Abstract
The effects of the Y- and Ti-containing inclusions on the tensile and impact properties of reduced activation ferritic martensitic (RAFM) steels were evaluated. Four steels with different Y and Ti contents were produced via vacuum induction melting. The size and quantity of inclusions in the steels were analyzed using scanning electron microscopy, and the oxide particle formation mechanism was clarified. These inclusions helped to enhance the pinning effect of the austenite grain boundaries based on the Zener pinning force. The average prior austenite grain sizes, measured via the linear intercept method, were 12.34 (0 wt.% Ti), 9.35 (0.010 wt.% Ti), 10.22 (0.030 wt.% Ti), and 11.83 (0.050 wt.% Ti) μm for the four steels, in order of increasing Ti content, respectively. Transmission electron microscopy was conducted to observe the fine carbides. The strength and impact properties of the steel containing 0.010 wt.% Ti were improved, and the ductile-to-brittle-transition temperature was reduced to −70.5 °C. The tensile strength and impact toughness of the steel with 0.050 wt.% Ti were significantly reduced due to the coarsening of both the inclusions and grain size, as well as the precipitation of large TiN inclusions. The RAFM steel with approximately 0.015 wt.% Y and 0.010 wt.% Ti exhibited an optimized combination of microstructures, tensile properties, and impact properties among the four steels.
Highlights
Reduced activation ferritic martensitic (RAFM) steels have been widely investigated as potential candidates for structural materials in future nuclear fusion reactors [1,2]
Lee [10] and Kim [11] investigated the effects of Ti on the microstructural stability and tensile properties of the RAFM steel and noted that the yield strength of the Ti-added RAFM steel (Ti–RAFM) is high because of additional precipitation hardening from the
The aforementioned studies only dealt with a single element (Y or Ti)
Summary
Reduced activation ferritic martensitic (RAFM) steels have been widely investigated as potential candidates for structural materials in future nuclear fusion reactors [1,2]. Lee [10] and Kim [11] investigated the effects of Ti on the microstructural stability and tensile properties of the RAFM steel and noted that the yield strength of the Ti-added RAFM steel (Ti–RAFM) is high because of additional precipitation hardening from the. Few reports exist on RAFM steel with Y and Ti and the formation mechanism of the inclusions during the smelting process [8,9,12]. Understanding the role of Y and Ti in the evolution of inclusions as well as the microstructure and properties of the RAFM steel is necessary. This study aimed to elucidate the oxide particle formation mechanism in steel with different Y and Ti contents and study the effects of the inclusions on the mechanical properties of 9Cr-RAFM steel
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