Effect of microstructure and composition on hydrogen permeation in X70 pipeline steels

International Journal of Hydrogen Energy

Volumn 38, Issue 5, 2013, Pages 2544-2556

  Haq, Ayesha J ^a   Muzaka, K ^a   Dunne, D P ^a   Calka, A ^a   Pereloma, E V ^a  

^a UNIVERSITY OF WOLLONGONG   (Australia)

Author keywords

Diffusion; Grain size; Microstructure; Permeability; Pipeline steel; Traps

Indexed keywords

DIFFUSION; FERRITE; MECHANICAL PERMEABILITY; MICROSTRUCTURE; PERMEATION; PIPELINES; STEEL PIPE;

CARBO-NITRIDE PRECIPITATE; ELECTROCHEMICAL PERMEATION; GRAIN SIZE; HYDROGEN PERMEATION; PIPELINE STEEL; TRAPS; UNIFORM MICROSTRUCTURE; X70 PIPELINE STEEL;

MANGANESE;

EID: 84874113059     PISSN: 03603199     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijhydene.2012.11.127     Document Type: Article

References (51)

1. Lee JY, Lee SM. Hydrogen trapping phenomena in metals with B.C.C. and F.C.C. crystals structures by the desorption thermal analysis technique. Surface and Coatings Technology 1986;28:301-14.
2. Pressouyre GM, Bernstein I. A quantitative analysis of hydrogen trapping. Metallurgical Transactions A 1978;10: 1571-80.
3. Villalba E, Atrens A. SCC of commercial steels exposed to high hydrogen fugacity. Engineering Failure Analysis 2008; 15:617-41.
4. Calder RD, Elleman TS, Verghese K. Grain boundary diffusion of tritium in 304- and 316-stainless steels. Journal of Nuclear Materials 1973;46:46-52.
5. Kimura A, Birnbaum HK. Hydrogen induced grain boundary fracture in high purity nickel and its alloys-enhanced hydrogen diffusion along grain boundaries. Acta Metallurgica 1988;36:757-66.
6. Tsuru T, Latanision RM. Grain boundary transport of hydrogen in nickel. Scripta Metallurgica 1982;16:575-8.
7. Brass AM, Chanfreau A. Electrochemical permeation of hydrogen in high purity nickel at 100 °C. Scripta Metallurgica et Materialia 1990;24:499-504.
8. Choo WY, Lee JY, Cho CG. Effect of grain size. Materials Science 1981;16:1285-93.
9. Wert CA. Trapping of hydrogen in metals. In: Alefeld G, Volkl J, editors. Hydrogen in metals II. Application-oriented properties. Springer-Verlag; 1978. p. 305-30.
10. Yao J, Cahoon JR. Theoretical modeling of grain boundary diffusion of hydrogen and its effect on permeation curves. Acta Metallurgica et Materialia 1991;39:119-26.
11. Ichimura M, Sasajima Y, Imabayashi M. Grain boundary effect on diffusion of hydrogen in pure aluminum. Materials Transactions JIM 1991;32:1109-14.
12. Yazdipour N, Haq AJ, Muzaka K, Pereloma EV. 2D modelling of the effect of grain size on hydrogen diffusion in X70 steel. Computational Materials Science 2012;56:49-57.
13. Huang F, Liu J, Deng ZJ, Cheng JH, Lu ZH, Li XG. Effect of microstructure and inclusions on hydrogen induced cracking susceptibility and hydrogen trapping efficiency of X120 pipeline steel. Materials Science and Engineering A 2010;527: 6997-7001.
14. Xue HB, Cheng YF. Characterization of inclusions of X80 pipeline steel and its correlation with hydrogen-induced cracking. Corrosion Science 2011;53:1201-8.
15. Lee SM, Lee JY. The effect of the interface character of TiC particles on hydrogen trapping in steel. Acta Metallurgica 1987;35:2695-700.
16. Garet M, Brass AM, Haut C, Guttierez-Solana F. Hydrogen trapping on non metallic inclusions in Cr-Mo low alloy steels. Corrosion Science 1998;40:1073-86.
17. Stevens MF, Bernstein IM. Microstructural trapping effects on hydrogen induced cracking of a microalloyed steel. Metall Trans A 1989;20A:909-19.
18. Takahashi I, Matsumoto Y, Tanaka T. In: Proc. JIMIS-2. Minakami, Tokyo, Japan; 1979.
19. Valentini R, Solina A, Matera S, De Gregorio P. Influence of titanium and carbon contents on the hydrogen trapping of microalloyed steels. Metallurgical and Materials Transactions A 1996;27:3773-80.
20. Wei FG, Tsuzaki K. Quantitative analysis on hydrogen trapping of TiC particles in steel. Metallurgical and Materials Transactions A 2006;37:331-53.
21. Wei FG, Hara T, Tsuzaki K. Nano-precipitates design with hydrogen trapping character in high strength steels. In: Somerday B, Sofronis P, Jones R, editors. Effects of hydrogen on materials, proceedings of the international hydrogen conference, Wyoming, USA; 2008. p. 448-55.
22. Wei FG, Tsuzaki K. Hydrogen trapping character of nanosized NBC precipitates in tempered martensite. In: Somerday B, Sofronis P, Jones R, editors. Effects of hydrogen on materials, proceedings of the international hydrogen conference, Wyoming, USA; 2008. p. 456-63.
23. Yamasaki S, Takahashi T. Evaluation method of delayed fracture property of high strength steels. Tetsu-to-Hagane 1997;83:454-9.
24. Yuan X. Precipitates and hydrogen permeation behavior in ultra-low carbon steel. Materials Science and Engineering A 2007;452-453:116-20.
