The effect of ultrasonic impact treatment on deformation and fracture of electron beam additive manufactured Ti-6Al-4V under uniaxial tension

“…Such a structure is typical for the Ti-6Al-4V titanium alloy obtained by additive technologies. [15][16][17][18][19][20] This structure is due to the directional heat dissipation during crystallization of the melt pool resulting in epitaxial growth of columnar primary β grains, the size of which is determined by the cooling rate of the melt pool. When the temperature of the crystallized layer is below %990 °C, the primary β-grains undergo a polymorphic β!α transformation, which develops according to the diffusion-free martensitic mechanism with the formation of a needle/plate martensitic α 0 phase.…”

“…The 3D‐printed parallelepiped‐shaped billets with the dimensions of 25 mm × 25 mm × 90 mm were successfully produced using electron‐beam melting of the Grade 5 (Ti–6Al–4V) wire of diameter 1.6 mm at the wire EBAM facility (ISPMS SB RAS, Tomsk, Russia). [ 20 ] Chemical compositions of the Grade 5 wire, assessed using a “Thermo Scientific Niton XL3t GOLDD” X‐ray fluorescence (XRF) analyzer (ThermoFisher Scientific, USA), is given in Table 1 . Wire melting was carried out in vacuum of 1.3 × 10 −3 Pa by the electron gun with plasma cathode at accelerating voltage of 30 kV.…”

“…It is worth noting that the presence of individual dislocations and extinction contours in the light-field TEM images indicates the The results presented here are in a good agreement with earlier electron microscopic studies of the Ti-6Al-4V alloy produced by wire-feed EBAM. [20] Figure 4 shows the results of electron backscatter diffraction (EBSD) analysis of the Ti-6Al-4V alloy in the initial 3D-printed state. The EBSD images in this state demonstrate a lamellar microstructure combined into large clusters with predominantly low-angle misorientation of the grain boundaries.…”

“…[19] The microstructure of the Ti-6Al-4V alloy samples produced by electron-beam wire additive manufacturing exhibits typical feature of columnar prior-β grains, within which the α/α 0 -Ti laths are observed that are collected in packages and separated by interlayers of residual β phase. [20] In addition, the 3D-printed Ti alloys manufactured by this technology are often characterized by a low volume fraction of residual β phase due to rapid solidification of the melt pool and multiple phase transformations resulting from repeated thermal cycles. [17] At the same time, the strength properties of the EBAM Ti-6Al-4V samples are often significantly lower than the strength properties of the Ti-6Al-4V samples obtained both by laser or electron-beam melting of powder feedstock and by traditional production methods (casting, stamping, etc.).…”

Microstructural Transformation and Enhanced Strength of Wire‐Feed Electron‐Beam Additive Manufactured Ti–6Al–4V Alloy Induced by High‐Pressure Torsion

“…Such a structure is typical for the Ti-6Al-4V titanium alloy obtained by additive technologies. [15][16][17][18][19][20] This structure is due to the directional heat dissipation during crystallization of the melt pool resulting in epitaxial growth of columnar primary β grains, the size of which is determined by the cooling rate of the melt pool. When the temperature of the crystallized layer is below %990 °C, the primary β-grains undergo a polymorphic β!α transformation, which develops according to the diffusion-free martensitic mechanism with the formation of a needle/plate martensitic α 0 phase.…”

“…The 3D‐printed parallelepiped‐shaped billets with the dimensions of 25 mm × 25 mm × 90 mm were successfully produced using electron‐beam melting of the Grade 5 (Ti–6Al–4V) wire of diameter 1.6 mm at the wire EBAM facility (ISPMS SB RAS, Tomsk, Russia). [ 20 ] Chemical compositions of the Grade 5 wire, assessed using a “Thermo Scientific Niton XL3t GOLDD” X‐ray fluorescence (XRF) analyzer (ThermoFisher Scientific, USA), is given in Table 1 . Wire melting was carried out in vacuum of 1.3 × 10 −3 Pa by the electron gun with plasma cathode at accelerating voltage of 30 kV.…”

“…It is worth noting that the presence of individual dislocations and extinction contours in the light-field TEM images indicates the The results presented here are in a good agreement with earlier electron microscopic studies of the Ti-6Al-4V alloy produced by wire-feed EBAM. [20] Figure 4 shows the results of electron backscatter diffraction (EBSD) analysis of the Ti-6Al-4V alloy in the initial 3D-printed state. The EBSD images in this state demonstrate a lamellar microstructure combined into large clusters with predominantly low-angle misorientation of the grain boundaries.…”

“…[19] The microstructure of the Ti-6Al-4V alloy samples produced by electron-beam wire additive manufacturing exhibits typical feature of columnar prior-β grains, within which the α/α 0 -Ti laths are observed that are collected in packages and separated by interlayers of residual β phase. [20] In addition, the 3D-printed Ti alloys manufactured by this technology are often characterized by a low volume fraction of residual β phase due to rapid solidification of the melt pool and multiple phase transformations resulting from repeated thermal cycles. [17] At the same time, the strength properties of the EBAM Ti-6Al-4V samples are often significantly lower than the strength properties of the Ti-6Al-4V samples obtained both by laser or electron-beam melting of powder feedstock and by traditional production methods (casting, stamping, etc.).…”

Microstructural Transformation and Enhanced Strength of Wire‐Feed Electron‐Beam Additive Manufactured Ti–6Al–4V Alloy Induced by High‐Pressure Torsion

“…The authors of the article, using MD simulation, demonstrated the development of reversible  phase transformations in the Ti-6Al-4V titanium alloy during scratch testing, which made it possible to explain the experimentally observed recovery of a scratch [17][18][19]. It has been found that the migration of the twin boundaries in the titanium crystallite under tension is also governed by the development of reversible  transformations [20]. However, it remains to be seen how the significant fragmentation and disorientation of the crystal lattice in the ultrasonically treated surface layer affect the development of the strain-induced phase transformations in the Ti-6Al-4V alloy.…”

Transformations of the Microstructure and Phase Compositions of Titanium Alloys during Ultrasonic Impact Treatment Part II: Ti-6Al-4V Titanium Alloy

Electron beam metal additive manufacturing: Defects formation and in-process control