A Proposal For The First Comparative Irradiation Of Various High Performance Zirconium Alloy Clad Fuel At Conditions Representative Of Low Temperature Dryout








Irradiation of Extrusion-clad Uranium-2 W/o Zirconium Alloy for EBR-1, Mark III

Author : J. H. Kittel

Publisher :

Page : 40 pages

File Size : 19,35 MB

Release : 1959

Category : Irradiation

ISBN :

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Book Description

The fuel material specified for the Mark III core of EBR-I was uranium-2 wt. % zirconium alloy coextruded with Zircaloy-2 cladding. From previous work on swaged or rolled uranium-2 wt% zirconium alloy, it was anticipated that the extruded alloy would be dimensionally unstable under irradiation unless stabilized by suitable heat treatment. In order to determine an effective heat treatment, irradiation studies were made on both clad and unclad extruded uranium-2 wt.% zirconium alloy specimens at irradiation temperature estimated at 200 to 750 deg C. The irradiation specimens included material with three different heat treatments, selected on the basis of previous studies, and material transient melted in its cladding. For unclad specimens, it was found that the irradiation temperature strongly influenced the various irradiation growth rates resulting from different heat treatments. Growth rates of the clad specimens were relatively insensitive to either irradiation temperature or prior heat treatment. An exception was the transient-melted material, which shortened under irradiation. The cladding had only limited ability to restrain the swelling rates of specimens irradiated at the more elevated temperatures. Clad transient-melted material was found to be most resistant to high-temperature swelling under irradiation. The results of the present study combined with observations in earlier investigations resulted in a recommendation that the reference heat treatment for the core consist of gamma solution at 800 deg C followed by isothermal transformation at 690 deg C.







Effects of Irradiation on the EBWR Fuel Alloy Uranium-5 W/o Zirconium-1.5 W/o Niobium

Author : J. H. Kittel

Publisher :

Page : 50 pages

File Size : 21,10 MB

Release : 1960

Category : Irradiation

ISBN :

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Book Description

Irradiations were made on small specimens of U-5 wt.% Zr-1.5 wt.% Nb alloy with a wide variety of fabrication histories and heat treatments in order to determine the optimum heat treatment for the fuel plates for the Experimental Boiling Water Reactor (EBW). In the time available, a heat treatment could not be found which simultaneously conferred dimensional stability and corrosion resistance to the alloy. The most effective heat treatment for dimensionally stabilizing swaged or round-rolled material was a 24-hr isothermal transformation from the gamma phase at 650 deg C. This heat treatment was subsequently used as a basis for the heat-treatment specifications for the EBWR fuel plates. In later studies on specimens cut from plates it was learned that the alloy could be adequately stabilized against irradiation growth and also made corrosion- resistant by first reducing the plate 12% in thickness by cold rolling followed by a 24-hr isothermal transformation from the gamma phase at 665 deg C, and finally quenching from 800 deg C. Irradiation growth rates of plate specimens were effectively reduced by the presence of metallurgically bonded Zircaloy-2 cladding. Flat-rolled material under irradiation generally increased in length and width and decreased in thickness.



In-PWR Irradiation Performance of Dilute Tin-Zirconium Advanced Alloys

Author : GP. Smith

Publisher :

Page : 17 pages

File Size : 38,86 MB

Release : 2002

Category : Corrosion resistance

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Book Description

Zirconium alloys containing about 0.5% tin, which are classified as dilute tin alloys, possess excellent uniform waterside corrosion resistance necessary for the PWR fuel applications. Mechanical and irradiation growth properties of the dilute alloys can be adjusted for specific component application by controlling the additions of other alloying elements such as iron, chromium, niobium, and oxygen. Cladding alloys with such additions have been successfully irradiated to burnups up to 69 GWd/MTU, showing significant improvements in corrosion resistance and irradiation growth characteristics compared to low-tin Zircaloy-4, one of the current standard materials. The in-PWR creep resistance of such dilute alloys is comparable to that of low-tin Zircaloy-4. Another dilute alloy with predominantly iron-containing second-phase particles that are unstable under neutron irradiation (in a cold-worked microstructure, cold work introduced prior to irradiation) appears to be most suitable for the grid strip application. Cold-worked I-spring of this alloy in a transverse stamped grid provides excellent fuel rod support by inward motion of the spring within the grid cell due to irradiation growth. The hydrogen pickup fraction of several zirconium alloys, including Zircaloy-4 and dilute alloys, exhibits a well-behaved correlation with oxide thickness under non-heat flux conditions. A similar correlation is expected under heat flux conditions. Under heat flux conditions, the hydrogen pickup fraction for Zircaloy-4 approaches a constant value of about 15% for oxide thicknesses greater than 50 ?m. For the non heat-flux conditions, the pickup fraction is less than 5% for oxide thickness values greater than 50 ?m. Possible reasons for influence of oxide thickness and heat flux on the hydrogen pickup fraction are the porosity traps in thick oxide layers and atomic vibrations of oxide lattice under heat flux conditions. The in-PWR performance characteristics of the dilute alloys such as corrosion resistance, ductility, and dimensional stability can be controlled by optimization of the composition and fabrication process. These parameters influence the composition of the second-phase particles (SPP) in the alloy microstructure, which determines the radiation stability of the SPP. Irradiation stabilityof SPP has strong impact on the in-PWR performance characteristics of zirconium alloys.