Abstract
The microstructure, isothermal oxidation, and hardness of the Nb-23Ti-5Si-5Al-5Hf-5V-2Cr-2Sn alloy and the hardness and Young’s moduli of elasticity of its Nbss and Nb5Si3 were studied. The alloy was selected using the niobium intermetallic composite elaboration (NICE) alloy design methodology. There was macrosegregation of Ti and Si in the cast alloy. The Nbss, αNb5Si3, γNb5Si3, and HfO2 phases were present in the as-cast or heat-treated alloy plus TiN in the near-the-surface areas of the latter. The vol.% of Nbss was about 80%. There were Ti- and Ti-and-Hf-rich areas in the solid solution and the 5-3 silicide, respectively, and there was a lamellar microstructure of these two phases. The V partitioned to the Nbss, where the solubilities of Al, Cr, Hf, and V increased with increasing Ti concentration. At 700, 800, and 900 °C, the alloy did not suffer from catastrophic pest oxidation; it followed parabolic oxidation kinetics in the former two temperatures and linear oxidation kinetics in the latter, where its mass change was the lowest compared with other Sn-containing alloys. An Sn-rich layer formed in the interface between the scale and the substrate, which consisted of the Nb3Sn and Nb6Sn5 compounds at 900 °C. The latter compound was not contaminated with oxygen. Both the Nbss and Nb5Si3 were contaminated with oxygen, with the former contaminated more severely than the latter. The bulk of the alloy was also contaminated with oxygen. The alloying of the Nbss with Sn increased its elastic modulus compared with Sn-free solid solutions. The hardness of the alloy, its Nbss, and its specific room temperature strength compared favourably with many refractory metal-complex-concentrated alloys (RCCAs). The agreement of the predictions of NICE with the experimental results was satisfactory.
Highlights
Interest in RM(Nb)ICs, i.e., refractory metal (RM) intermetallic composites based on Nb, known as Nb-silicide-based alloys or Nb in situ composites, as potential metallic ultra-high temperature materials (UHTM) to replace Ni-based superalloys in hightemperature structural applications in aero engines, has arisen from early research on binary Nb-Si alloys and experimental data that showed that such RMICs could offer an attractive combination of high temperature strength, creep resistance, and room temperature fracture toughness
Isothermal oxidation, and hardness of the Nb-23Ti-5Si5Al-5Hf-5V-2Cr-2Sn alloy and the hardness and Young’s moduli of elasticity of its Nb solid solution (Nbss) and Nb5Si3
The V partitioned to the Nbss, where its solubility increased with increasing Ti concentration
Summary
Interest in RM(Nb)ICs, i.e., refractory metal (RM) intermetallic composites based on Nb, known as Nb-silicide-based alloys or Nb in situ composites, as potential metallic ultra-high temperature materials (UHTM) to replace Ni-based superalloys in hightemperature structural applications in aero engines, has arisen from early research on binary Nb-Si alloys and experimental data that showed that such RMICs could offer an attractive combination of high temperature strength, creep resistance, and room temperature fracture toughness (e.g., see [1]) Another contributing factor was the phase equilibria of the binary system [2] that makes it possible to cast in situ composites consisting of a RM terminal solid solution, namely, the bcc Nb solid solution (Nbss), and the creep-resistant tetragonal Nb5Si3 silicide. Even with RM alloying additions, e.g., Mo, it is possible to have RM(Nb)ICs with densities as low as 6.55 g/cm3 [6] compared with the typical densities of about 9 g/cm for Ni-based superalloys
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
