TPWJ, 2020, #2, 9-15 pages
Impact of tig welding on the structure and mechanical properties of joints of pseudo-β-titanium alloy
S.V. Akhonin, V.Yu. Bilous, R.V. Selin and I.K. Petrychenko
E.O. Paton Electric Welding Institute of the NAS of Ukraine
11 Kazymyr Malevych Str., 03150, Kyiv, Ukraine. E-mail: firstname.lastname@example.org
Structural pseudo-β-titanium alloys attract a lot of interest in fabrication of complex constructions for critical purposes.
This alloy class includes alloys with the structure represented by one β-phase after hardening or normalizing from the
β-region. The alloy weldability is an important factor at application of pseudo-β-titanium alloys in aircraft and rocket
engineering. By their mechanical characteristics, the welded joints of modern pseudo-β titanium alloys should match
the level of base metal mechanical properties. In this work, the impact of argon arc welding, as well as further heat
treatment on the phase composition, structure and mechanical properties of welded joints of pseudo-β-titanium alloy
was studied. It was established that as a result of the impact of thermal cycle of welding predominantly β-phase in the
quantity of 77 % is recorded in the weld metal of joints of pseudo-β alloy VT19. Application of VT1-00sv filler wire
enhances the quantity of dispersed α-phase particles and reduces the quantity of β-phase in the weld metal to 60 %, respectively.
Annealing results in formation of a uniform, homogeneous finely-dispersed two-phase (α+β)-structure with
tensile strength values of welded joints on the level of σt = 1010 MPa, that exceed the respective base metal values by
12 %. 16 Ref., 5 Tables, 8 Figures.
pseudo-β titanium alloys, TIG welding, mechanical properties
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