25. Andenna C, Torella R. A study of hydrogen permeation on API X65 TMCP steel under stress conditions. In: Turnbull A, editor. Hydrogen transport and cracking in metals. Proceedings of a conference, Teddington UK; 1995. p. 240-52.
26. Contreras A, Albiter A, Salazar M, Pérez R. Slow strain rate corrosion and fracture characteristics of X-52 and X-70 pipeline steels. Materials Science and Engineering A 2005; 407:45-52.
27. Dong CF, Li XG, Liu ZY, Zhang YR. Hydrogen-induced cracking and healing behaviour of X70 steel. Journal of Alloys and Compounds 2009;484:966-72.
28. Dong CF, Liu ZY, Li XG, Cheng YF. Effects of hydrogencharging on the susceptibility of X100 pipeline steel to hydrogen-induced cracking. International Journal of Hydrogen Energy 2009;34:9879-84.
29. Kim WK, Koh SU, Yang BY, Kim KY. Effect of environmental and metallurgical factors on hydrogen induced cracking of HSLA steels. Corrosion Science 2008;50:3336-42.
30. Koh SU, Kim JS, Yang BY, Kim KY. Effect of line pipe steel microstructure on susceptibility to sulfide stress cracking. Corrosion Science 2004;60:244-54.
31. Park GT, Koh SU, Jung HG, Kim KY. Effect of microstructure on the hydrogen trapping efficiency and hydrogen induced cracking of linepipe steel. Corrosion Science 2008;50:1865-71.
32. Ramírez E, González-Rodriguez JG, Torres-Islas A, Serna S, Campillo B,Dominguez-Patiño G, et al. Effect of microstructure onthe sulphide stress cracking susceptibility of a high strength pipeline steel. Corrosion Science 2008;50:3534-41.
33. Scoppio L, Barteri M. Methods of hydrogen uptake measurements by electrochemical permeation test on low alloy steels. In: Turnbull A, editor. Hydrogen transport and cracking in metals. Proceedings of a conference, Teddington UK; 1995. p. 204-15.
34. Serna S, Martínez H, López SY, González- Rodríguez JG, Albarrán JL. Electrochemical technique applied to evaluate the hydrogen permeability in microalloyed steels. International Journal of Hydrogen Energy 2005;30:1333-8.
35. Skjellerudsveen M, Akselsen OM, Olden V, Johnsen R, Smirnova A. Effect of microstructure and temperature on hydrogen diffusion and tripping in X70 grade pipeline steel and its weldments. In: Proceedings of the 2010 EUROCORR conference, Moscow, Russia; 2010.
36. Williams JG. Advances in steels for high strength ERW linepipe applications in Australia. Materials Forum 2007;31: 1-10.
37. Devanathan MAV, Stachurski Z. The adsorption and diffusion of electrolytic hydrogen in palladium. The Royal Society of London A 1962;270:90-102.
38. Iino M. Analysis of irreversible hydrogen trapping. Acta Metallurgica 1982;30:377-83.
39. 2S concentration on hydrogen diffusion and trapping in a 13% chromium martensitic stainless steel in acidified NaCl. Corrosion Science 1990;30:667-79.
40. Kiuchi K, McLellan RB. The solubility and diffusivity of hydrogen in well-anealed and deformed iron. Acta Metallurgica et Materialia 1983;31:961-84.
41. Dunne DP. Ferrite morphology and residual phases in continuously cooled low carbon steels. Materials Forum 1999;23:63-76.
42. Desforges CD, Duckworth WE, Ryan TFJN. Manganese in ferrous metallurgy. Paris: The Manganese Centre; 1977.
43. Manolatos P, Jerome M, Thual CD, Coze JL. The electrochemical permeation of hydrogen in steels without palladium coating. Part I: interpretation difficulties. Corrosion Science 1995;37:1773-83.
44. Beck B, Bockris JO, McBreen J, Nanis L. Proceedings of the Royal Society of London A 1966;290:220.
45. Amiot PAB, Pinard-Legry G. Contribution a I'etude du cloquage des a&r pour constructions soudees. presentee a Deuxieme Congres International. L'hydrogene dans les metaux. Paris, 3E8; 1977.
46. Bruzzoni P, Garavaglia R. Anodic iron oxide films and their effect on the hydrogen permeation through steel. Corrosion Science 1992;33:1797-807.
47. Charbonnier JC, Margot-Marette H, Brass AM, MAucoutier M. Sulfide stress cracking of high strength modified Cr-Mo steels. Metallurgical Transactions A 1985;16:935-44.
48. Pérez Escobar D, Miñambres C, Duprez L, Verbeken K, Verhaege M. Internal and surface damage of multiphase steels and pure iron after electrochemical hydrogen charging. Corrosion Science 2011;53:3166-76.
49. Lee HL, Chan SLI. Hydrogen embrittlement of AISI 4130 steel with an alternate ferrite/pearlite banded structure. Materials Science and Engineering A 1991;142:193-201.
50. Tau L, Chan SLI. Effects of ferrite/pearlite alignment on the hydrogen permeation in a AISI 4130 steel. Materials Letters 1996;29:143-7.
51. Hejazi D, Haq AJ, Yazdipour N, Dunne DP, Calka A, Barbaro F, et al. Effect of manganese content and microstructure on the susceptibility of pipeline steel to hydrogen cracking. Materials Science and Engineering A 2012;551:40-9.