Enhanced strength-ductility synergy in hybrid additive manufactured Ti–6Al–4V via interlayer friction stir processing assisted laser-directed energy deposition

Enhanced strength-ductility synergy in hybrid additive manufactured Ti–6Al–4V via interlayer friction stir processing assisted laser-directed energy deposition

The strengthening and toughening of AM-ed Ti–6Al–4V alloy remain persistent challenges in engineering applications. This study proposes a hybrid additive manufacturing (HAM) strategy integrating low-energy density laser-directed energy deposition (L-DED) with a reduced molten pool diameter (∼φ1.5 mm...

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Bibliographic Details
Main Authors: Han Xie, Siyu Zhou, Baosheng Guan, Yuhang Ren, Zhonggang Sun, Guoqing Dai, Guang Yang
Format: Article
Language:English
Published: Taylor & Francis Group 2025-12-01
Series:Virtual and Physical Prototyping
Subjects:
Laser-direction energy deposition
friction stir processing
Ti–6Al–4V alloy
mechanical property
microstructure evolution
Online Access:https://www.tandfonline.com/doi/10.1080/17452759.2025.2499935
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Summary:The strengthening and toughening of AM-ed Ti–6Al–4V alloy remain persistent challenges in engineering applications. This study proposes a hybrid additive manufacturing (HAM) strategy integrating low-energy density laser-directed energy deposition (L-DED) with a reduced molten pool diameter (∼φ1.5 mm) and friction stir processing (FSP). The microstructure evolution during hybrid additive manufacturing was investigated through multiscale characterisation and thermal field simulation. The results show that the L-DED-produced sample exhibits near-equiaxed grains (average width: ∼333 μm) comprising refined acicular α and martensitic α′ phases. In contrast, the HAM-processed hybrid zone demonstrates exceptional thermal stability during subsequent thermal cycling, maintaining an ultrafine-grained structure (average size: 5.04 μm) dominated by α + β lamellar structure and globular α phases. The HAM samples achieve a strength-ductility synergy with an ultimate tensile strength of ∼974.8 MPa and elongation of ∼20.4%, demonstrating the efficacy of this hybrid approach. This work establishes a viable pathway for fabricating high-performance titanium alloy components via hybrid-optimised additive manufacturing.
ISSN:1745-2759
1745-2767

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