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Nuclear Technology Volume 103, 1993 - Issue 3
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Technical Note

Potential Application of Zircaloy Chemical Embrittlement to Volume Reduction of Spent-Fuel Cladding

Masafumi NakatsukaNippon Nuclear Fuel Development Company, Ltd. 2163, Narita-cho, Oarai-machi, Higashi-Ibaraki-gun Ibaraki-ken, 311-13, Japan
Pages 426-433 | Published online: 10 May 2017

References

  • A. JOUAN et al., “New Volume Reduction Conditioning Options for Solid α-Bearing Waste,” presented at 3rd European Community Conf. Radioactive Waste Management and Disposal, Luxemburg, September 24–28, 1990.
  • G. COTTONE, “Arising of Cladding Wastes from Nuclear Fuel in the European Community,” EUR-5969EN, Commission of the European Communities (1978).
  • G. BOEHME, G. SPENK, and C. SOMBRET, “Study of Methods for Conditioning and Storage of Spent Fuel Element Hulls,” EUR-8250, Commission of the European Communities (1982).
  • N. JACQUET-FRANCILLON et al., “Hull Melting,” Proc. 3rd Int. Conf. Nuclear Fuel Reprocessing and Waste Management, Sendai, Japan, April 14–18, 1991, Vol. 2, p. 909 (1991).
  • H. S. ROSENBAUM, “Interaction of Iodine with Zircaloy-2,” Electrochem. Technol., 4, 153 (1966).
  • F. L. YAGGEE, R. F. MATTAS, and L. A. NEIMARK, “Characterization of Irradiated Zircaloys: Susceptibility to Stress Corrosion Cracking,” NP-1155, Electric Power Research Institute (1979).
  • A. GARLICK and P. D. WOFFENDEN, “Fracture of Zirconium Alloys in Iodine Vapor,” J. Nucl. Mater., 41, 274 (1971).
  • M. NAKATSUKA and Y. HAYASHI, “Effect of Texture of Zirconium Alloy and Multi-Axial Stress on Iodine SCC Susceptibility,” J. Nucl. Sci. Technol., 19, 2, 119 (1982).
  • D. CUBICIOTTI and R. L. JONES, “EPRI-NASA Cooperative Project on Stress Corrosion Cracking of Zircaloys,” NP-717, Electric Power Research Institute (1978).
  • R. P. GRANGLOFF, D. E. GRAHAM, and A. W. FUNKENBUSCH, “The Effect of Environmental Purity on Gaseous Iodine Embritdement of Zircaloy-2 and High Purity Zirconium,” Corros.-NACE,35, 7, 316 (1979).
  • J. T. A. ROBERTS et al., “A Stress Corrosion Cracking Model for Pellet-Cladding Interaction Failures in Light Water Reactor Fuel Rods,” STP 681, p. 285, American Society for Testing and Materials (1979).
  • D. CUBICIOTTI, R. L. JONES, and B. C. SYRETT, “Chemical Aspects of Iodine Induced SCC of Zircaloy,” STP-754, p. 146, American Society for Testing and Materials (1982).
  • T. T. YANG and C. H. TSAI, “On the Susceptibility to Stress Corrosion Cracking of Zircaloy in an Iodine Containing Environment,” J. Nucl. Mater., 166, 252 (1989).
  • M. A. GOLOZAR and J. C. SCULLY, “The Effect of Loading Mode on the Stress Corrosion Cracking of Zircaloy-2 in a CH3OH/HCI Solution,” Corros. Sci., 22, 11, 1015 (1982).
  • M. H. HONG et al., “A Fractographic Study of Stress Corrosion Cracking of Zircaloy-4 in a Methanol/HCL Solution,” J. Nucl. Mater., 173, 7 (1990).
  • K. R. HEBBAR, H. V. SUDHAKER NAYAK, and T. RAMACHANDRAN, “Stress Corrosion Failure of Zircaloy-2 Sheets in Methanolic HCl Solution: Role of Crystallographic Texture,” Werkstoffe Korrosion, 33, 554 (1982).
  • Β. COX, “Stress Corrosion Cracking of Zircaloys in Iodine Containing Environments,” STP 551, p. 419, American Society for Testing and Materials (1974).
  • B. COX, “A Correlation Between Acoustic Emission During SCC and Fractography of the Zircaloys,” Corros., 30, 6, 190 (1974).
  • J. C. SCULLY, “Stress Corrosion Propagation in a Ti-O Alloy in Aqueous and Methanolic Solutions,” Corros. Sci., 17, 789 (1977).
  • K. ELAYAPERUNAL et al., “Electrochemical Factors of Stress Corrosion Cracking of Zirconium in ch3oh + HCl Solution,” Corros. Sci., 11, 579 (1971).
  • P. MAJUMDAR and J. C. SCULLY, “Reversible Embrittlement in Zircaloy-2,” Corros. Sci., 19, 141 (1979).
  • Β. COX, “Stress Corrosion Cracking of Zry-2 in Neutral Aqueous Chloride Solutions at 25C,” Corros.-NACE, 9, 4, 157 (1973).
  • J. R. McMAHON and D. J. TRUAX, “Mechanism of Stress Corrosion Cracking of Titanium-Aluminum Alloys in Methanol-HCl Solutions,” Corros.-NACE, 29, 2 (1973).

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