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The Effects of Exposure to Flowing Sodium on Vanadium Alloys in Stainless Steel Containment Systems

  • Chapter
Corrosion by Liquid Metals

Abstract

In recent years considerable effort has been expended on the development of vanadium base alloys for fuel element cladding in sodium-cooled fast breeder reactors. This paper deals with the effects of exposure to sodium on several of the more promising vanadium alloys. The compositions that were studied are:

V-9Cr-3Fe-1.3Zr-0.05C (VANSTAR 7)

V-8Cr-10Ta-1.3Zr-0.05C (VANSTAR 8)

V-6Fe-5Nb-1.3Zr-0.05C (VANSTAR 9)

V-20Ti (for comparison)

All alloys exhibited weight gains after exposure to flowing sodium containing less than lOppm oxygen in a Type 316 stainless steel loop system over the temperature range of 675–800°C. Removal of the interstitials, nitrogen, carbon, and oxygen from the stainless steel, and their absorption by the vanadium alloys is shown to account for the observed increase in weight after exposure. The kinetics of the corrosion process, the weight change data, and the mechanical property changes related to interstitial pick up from the stainless steel have been examined, using a layer chemical analysis technique. Interstitial concentration gradients in both the vanadium alloys and the stainless steel loop tubing have been used to obtain activation energies for corrosion and interstitial diffusion coefficients in these materials. In addition to weight change and metallographic results, data are presented on the effects of this interstitial absorption on the mechanical properties of the vanadium alloys. After 1500 and 2650 hours of exposure to sodium, 800°C tensile elongation values greater than 20 percent were obtained for the VANSTAR alloys, but the room temperature ductility was very much reduced. This paper discusses ways of reducing the interstitial absorption and mechanical property deterioration. Among these are the use of stabilized stainless steel loop construction at more realistic reactor operating temperatures, or modification of stainless to vanadium alloy surface area ratios.

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References

  1. J. E. Irvin, A. L. Bement, and R. G. Hoagland, “The Combined Effects of Temperature and Irradiation on the Mechanical Properties of Austenitic Stainless Steels,” Flow and Fracture of Metals and Alloys in Nuclear Environments, ASTM STP-380, pp 236–250, ASTM, (1965)

    Chapter  Google Scholar 

  2. H. Böhm, W. Dienst, H. Hauck, and H. J. Laue, “Irradiation Effects on the Mechanical Properties of Vanadium-Base Alloys,” Paper No$1175, ASTM STP No. 426, June 27-July 1, (1966).

    Google Scholar 

  3. R. T. Begley, E. C. Bishop, R. W. Buckman, R. A. Nadler, and G. A. Whitlow, “Development of Vanadium Alloys for LMFBR Cladding,” Trans. Am. Nucl. Soc., 11, 2, p. 501, (1968).

    Google Scholar 

  4. H. U. Borgstedt and G. Frees, “The Oxidation of Vanadium Base Alloys by Liquid Sodium Containing Dissolved Oxides in Temperatures Ranging from 500 to 600°C,” Corrosion, 24, 7, 209, (July 1968).

    Article  Google Scholar 

  5. H. U. Borgstedt and G. Frees,“ The Oxidation of Metals and Alloys for Cladding of Fast Reactor Fuel Elements by Oxygen Containing Liquid Sodium,” Paper presented at The 4th International Congress on Metallic Corrosion, Amsterdam, ( September 1969 ).

    Google Scholar 

  6. L. Champeix, R. Darras, and J. Sannier, “Corrosion of Vanadium Alloys in Sodium,” Proc, IAEA Symp. on Alkali Metal Coolants, Vienna, SM 85 /7 pp. 45–61, (1966).

    Google Scholar 

  7. Annual Progress Report for 1965 Metallurgy Division,“ ANL-715, Argonne National Laboratory, (1965).

    Google Scholar 

  8. Annual Progress Report for 1966 Metallurgy Division,“ ANL-7299, Argonne National Laboratory, (1966).

    Google Scholar 

  9. S. Greenberg, W. E. Ruther, and H. A. Levin, “Corrosion of Vanadium Base Alloys in Sodium at 500 to 750°C,” Proc. IAEA Symp. on Alkali Metal Coolants, Vienna, SM 85 /20, pp. 63–84, (1966).

    Google Scholar 

  10. W. E. Ruther, “The Corrosion of Vanadium-base Alloys in Sodium,” Proc. Int. Conf. on Sodium Technology and Large Fast Reactor Design, ANL-7520 Part I pp. 182–191, (1968).

    Google Scholar 

  11. J. R. Weeks, “Quarterly Progress Report of Work Sponsored by the Fuels and Materials Branch,” BNL 50123 (T-501), Brookhaven National Laboratory, (1968).

    Google Scholar 

  12. Los Alamos Scientific Laboratory, “Quarterly Status Report on the Advanced Plutonium Fuels Program,” LA-3745-MS, (1967).

    Google Scholar 

  13. K. C. Thomas, E. C. Bishop, and G. A. Whitlow, “The Corrosion and Compatibility of Vanadium Alloys for Fuel Element Cladding,” Nuclear Applications and Technology, vol. 7, No. 2, pp 144–154, (1969).

    Google Scholar 

  14. G. A. Whitlow, R. J. Hornak, S. L. Schrock, and E. C. Bishop, “The Effects of Exposure to Sodium on the Metallurgical and Mechanical Properties of Vanadium Alloys,” J. Less Common Metals, 18, pp. 357–371, (1969).

    Article  Google Scholar 

  15. W. Pollack, K. C. Thomas, K. R. Jordan, R. T. Begley, R. W. Buckman, and E. C. Bishop, Westinghouse Electric Corporation Rept. WCAP-3487–16, (1967).

    Google Scholar 

  16. D. L. Smith, Reactor Development Program Progress Report ANL7577, p. 153–155, (April-May 1969 ).

    Google Scholar 

  17. E. C. Bishop, R. A. Nadler, and G. A. Whitlow, “Vanadium Alloy Cladding Development Quarterly Progress Report for the Period Ending December 31, 1968,” Westinghouse Electric Corporation, WARD 3791–30, (1969).

    Google Scholar 

  18. Allison Division, General Motors Final Report, “Investigation of Bimetallic Liquid Metal Systems,” GMAD 3643–8, (1966).

    Google Scholar 

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Author information

Authors and Affiliations

  1. Advanced Reactors Division, Westinghouse Electric Corporation, Madison, Pa., USA

    G. A. Whitlow, R. J. Hornak, S. L. Schrock & E. C. Bishop

Authors
  1. G. A. Whitlow
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  2. R. J. Hornak
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  3. S. L. Schrock
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  4. E. C. Bishop
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Editor information

Editors and Affiliations

  1. Chemical Engineering Division, Argonne National Laboratory, Argonne, Illinois, USA

    Joseph E. Draley

  2. Department of Applied Science, Brookhaven National Laboratory, Upton, New York, USA

    John R. Weeks

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© 1970 Springer Science+Business Media New York

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Whitlow, G.A., Hornak, R.J., Schrock, S.L., Bishop, E.C. (1970). The Effects of Exposure to Flowing Sodium on Vanadium Alloys in Stainless Steel Containment Systems. In: Draley, J.E., Weeks, J.R. (eds) Corrosion by Liquid Metals. Springer, Boston, MA. https://doi.org/10.1007/978-1-4684-1845-3_8

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  • DOI: https://doi.org/10.1007/978-1-4684-1845-3_8

  • Publisher Name: Springer, Boston, MA

  • Print ISBN: 978-1-4684-1847-7

  • Online ISBN: 978-1-4684-1845-3

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