Abstract
The effect of Ni on microstructure, elemental partition behavior, γ′ phase solvus temperature, lattice misfit between γ and γ′ phases, and mechanical properties of the Co-8Ti-11V-xNi alloys was investigated. The result shows that the lattice misfit in the alloys decreases from 0.74% to 0.61% as the Ni content increases from 0 to 10%, and the average sizes of the cuboidal γ′ phase were measured to be 312.10 nm, 112.86 nm, and 141.84 nm for the Co-8Ti-11V, Co-8Ti-11V-5Ni, and Co-8Ti-11V-10Ni, respectively. Ti, V, and Ni exhibit a slight tendency to partition into the γ′ phase, while Co shows a slight tendency to partition into the γ phase. The solvus temperatures of the γ′ phase were measured to be 1167°C, 1114°C, and 1108°C for the Co-8Ti-11V, Co-8Ti-11V-5Ni, and Co-8Ti-11V-10Ni alloys, respectively, by using differential scanning calorimetry (DSC). Moreover, the yield strength and ultimate strength of the Co-8Ti-11V, Co-8Ti-11V-5Ni, and Co-8Ti-11V-10Ni alloys were investigated, and the yield strength and ultimate strength of the 10Ni alloy were highest, at 219 MPa and 240 MPa. After compression at 1000°C, the dislocations cannot effectively shear the γ′ phase in the 0Ni and 10Ni alloys, resulting in a relatively high compressive strength of the 0Ni and 10Ni alloys. However, the γ′ phase of the 5Ni alloy is no longer visible, and its strength is the lowest.
Highlights
The superalloys, which are normally used in the industrial environments with elevated temperature and high pressure, can be divided into three classes named as nickel-based, cobalt-based, and iron-based superalloys [1, 2]
The results indicate that adding Ni content can retard the coarsening behavior of the γ′ phase
The results show that the Ti element partitioning into the γ′ phase was restrained for the 5Ni alloy and the Ti element partitioning into the γ′ phase was promoted for the 10Ni alloy
Summary
The superalloys, which are normally used in the industrial environments with elevated temperature and high pressure, can be divided into three classes named as nickel-based, cobalt-based, and iron-based superalloys [1, 2]. It is believed that the lack of GCP phases in traditional carbide-strengthened Co-based superalloys leads to their inferior high-temperature strengths [6,7,8,9,10,11,12,13]. Some researchers found the γ′ phase in the Co-Al-W ternary alloy was metastable [15] It needs to incorporate some alloying elements like Ni, Ti, B, and Cr to improve thermal stability [16,17,18]. Most research studies have focused on replacing some of the W with various refractory elements, such as Ta and Nb [14, 23], which can stabilize the γ′ phase, increase the γ′ phase solvus temperature, and improve the high temperature strength.
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