Hydrogen environment embrittlement testing at low temperatures and high pressures

Corrosion Science

Volumn 50, Issue 12, 2008, Pages 3519-3526

  Michler, Thorsten ^a   Yukhimchuk, Arkadiy A ^b   Naumann, Joerg ^c  

^a GENERAL MOTORS CORPORATION   (United States)

^b RUSSIAN FEDERAL NUCLEAR CENTER VNIIEF   (Russian Federation)

^c BMW AG   (Germany)

Author keywords

High pressure; Hydrogen embrittlement testing; Low temperature; Stainless steel

Indexed keywords

ATMOSPHERIC TEMPERATURE; AUSTENITE; AUSTENITIC STAINLESS STEEL; AUSTENITIC STEEL; EMBRITTLEMENT; HELIUM; HIGH PRESSURE LIQUID CHROMATOGRAPHY; HYDROGEN; LOW TEMPERATURE TESTING; NICKEL ALLOYS; NONMETALS; ORES; STAINLESS STEEL; STEEL CORROSION; STEEL METALLURGY; STEEL TESTING; STRAIN RATE; TENSILE TESTING;

AUSTENITIC; CHEMICAL COMPOSITIONS; ERROR SOURCES; HIGH PRESSURE; HIGH PRESSURES; HYDROGEN ATMOSPHERES; HYDROGEN ENVIRONMENT EMBRITTLEMENTS; LOCAL DEVIATIONS; LOW TEMPERATURE; LOW TEMPERATURES; NI CONTENTS; RELATIVE REDUCTIONS; REPRODUCIBILITY; SCREENING TESTS; SLOW STRAIN RATE TENSILE; TENSILE TESTS;

HYDROGEN EMBRITTLEMENT;

EID: 56649091185     PISSN: 0010938X     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.corsci.2008.09.025     Document Type: Article

References (27)

1. Fukuyama S., Zhang L., and Yokogawa K. Development of materials testing equipment in high pressure hydrogen and hydrogen environment embrittlement of austenitic stainless steel. J. Jpn. Inst. Met. 68 2 (2004) 62-65
2. Caskey G.R. Hydrogen Compatibility Handbook for Stainless Steels (1983), E.I. du Pond de Nemours&Co, Savannah River Lab.
3. Fukuyama S., Sun D., Zhang L., Wen M., and Yokogawa K. Effect of temperature on hydrogen environment embrittlement of type 316 series austenitic stainless steels at low temperatures. J. Jpn. Inst. Met. 67 9 (2003) 456-459
4. Han G., He S., Fukuyama S., and Yokogawa K. Effect of strain-induced martensite on hydrogen environment embrittlement of sensitized austenitic stainless steels at low temperature. Acta Mater. 46 13 (1998) 4559-4570
5. Holbrook J.H., and West A.J. The effect of temperature and strain rate on the tensile properties of hydrogen charged 304L, 21-6-9, and JBK 75. Proceedings of International Conference on Effect of Hydrogen on Behavior of Materials: Hydrogen Effects in Metals (1980), The Metallurgical Society of AIME, Moran WY 655-663
6. Borchers C., Michler T., and Pundt A. Effect of hydrogen on the mechanical properties of stainless steels. Adv. Eng. Mater. 10 1-2 (2008) 11-23
7. Tkachov V.I., Choladny V.I., and Levina I.N. Performance of Steels and Alloys in Hydrogen (1999), Vertical Publ., Lvov in Russian
8. Omura T., Kobayashi K., Miyahara M., and Kudo T. Hydrogen embrittlement properties of stainless steels in high pressure gaseous hydrogen environment. Zairyo to Kankyo/Corros. Eng. 55 (2006) 139-145
9. Hofmann W., and Rauls W. Ductility of steel under the influence of external high pressure hydrogen. Weld. Res. Suppl. May (1965) 225s-230s
10. Kesterson R.L. Effects of irradiation and oxygen on hydrogen environment embrittlement of selected alloys. ASTM STP 543 (1974) 254-263
11. Deimel P., and Hanisch C. Int. J. Hydrogen Energy 14 (1989) 147-151
12. Michler T., and Naumann J. Hydrogen environment embrittlement of austenitic stainless steels at low temperatures. Int. J. Hydrogen Energy 33 (2008) 2111-2122
13. Talonen J., Aspegren P., and Hänninen H. Comparison of different methods for measuring the strain induced á-martensite content in austenitic steels. Mater. Sci. Technol. 20 (2004) 1506-1512
14. Angel T. Formation of martensite in austenitic stainless steels. J. Iron Steel Inst. May (1954) 165-174
15. Zhang T., Chu W.Y., Gao K.W., and Qiao L.J. Study of correlation between hydrogen-induced stress and hydrogen embrittlement. Mater. Sci. Eng. A 347 (2003) 291-299
16. Maksimovich G.G., Tret'yak I.Yu., Ivas'kevich L.M., and Slipchenko T.V. On the role of the martensitic transformation in the process of hydrogen embrittlement of unstable austenitic steels. Mater. Sci. 21 4 (1986) 320-323
17. Vennett R.M., and Ansell G.S. The effect of hydrogen on the tensile properties and fracture behaviour of 304L stainless steel. Trans. ASM 60 (1967) 242-251
18. Buckley J.R., and Hardie D. The effect of pre-straining and d-ferrite on the embrittlement of 304L stainless steel by hydrogen. Corros. Sci. 34 1 (1993) 93-107
19. Vesely E.J., Jacobs R.K., Watwood M.C., and McPherson W.B. Influence of strain rate on tensile properties in high-pressure hydrogen. Proceedings of 5th International Conference on the Effect of Hydrogen on the Behavior of Materials: Hydrogen Effects in Materials, 1994 (1996), Moran WY TMS, Warrendale PA 363-374
20. A. Duncan, P.-S. Lam, T. Adams, Tensile testing of carbon steel in high pressure hydrogen, in: Proceedings of PVP Pressure Vessel Piping Conference, July 22-26, 2007, San Antonio, Texas, USA.
21. R.J. Walter, W.T. Chandler, Effects of high pressure hydrogen on metals at ambient temperature, NASA Report R-7780-1, Prepared by Rocketdyne Research Center, Canoga Park, CA, USA, February 1969.
22. Odegard B.C., Brooks J.A., and West A.J. The effect of hydrogen on the mechanical behaviour of nitrogen strengthened stainless steel. In: Thompson A.W., and Bernstein I.M. (Eds). Effect of Hydrogen on Behaviour of Materials (1976), TMS, New York 116-125
23. Fukuyama S., Zhang L., Wen M., and Yokogawa K. Tensile properties of SUS304 stainless steel in high pressure hydrogen at room temperature. J. Jpn. Inst. Metals 67 4 (2003) 157-160
24. Harris J.A., and VanVanderham M.C. Various mechanical tests used to determine the susceptibility of metals to high-pressure hydrogen. ASTM STP 543 (1974) 198-220
25. K. Yokogawa, S. Fukuyama, Method for deciding austenite stainless steel, Japan Patent Publication No. 2005-009955.
26. Rozenak P. Effects of nitrogen on hydrogen embrittlement in AISI type 316, 321 and 347 austenitic stainless steels. J. Mater. Sci. 25 (1990) 2532-2538
27. San Marchi C., Somerday B.P., Tang X., and Schiroky G.H. Effects on alloy composition and strain hardening on tensile fracture of hydrogen-precharged type 316 stainless steels. Int. J. Hydrogen Energy 33 2 (2008) 889-904