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Optimized analytical approach for the detection of process-induced defects using acoustic emission during directed energy deposition process

Optimized analytical approach for the detection of process-induced defects using acoustic emission during directed energy deposition process
Optimized analytical approach for the detection of process-induced defects using acoustic emission during directed energy deposition process
Directed energy deposition (DED), an advanced additive manufacturing (AM) technique, facilitates the production of complex metallic and metal matrix composite structures. The DED process has continuously improved and offers numerous advantages for depositing high-quality coatings with excellent wear and corrosion resistance onto metallic surfaces. The dynamic nature of the process, however, introduces a significant risk of process-induced defects in manufactured parts. This study presents an optimized analytical approach using acoustic emission (AE) based defect detection technique to identify and quantify process-induced cracks during the DED process. The developed signal processing technique enabled the identification of actual AE events associated with cracking, distinguishing them from other disturbances. Experimental validation was conducted using manufactured parts that were longitudinally sectioned to determine the relationship of the crack location with the recorded acoustic signal. The demonstrated correlation of acoustic signatures with cracking illustrates the robustness of the AE technique to identify the process-induced cracking for quality assurance during the DED process.
2214-8604
Ansari, Md Jonaet
30e87232-88e9-4923-aace-5cfc027396f5
Arcondoulis, Elias JG
4e0c8bdf-1810-4d4e-b8e8-9ba9ccd6b746
Roccisano, Anthony
99094b34-fafd-4eea-bb09-21ecbd63305e
Schulz, Christiane
8b0098be-9b22-42fc-bd46-5fd88e1f3953
Schlaefer, Thomas
a21dc5bc-f4c2-48d9-b194-674e8318ab1d
Hall, Colin
d8f6200d-e143-4aa8-8835-6cf29e6b5fc0
Ansari, Md Jonaet
30e87232-88e9-4923-aace-5cfc027396f5
Arcondoulis, Elias JG
4e0c8bdf-1810-4d4e-b8e8-9ba9ccd6b746
Roccisano, Anthony
99094b34-fafd-4eea-bb09-21ecbd63305e
Schulz, Christiane
8b0098be-9b22-42fc-bd46-5fd88e1f3953
Schlaefer, Thomas
a21dc5bc-f4c2-48d9-b194-674e8318ab1d
Hall, Colin
d8f6200d-e143-4aa8-8835-6cf29e6b5fc0

Ansari, Md Jonaet, Arcondoulis, Elias JG, Roccisano, Anthony, Schulz, Christiane, Schlaefer, Thomas and Hall, Colin (2024) Optimized analytical approach for the detection of process-induced defects using acoustic emission during directed energy deposition process. Additive Manufacturing, 86, [104218]. (doi:10.1016/j.addma.2024.104218).

Record type: Article

Abstract

Directed energy deposition (DED), an advanced additive manufacturing (AM) technique, facilitates the production of complex metallic and metal matrix composite structures. The DED process has continuously improved and offers numerous advantages for depositing high-quality coatings with excellent wear and corrosion resistance onto metallic surfaces. The dynamic nature of the process, however, introduces a significant risk of process-induced defects in manufactured parts. This study presents an optimized analytical approach using acoustic emission (AE) based defect detection technique to identify and quantify process-induced cracks during the DED process. The developed signal processing technique enabled the identification of actual AE events associated with cracking, distinguishing them from other disturbances. Experimental validation was conducted using manufactured parts that were longitudinally sectioned to determine the relationship of the crack location with the recorded acoustic signal. The demonstrated correlation of acoustic signatures with cracking illustrates the robustness of the AE technique to identify the process-induced cracking for quality assurance during the DED process.

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More information

Published date: 25 April 2024

Identifiers

Local EPrints ID: 506115
URI: http://eprints.soton.ac.uk/id/eprint/506115
DOI: doi:10.1016/j.addma.2024.104218
ISSN: 2214-8604
PURE UUID: 128ddca4-78c3-44e3-941b-21ea6fa59858
ORCID for Elias JG Arcondoulis: ORCID iD orcid.org/0000-0002-3791-395X

Catalogue record

Date deposited: 28 Oct 2025 18:29
Last modified: 29 Oct 2025 03:15

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Contributors

Author: Md Jonaet Ansari
Author: Elias JG Arcondoulis ORCID iD
Author: Anthony Roccisano
Author: Christiane Schulz
Author: Thomas Schlaefer
Author: Colin Hall

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