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Experimental investigation of additive manufacturing using a hot-wire plasma welding process on titanium parts
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Document Title
Experimental investigation of additive manufacturing using a hot-wire plasma welding process on titanium parts
Author
Poolperm P., Nakkiew W., Naksuk N.
Name from Authors Collection
Scopus Author ID
8346360800
Affiliations
Department of Industrial Engineering, Faculty of Engineering, Chiang Mai University, Chiang Mai, 50200, Thailand; Advanced Manufacturing Technology Research Center (AMTech), Department of Industrial Engineering, Faculty of Engineering, Chiang Mai University, Chiang Mai, 50200, Thailand; Department of Industrial Engineering, Faculty of Engineering, Chiang Mai University, Chiang Mai, 50200, Thailand; Automation for Material Processing Research Team, Material Processing and Manufacturing Automation Research Group, National Metal and Materials Technology Center (MTEC), National Science and Technology Development Agency (NSTDA), Thailand Science Park, Pathum Thani, 12120, Thailand
Type
Article
Source Title
Materials
ISSN
19961944
Year
2021
Volume
14
Issue
5
Page
43831
Open Access
All Open Access, Gold
Publisher
MDPI AG
DOI
10.3390/ma14051270
Format
Abstract
In this paper, we propose hot-wire plasma welding, a combination of the plasma welding (PAW) process and the hot-wire process in the additive manufacturing (AM) process. Generally, in plasma welding for AM processes, the deposit grain size increases, and the hardness decreases as the wall height increases. The coarse microstructure, along with the large grain size, corresponds to an increase in deposit temperature, which leads to poorer mechanical properties. At the same time, the hot-wire laser process seems to contain an overly high interstitial amount of oxygen and nitro-gen. With an increasing emphasis on sustainability, the hot-wire plasma welding process offers significant advantages: deeper and narrow penetration than the cold-wire plasma welding, improved design flexibility, large deposition rates, and low dilution percentages. Thus, the hot-wire plasma welding process was investigated in this work. The wire used in the welding process was a titanium American Welding Society (AMS) 4951F (Grade 2) welding wire (diameter 1.6 mm), in which the welding was recorded in real time with a charge-coupled device camera (CCD camera). We studied three parameters of the hot-wire plasma welding process: (1) the welding speed, (2) wire current, and (3) wire feeding speed. The mechanical and physical properties (porosity, Vickers hardness, microstructure, and tensile strength) were examined. It was found that the number of layers, the length and width of the molten pool, and the width of the deposited bead increased, while the height of the layer increased, and the hot-wire current played an important role in the deposition. In addition, these results were benchmarked against specimens created by a hot-wire plasma weld-ing/wire-based additive manufacturing process with an intention to develop the hot-wire PAW process as a potential alternative in the additive manufacturing industry. © 2021 by the authors. Licensee MDPI, Basel, Switzerland.
Keyword
Additive manufacturing | Hot-wire | Mechanical properties | Plasma welding | Titanium alloy | Wire feed
Industrial Classification
Knowledge Taxonomy Level 1
Knowledge Taxonomy Level 2
Knowledge Taxonomy Level 3
Funding Sponsor
Chiang Mai University; National Science and Technology Development Agency; Thailand Graduate Institute of Science and Technology
License
N/A
Rights
N/A
Publication Source
Scopus
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Experimental investigation of additive manufacturing using a hot-wire plasma welding process on titanium partsDownload