Corrosion-fatigue durability of pipe steel in carbonate-bicarbonate medium

1. I. G. Abdullin and A. G. Gareev, “Diagnostics of stress-corrosion cracking of pipelines,” in:Proceedings of 2nd International Conference on Pipeline Inspection, MSIA “Spectrum,” Moscow (1991), pp. 338–341.

2. A. G. Gareev and I. G. Abdullin, “Investigation of the process of carbonate corrosion cracking,” in:Abstracts of the Regional Scientific and Technical Conference [in Russian], UAI, Ufa (1990), pp. 33–34.

   Google Scholar 

3. E. Baidal, P. J. Haagtnsen, M. Grovlen, and F. Sather, “Effects of cathodic protection on corrosion fatigue crack in a platform steel in sea water,” in:Proceedings of 2nd International Conference “Fatigue-84,” Vol. 3. Warley, Birmingham (1984), pp. 1541–1551.

   Google Scholar 

4. G. Philoponeu, S. Widawski, M. Habayi, and J. Galland. “Cathodic polarization effects on magnesium calcium deposit formation at fatigue crack roots of mild steel in sea water,” in:Proceedings of International Conference on Fracture Prevention in Energy and Transport Systems, Rio de Janeiro, Vol. 1, Warley (1984), pp. 209–220.

5. J. A. Beavers, W. E. Berry, and R. N. Parkins, “Standard test procedure for stress corrosion cracking threshold stress determination,”Mater. Perf. 25, No. 6, 9–17 (1966).

   Google Scholar 

6. A. J. Mendosa and J. M. Sykes, “The effect of low frequency cyclic stress on initiation of stress corrosion cracking in X60 line pipe steel in carbonate solution,”Corr. Sci. 23, No. 6, 547–558 (1983).

   Google Scholar 

7. S. V. Serensen (ed.),Handbook for Mechanical Engineer [in Russian], Vol. 3, Mashgiz, Moscow (1962).

   Google Scholar 

8. L. M. Shkol'nik,Crack-Growth Rate and Life of Metal [in Russian], Metallurgiya, Moscow (1973).

   Google Scholar 

Download references