Effect of Y/Zr Ratio on Inclusions and Mechanical Properties of 9Cr-RAFM Steel Fabricated by Vacuum Melting

Abstract

This study investigates the inclusions, microstructures, tensile properties, and impact toughness of reduced-activation ferritic/martensitic (RAFM) steels with different Y/Zr ratio contents. An optical microscope and a scanning electron microscope (SEM) were employed to determine the size and number of inclusions, and SEM and transmission electron microscope were employed to examine the inclusion types. The increase in Y/Zr ratio influenced the prior austenite grain size owing to the pinning effect of the inclusions. The result of this examination showed that the mechanical properties of the steel are closely related to the refinement of prior austenite grain size and as well as the fine submicron-sized inclusions. The average prior austenite grain sizes of the alloys were 14.5, 13.5, and 13.4 μm for the steels with different Y/Zr ratio contents (i.e., 1/2, 5/3, and 11/2, respectively). Moreover, the submicron-sized inclusions in the alloys achieved densities of 4.71 × 1016, 4.49 × 1016, and 3.84 × 1016/m3. The ductile-to-brittle transition temperature (DBTT) decreases when the Y/Zr ratio increases to 5/3. However, the DBTT increases when the Y/Zr ratio reaches 11/2 owing to inclusion coarsening. The RAFM steel with Y content of approximately 0.005 wt.% and Zr content of 0.002 wt.% was verified to exhibit an optimized combination of microstructures, tensile properties, and impact toughness.