Laser directed energy deposition additive manufacturing using friction stir channelling extruded wire
Laser directed energy deposition additive manufacturing using friction stir channelling extruded wire
This paper investigates a new ‘forged’ wire additive manufacturing processing, in which the metal wire is produced as a by-product from stationary shoulder friction stir channelling (SS-FSC) under the severe plastic deformation mechanism (known as CoreFlow®), and then used as the feedstock in directed energy deposition with a laser beam and wire feedstock (DED-LB/w) additive manufacturing. For the first time, the ‘by-products’ produced in the SS-FSC process, which are ‘forged’ 6082 aluminium alloy wire, were tested with built-tracks using DED-LB/w. Process mapping was built to demarcate the melting states, including the stable, dripping, and incomplete melting regimes, over a wide range of laser energy densities (92 to 303 kJ·s·g −1·cm −2). Metallurgy tests were also conducted to reveal the evolution of the microstructure and defect formation of the deposited tracks. It was found that: (i) Stable deposition with a grain size of 9−20μm can be achieved with optimised processing parameters, i.e., energy density 243kJ·s·g −1·cm −2 with a laser power 3.8kW, a scanning speed 0.8cm·s −1 and a wire feed rate 2.0cm·s −1; (ii) The substructure morphology is gradually transitioned from columnar at the track bottom to cellular (8.9±1.8μm) at the top, driven by an increased cooling rate; and (iii) The built track porosity is mainly composed of gas pores that are small (equivalent diameter of 20−50μm) and spherical, primarily resulting from the ambient gas, the SS-FSC extruded wire oxides and contaminations. The study supports resource-efficient, low-carbon manufacturing via reuse of by-products, in alignment with the Net Zero Strategy.
Additive manufacturing, Directed energy deposition with a laser beam and wire feedstock (DED-LB/w), Microstructure, Porosity defect, Process mapping, Stationary shoulder friction stir channelling (SS-FSC)
122-133
Chu, Yajie
c1c4ca21-cca6-4710-a3b3-788320297d97
Zhao, Xingjian
58a8bb85-92c9-4e89-b4af-43d57fbe865f
Sun, Wanting
27a42ef5-573d-4492-b7bb-878c7dc34277
Holdsworth, Sam
68bafefe-a82a-447d-a9de-9c597c9f5d1f
Guan, Dikai
d20c4acc-342a-43fa-a204-7283f0cc33bf
Huang, Yuze
25e8269b-b0f6-403c-ac18-21137eedaa9e
2 October 2025
Chu, Yajie
c1c4ca21-cca6-4710-a3b3-788320297d97
Zhao, Xingjian
58a8bb85-92c9-4e89-b4af-43d57fbe865f
Sun, Wanting
27a42ef5-573d-4492-b7bb-878c7dc34277
Holdsworth, Sam
68bafefe-a82a-447d-a9de-9c597c9f5d1f
Guan, Dikai
d20c4acc-342a-43fa-a204-7283f0cc33bf
Huang, Yuze
25e8269b-b0f6-403c-ac18-21137eedaa9e
Chu, Yajie, Zhao, Xingjian, Sun, Wanting, Holdsworth, Sam, Guan, Dikai and Huang, Yuze
(2025)
Laser directed energy deposition additive manufacturing using friction stir channelling extruded wire.
Journal of Manufacturing Process, 154, .
(doi:10.1016/j.jmapro.2025.09.060).
Abstract
This paper investigates a new ‘forged’ wire additive manufacturing processing, in which the metal wire is produced as a by-product from stationary shoulder friction stir channelling (SS-FSC) under the severe plastic deformation mechanism (known as CoreFlow®), and then used as the feedstock in directed energy deposition with a laser beam and wire feedstock (DED-LB/w) additive manufacturing. For the first time, the ‘by-products’ produced in the SS-FSC process, which are ‘forged’ 6082 aluminium alloy wire, were tested with built-tracks using DED-LB/w. Process mapping was built to demarcate the melting states, including the stable, dripping, and incomplete melting regimes, over a wide range of laser energy densities (92 to 303 kJ·s·g −1·cm −2). Metallurgy tests were also conducted to reveal the evolution of the microstructure and defect formation of the deposited tracks. It was found that: (i) Stable deposition with a grain size of 9−20μm can be achieved with optimised processing parameters, i.e., energy density 243kJ·s·g −1·cm −2 with a laser power 3.8kW, a scanning speed 0.8cm·s −1 and a wire feed rate 2.0cm·s −1; (ii) The substructure morphology is gradually transitioned from columnar at the track bottom to cellular (8.9±1.8μm) at the top, driven by an increased cooling rate; and (iii) The built track porosity is mainly composed of gas pores that are small (equivalent diameter of 20−50μm) and spherical, primarily resulting from the ambient gas, the SS-FSC extruded wire oxides and contaminations. The study supports resource-efficient, low-carbon manufacturing via reuse of by-products, in alignment with the Net Zero Strategy.
Text
1-s2.0-S1526612525010424-main
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More information
Accepted/In Press date: 22 September 2025
e-pub ahead of print date: 2 October 2025
Published date: 2 October 2025
Keywords:
Additive manufacturing, Directed energy deposition with a laser beam and wire feedstock (DED-LB/w), Microstructure, Porosity defect, Process mapping, Stationary shoulder friction stir channelling (SS-FSC)
Identifiers
Local EPrints ID: 506612
URI: http://eprints.soton.ac.uk/id/eprint/506612
ISSN: 1526-6125
PURE UUID: f2d6904f-e955-4d97-87b7-003d059708f8
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Date deposited: 12 Nov 2025 17:34
Last modified: 13 Nov 2025 03:04
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Contributors
Author:
Yajie Chu
Author:
Xingjian Zhao
Author:
Wanting Sun
Author:
Sam Holdsworth
Author:
Dikai Guan
Author:
Yuze Huang
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