STP1132: Investigation of Nodular Corrosion Mechanism for Zircaloy Products

    Wang, CT
    Teledyne Wah Chang Albany, Albany, OR

    Eucken, CM
    Teledyne Wah Chang Albany, Albany, OR

    Graham, RA
    Teledyne Wah Chang Albany, Albany, OR

    Pages: 26    Published: Jan 1991


    Abstract

    Flat mill products of Zircaloy-4 and controlled-chemistry Zircaloy-2 were processed using different rolling schedules in order to generate different textures and other metallurgical conditions. Tubular products of three heats of controlled-chemistry Zircaloy-2 were also processed using various thermo-mechanical parameters and different tube reduction schedules. Samples were taken for 500 and 520°C steam autoclave tests and texture and microstructure examination. Intermetallic precipitates were analyzed for mean diameters and particle size distributions using optical high magnification photographs. Matrix concentrations of Fe, Cr, and Ni were analyzed by electron microprobe with automated stage control.

    Results showed that the nodular corrosion resistance for controlled-chemistry Zircaloy-2 was excellent, while that for Zircaloy-4 was rather poor. The Zircaloy-2 tubeshell may be annealed up to 663°C/2h without detriment to the nodular corrosion resistance of the final size tubing if other fabrication variables are properly controlled. The optimum process for tube reducing is a high Q ratio and high percent of reduction in area. Neither β quench nor α + β treatment after tube extrusion is required to produce cladding tube that is free of nodules in 500 or 520°C autoclave tests. Low basal pole densities are generally related to high corrosion weight gains. The accumulated annealing parameter, ΣA, can generally predict the nodular corrosion behavior of the material, but it cannot account for the higher corrosion weight gain at an intermediate stage and lower weight gain at the final size.

    The most significant correlation is established between variation in concentrations of iron, chrome, and nickel in Zircaloy-2 and nodular corrosion behavior of the material. A depletion of these elements in the matrix or a large spacing between intermetallic precipitates causes poor nodular corrosion resistance. The positive effect of cold work on the nodular corrosion resistance is attributed to increasing the yield strength of the substrate.

    Keywords:

    nodular corrosion, Zircaloy-2, Zircaloy-4, out reactor, tubing, plate, microstructure, precipitation, solute concentration


    Paper ID: STP25515S

    Committee/Subcommittee: B10.02

    DOI: 10.1520/STP25515S


    CrossRef ASTM International is a member of CrossRef.