Abstract
As a new near β titanium alloy designed by NIN (the Northwest Institute for Non-ferrous Metal Research), the phase transformations of the β-quenched Ti-5Al-3Mo-3V-2Cr-2Zr-1Nb-1Fe alloy during continuous heating have been investigated by means of in situ dilatometer test coupled with X-ray diffraction (XRD), scanning electron microscopy (SEM) and transmission electron microscopy (TEM). The β-quenched Ti-5321 alloy with an initial structure consisting of metastable β phase and dense ωath, which was subjected to continuous heating treatment and underwent the following transformations: β + ωath→ β + ωiso→ β + α+ ωiso→ β + α. The ωisophase precipitated at 300 ℃ with a ~3 nm ellipsoidal morphology. When continuously heated to 390 ℃, a coexistence of both ωiso and α phase was observed in the β matrix, the platelet-like α phase closely nucleating at the ω/β interface with ~1 nm in width and ~8 nm in length. The α phase subsequently developed into lamellar structure when heated to higher temperatures, with a width of ~20 nm at 570 ℃ and ~85 nm at 690 ℃ respectively. Meanwhile, these α laths were uniformly distributed and composed of two distinct orientations within the microstructure. Finally, it can be found that the α morphology is directly associated with the formation and decomposition of the metastable ωisophase which may lead to the homogeneous and fine distribution of α precipitates. Based on the study of phase transformations occurring during the continuous heating process presented in this paper, an efficient guidance to engineer the microstructures and mechanical properties of this new near β titanium alloy was offered.
Highlights
Titanium alloys with high strength and toughness fill an important role in the aerospace industry, like Ti-10V-2Fe-3Al, Ti-3Al-8V-6Cr-4Zr-4Mo, Ti-5Al-5V-5Mo-3Cr-0.5Fe are known to be in steady production[1]
It is known that ω phase result in drastic embrittlement, but when aged at proper temperatures, fine scale α phase precipitation in titanium alloys can leading to extremely high strength
The phase transformations in the β-quenched Ti-5321 alloy during continuous heating have been investigated by means of in situ dilatometer test coupled with X-ray diffraction (XRD), scanning electron microscopy (SEM) and transmission electron microscopy (TEM)
Summary
Titanium alloys with high strength and toughness fill an important role in the aerospace industry, like Ti-10V-2Fe-3Al, Ti-3Al-8V-6Cr-4Zr-4Mo, Ti-5Al-5V-5Mo-3Cr-0.5Fe are known to be in steady production[1]. It is known that ω phase result in drastic embrittlement, but when aged at proper temperatures, fine scale α phase precipitation in titanium alloys can leading to extremely high strength. This metastable ω phase has intrigued researchers’ interests for many years, on the one hand, its mechanism of formation is complex; on the other, it’s a vital phase to tailor the multiphase microstructures of titanium alloys for various specific applications. The phase transformation of ω phase and α phases were systematically analysed This can offer a guidance to engineer the α phase in this new near β titanium alloys in the aging process and control mechanical properties. The mechanism available for other similar near β titanium alloys, such as Ti-5553 alloy and so on
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