Relationship between associated acoustic emission and crack position during directed energy deposition of a metal matrix composite
Relationship between associated acoustic emission and crack position during directed energy deposition of a metal matrix composite
Laser-based directed energy deposition (DED) is a versatile additive manufacturing (AM) technique capable of depositing high-quality coatings, repairing components, and fabricating complex metal matrix composite structures. The DED process, however, is prone to defects, particularly cracking, due to dynamic thermal gradients and residual stresses inherent in the process. Conventional monitoring methods, such as optical and thermal imaging, primarily focus on surface defects and often fail to detect subsurface cracks, that can significantly affect the structural integrity of fabricated structures. This study presents a novel acoustic emission (AE)-based monitoring method capable of detecting and quantifying both surface and subsurface cracks during the DED process. By exploiting the exponential decay of the unique acoustic emissions due to DED, the second-order derivative of the acoustic signal is invariant, thereby filtering extraneous noise sources and hence yielding a robust methodology for relating DED-based cracking initiation times and their associated positions. The results reveal that crack formation timing and location vary significantly with energy density. The novel techniques were used to show that higher energy density leads to slower cooling and solidification rates, resulting in delayed crack formation and detection further behind the laser beam's position.
Acoustic emission, Crack detection, Directed energy deposition
177-190
Ansari, Md Jonaet
4afb29de-94dc-493c-96aa-1f7b6243e76a
Roccisano, Anthony
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Arcondoulis, Elias J.G.
4e0c8bdf-1810-4d4e-b8e8-9ba9ccd6b746
Schulz, Christiane
bec72896-be0e-4bac-8ec8-7fefc2dba459
Schläfer, Thomas
6df233b6-2ab6-419b-9fc7-f50c17160d96
Hall, Colin
1a3ae3fd-6de2-4143-8a39-86449bd4fc41
19 May 2025
Ansari, Md Jonaet
4afb29de-94dc-493c-96aa-1f7b6243e76a
Roccisano, Anthony
8d199bf0-4e0d-4226-92e8-2ed1bfa5bb07
Arcondoulis, Elias J.G.
4e0c8bdf-1810-4d4e-b8e8-9ba9ccd6b746
Schulz, Christiane
bec72896-be0e-4bac-8ec8-7fefc2dba459
Schläfer, Thomas
6df233b6-2ab6-419b-9fc7-f50c17160d96
Hall, Colin
1a3ae3fd-6de2-4143-8a39-86449bd4fc41
Ansari, Md Jonaet, Roccisano, Anthony, Arcondoulis, Elias J.G., Schulz, Christiane, Schläfer, Thomas and Hall, Colin
(2025)
Relationship between associated acoustic emission and crack position during directed energy deposition of a metal matrix composite.
Journal of Manufacturing Processes, 147, .
(doi:10.1016/j.jmapro.2025.05.015).
Abstract
Laser-based directed energy deposition (DED) is a versatile additive manufacturing (AM) technique capable of depositing high-quality coatings, repairing components, and fabricating complex metal matrix composite structures. The DED process, however, is prone to defects, particularly cracking, due to dynamic thermal gradients and residual stresses inherent in the process. Conventional monitoring methods, such as optical and thermal imaging, primarily focus on surface defects and often fail to detect subsurface cracks, that can significantly affect the structural integrity of fabricated structures. This study presents a novel acoustic emission (AE)-based monitoring method capable of detecting and quantifying both surface and subsurface cracks during the DED process. By exploiting the exponential decay of the unique acoustic emissions due to DED, the second-order derivative of the acoustic signal is invariant, thereby filtering extraneous noise sources and hence yielding a robust methodology for relating DED-based cracking initiation times and their associated positions. The results reveal that crack formation timing and location vary significantly with energy density. The novel techniques were used to show that higher energy density leads to slower cooling and solidification rates, resulting in delayed crack formation and detection further behind the laser beam's position.
Text
1-s2.0-S1526612525005687-main
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More information
Accepted/In Press date: 13 May 2025
e-pub ahead of print date: 19 May 2025
Published date: 19 May 2025
Keywords:
Acoustic emission, Crack detection, Directed energy deposition
Identifiers
Local EPrints ID: 506968
URI: http://eprints.soton.ac.uk/id/eprint/506968
PURE UUID: 10f0d9c5-ca0f-488d-857d-f63f35e50be5
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Date deposited: 24 Nov 2025 17:49
Last modified: 25 Nov 2025 03:20
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Contributors
Author:
Md Jonaet Ansari
Author:
Anthony Roccisano
Author:
Elias J.G. Arcondoulis
Author:
Christiane Schulz
Author:
Thomas Schläfer
Author:
Colin Hall
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