Published: Jan 2010
| ||Format||Pages||Price|| |
|PDF (3.4M)||24||$25||  ADD TO CART|
|Complete Source PDF (69M)||24||$125||  ADD TO CART|
Significant data and milestones in the development of the ZIRLO alloy for PWR applications arc reviewed. From humble beginnings as an R&D program, an approach to improving the corrosion resistance of zirconium-based alloys was developed. The corrosion resistance of dilute alloys is controlled by the microstructure, and both solid solution and precipitate effects impact corrosion performance. Several transition metals are beneficial for corrosion at low concentrations, but the most favourable alloy system is zirconium-niobium, because it offers flexibility in processing options. Strength of the binary alloys can be improved by additions of tin, which, in combination with low levels of iron, provide corrosion resistance in lithium hydroxide solutions. Numerous experimental ingots, thermo-mechanical processing routes, corrosion tests, and materials characterizations were performed along the path to the final alloy composition. The resulting material, ZIRLO, has proven itself as a successful alloy for PWR fuel cladding and structural applications. The original paper was published by ASTM International in the Journal of ASTM International, February 2005.
zirconium, zirconium alloys, ZIRLO, Zircaloy-4, tin, niobium, iron, corrosion, water, steam, lithium hydroxide, in-reactor corrosion, microstructure, precipitates, fuel cladding, heat treatment, creep, growth, PWRs
Sabol, George P.
Consultant in Nuclear Materials, Westinghouse Electric Company,
Paper ID: MNL12123R