An investigation into Ti-22Al-25Nb in-situ fabricated by electron beam freeform fabrication with an innovative twin-wire parallel feeding method

Wire-based in-situ additive manufacturing technology realizes the integration of material preparation and part manufacturing with high deposition efficiency and material utilization. However, the complicated two-droplet transfer and fast cooling rate of the molten pool make this technology face the...

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Bibliographic Details
Published in:Additive manufacturing 2022-02, Vol.50, p.102552, Article 102552
Main Authors: Li, Zixiang, Cui, Yinan, Wang, Li, Zhang, Haoyu, Liang, Zhiyue, Liu, Changmeng, Du, Dong
Format: Article
Language:English
Subjects:
Mechanical properties
Microstructure
Ti-22Al-25Nb intermetallic
Twin-wire electron beam freeform fabrication
Twin-wire parallel feeding
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Summary:Wire-based in-situ additive manufacturing technology realizes the integration of material preparation and part manufacturing with high deposition efficiency and material utilization. However, the complicated two-droplet transfer and fast cooling rate of the molten pool make this technology face the challenges of poor stability, repeatability, forming accuracy, and composition macro-segregation. In this work, an innovative wire feeding method, named twin-wire “parallel” feeding (TWPF), combined with the high-frequency of electron beam scanning for molten pool stirring was adopted to mitigate these issues. The multi-element Ti-22Al-25Nb (at%) intermetallic is taken as the target alloy, due to its huge application prospects in the aerospace field but great difficulties in traditional processing methods. Results show that the TWPF method can provide a stable and repeatable double-droplet transfer mode. Ti-22Al-25Nb parts with high forming accuracy and relatively good mechanical properties can be successfully fabricated. In addition, the two-droplet transfer, Al evaporation quantity, pore, and microstructure evolution mechanism are all systematically studied. This work is of great significance to solve the commonly existing challenges in wire-based in-situ AM technology, as well as to shorten the processing cycle and promote the wider application of the Ti-22Al-25Nb component. •Ti-22Al-25Nb (at%) alloy are in-situ fabricated by twin-wire electron beam freeform fabrication.•A twin-wire parallel feeding device was used to overcome the problem of poor stability, repeatability and forming accuracy.•Electron beam scanning was firstly adopted to promote mass transfer and metallurgical reaction.•The mechanism of the double-droplet transition and porosity evolution are revealed.•Microstructure evolution and corresponding mechanical properties were studied.
ISSN:2214-8604
2214-7810
DOI:10.1016/j.addma.2021.102552