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    Thermal Creep of Irradiated Zircaloy Cladding

    Published: 01 January 2005

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    As part of an effort to investigate spent-fuel behavior during dry-cask storage, thermal creep tests are being performed with defueled Zircaloy-4 cladding segments from two pressurized water reactors — Surry at ≈36 GWd/MTU burnup and H. B. Robinson at ≈67 GWd/MTU burnup, with corresponding fast (E > 1 MeV) fluence levels of 7×1025 and 14×1025 n/m2. The Surry rods are particularly relevant because they were stored in an inert-atmosphere (He) cask for 15 years. The Robinson rods were received after reactor discharge and pool storage. Commensurate with their high burnup, the Robinson cladding has significant waterside corrosion and hydrogen uptake. Test results to-date indicate good creep ductility for both claddings in the 360–400°C and 160–250 MPa (hoop-stress) regime. Partial recovery of radiation hardening may have occurred during the long tests at 400°C, which led to improved creep ductility. Creep-rate sensitivity is significant for stress and even more so for temperature. The higher hydrogen content in the Robinson material appears to have no detrimental effect on creep behavior at the test temperature. One Robinson sample, which ruptured in the weld region at 205°C during cooling from 400°C under stress (190 MPa), precipitated all visible hydrides in the radial direction.


    Zircaloy-4 cladding, thermal creep, stress, temperature, hydrides, annealing, stress, temperature sensitivity

    Author Information:

    Tsai, H
    Principal Investigator, Argonne National Laboratory, Argonne, IL

    Billone, MC
    Section Manager, Energy Technology, Argonne National Laboratory, Argonne, IL

    Committee/Subcommittee: B10.02

    DOI: 10.1520/STP37528S