Idrissi, H. 2008. Detection of stress corrosion cracking of high-strength steel used in prestressed concrete structures by acoustic emission technique. Applied Surface Science 254, 2255–2261. Toribio, J., Ayaso, F.J. 2004. Optimization of round-notched specimen for hydrogen embrittlement testing of materials. Journal of Materials Science Letters 39, 4675–4678. Toribio, J., Kharin, V., Vergara. D., Lorenzo, M. 2011. Optimization of the simulation of stress-assisted hydrogen diffusion for studies of hydrogen embrittlement of notched bars. Materials Science 46, 819–833. Toribio, J., Lancha, A.M., Elices, M. 1992. The tearing topography surface as the zone associated with hydrogen embrittlement processes in pearlitic steel. Metallurgical Transactions 23A, 1573–1584. Capelle, J., Gilgert, J., Dmytrakh, I., Pluvinage, G. 2011. The effect of hydrogen concentration on fracture of pipeline steels in presence of a notch. Engineering Fracture Mechanics 78, 364–373.