In situ X-ray diffraction and thermal simulation of material extrusion additive manufacturing of polymer
In situ X-ray diffraction and thermal simulation of material extrusion additive manufacturing of polymer
Material extrusion additive manufacturing (AM) has gradually become a dominant technology for the fabrication of complex-designed thermoplastic polymers that require a higher level of control over the morphological and mechanical properties. The polymer internal crystal structure formed during the AM process can present significant impacts on the mechanical properties of the individual filaments, as well as the whole structure. Currently, limited details are known about the crystal structure evolution during the material extrusion AM processes of polymers. A novel in situ synchrotron X-ray diffraction (XRD) experimental configuration was developed enabling us to capture the material evolution data throughout the extrusion AM process. The in situ time-resolved data was analysed to reveal nucleation and crystallization sequences during the continuous deposition, with the aid of both complimentary numerical simulations and post-process (ex situ) characterisations. The thermal simulations supported the prediction of the filament temperature profile over time and location during the AM process, while ex situ characterisations validated the correlation between polymer crystallinity (resulting from printing parameters) and corresponding mechanical properties. The results obtained from varied process parameters suggest that the processing temperature has a dominant influence on the crystal microstructure evolution compared to the deposition velocity. A lower processing temperature just above the melting temperature permitted favourable crystallization conditions. The overall analysis demonstrated prospects for enhancing polymer AM, to engineering mechanically hierarchical structures through correlative investigations.
Additive manufacturing, In situ X-ray diffraction, Material extrusion, Polymer
Wang, Weiguang
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Hou, Yanhao
082d81da-35ae-4632-8e53-94a6b3a2fe99
Yang, Jiong
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Yan, Zhengyu
f751de7d-a2f0-48ad-b5af-c37296dc04ab
Liu, Fengyuan
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Vyas, Cian
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Mirihanage, Wajira
fc929099-b7ea-4127-886e-07f4ddc05b42
Bartolo, Paulo
2c085472-871d-4ac1-8767-23e5fe9703cf
18 August 2024
Wang, Weiguang
0cc699c0-e7b3-49d0-8c84-1e9d63f747d8
Hou, Yanhao
082d81da-35ae-4632-8e53-94a6b3a2fe99
Yang, Jiong
69a8f107-4f74-495f-9944-f15e966ef87c
Yan, Zhengyu
f751de7d-a2f0-48ad-b5af-c37296dc04ab
Liu, Fengyuan
34504cf0-2b1a-4b0b-afe3-6e6e7f86a193
Vyas, Cian
d6dde9b5-3361-4052-9aa4-6ef750b7bd36
Mirihanage, Wajira
fc929099-b7ea-4127-886e-07f4ddc05b42
Bartolo, Paulo
2c085472-871d-4ac1-8767-23e5fe9703cf
Wang, Weiguang, Hou, Yanhao, Yang, Jiong, Yan, Zhengyu, Liu, Fengyuan, Vyas, Cian, Mirihanage, Wajira and Bartolo, Paulo
(2024)
In situ X-ray diffraction and thermal simulation of material extrusion additive manufacturing of polymer.
Materials & Design, 245, [113255].
(doi:10.1016/j.matdes.2024.113255).
Abstract
Material extrusion additive manufacturing (AM) has gradually become a dominant technology for the fabrication of complex-designed thermoplastic polymers that require a higher level of control over the morphological and mechanical properties. The polymer internal crystal structure formed during the AM process can present significant impacts on the mechanical properties of the individual filaments, as well as the whole structure. Currently, limited details are known about the crystal structure evolution during the material extrusion AM processes of polymers. A novel in situ synchrotron X-ray diffraction (XRD) experimental configuration was developed enabling us to capture the material evolution data throughout the extrusion AM process. The in situ time-resolved data was analysed to reveal nucleation and crystallization sequences during the continuous deposition, with the aid of both complimentary numerical simulations and post-process (ex situ) characterisations. The thermal simulations supported the prediction of the filament temperature profile over time and location during the AM process, while ex situ characterisations validated the correlation between polymer crystallinity (resulting from printing parameters) and corresponding mechanical properties. The results obtained from varied process parameters suggest that the processing temperature has a dominant influence on the crystal microstructure evolution compared to the deposition velocity. A lower processing temperature just above the melting temperature permitted favourable crystallization conditions. The overall analysis demonstrated prospects for enhancing polymer AM, to engineering mechanically hierarchical structures through correlative investigations.
Text
1-s2.0-S0264127524006300-main
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More information
Accepted/In Press date: 14 August 2024
e-pub ahead of print date: 15 August 2024
Published date: 18 August 2024
Keywords:
Additive manufacturing, In situ X-ray diffraction, Material extrusion, Polymer
Identifiers
Local EPrints ID: 498478
URI: http://eprints.soton.ac.uk/id/eprint/498478
ISSN: 0261-3069
PURE UUID: a715953f-f714-4ae9-819c-9a6f16ab47e9
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Date deposited: 19 Feb 2025 18:12
Last modified: 20 Feb 2025 03:14
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Contributors
Author:
Weiguang Wang
Author:
Yanhao Hou
Author:
Jiong Yang
Author:
Zhengyu Yan
Author:
Fengyuan Liu
Author:
Cian Vyas
Author:
Wajira Mirihanage
Author:
Paulo Bartolo
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