Developing high intensity ultrasonic cleaning (HIUC) for post-processing additively manufactured metal components
The high energy phenomenon of cavitation bubble collapses has enabled numerous applications, including cleaning. In ultrasonic cleaning, cavitation intensity is typically lower than in other applications, such as sonochemistry and material processing. However, there has been an emerging application...
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sg-ntu-dr.10356-1630522023-07-14T16:05:07Z Developing high intensity ultrasonic cleaning (HIUC) for post-processing additively manufactured metal components Tan, W. X. Tan, Kwan Wee Tan, Kai Liang School of Materials Science and Engineering Engineering::Materials Ultrasonic Cavitation Focused Ultrasonic Wave The high energy phenomenon of cavitation bubble collapses has enabled numerous applications, including cleaning. In ultrasonic cleaning, cavitation intensity is typically lower than in other applications, such as sonochemistry and material processing. However, there has been an emerging application in intense cleaning of metal additively manufactured (AM) components. The presence of partially melted powders on AM surfaces is undesirable, contributing to high surface roughness and posing contamination risks during usage. We designed a high-intensity cavitation cleaning process that has significantly higher inertial cavitation intensity - i.e., erosion potential - than a conventional ultrasonic cleaning tank. Through acoustic signal characterisation, we showed that placing transducer sets on four sides of the tank could effectively focus and generate high-amplitude pressure waves directed towards the central region. Strong subharmonic signals indicate intensely inertial cavitation throughout the tank. Cavitation intensities were measured at various locations to understand the wave transmission characteristics and distribution patterns. Our results show that the cavitation intensity distribution is highly dependent on the height position. Finally, we demonstrated that the high intensity ultrasonic cleaning (HIUC) process could remove partially melted powders from an AM surface - which was not possible through conventional ultrasonic cleaning. HIUC could lead to higher cleaning efficiency and enhanced AM specimen cleanliness. Agency for Science, Technology and Research (A*STAR) Submitted/Accepted version This work was conducted within the Advanced Remanufacturing and Technology Center, Singapore and supported under the core research funding of the Data-Driven Surface Enhancement Group. 2022-11-18T01:06:03Z 2022-11-18T01:06:03Z 2022 Journal Article Tan, W. X., Tan, K. W. & Tan, K. L. (2022). Developing high intensity ultrasonic cleaning (HIUC) for post-processing additively manufactured metal components. Ultrasonics, 126, 106829-. https://dx.doi.org/10.1016/j.ultras.2022.106829 0041-624X https://hdl.handle.net/10356/163052 10.1016/j.ultras.2022.106829 35998399 2-s2.0-85136146330 126 106829 en Ultrasonics © 2022 Elsevier B.V. All rights reserved. This paper was published in Ultrasonics and is made available with permission of Elsevier B.V. application/pdf |
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Engineering::Materials Ultrasonic Cavitation Focused Ultrasonic Wave Tan, W. X. Tan, Kwan Wee Tan, Kai Liang Developing high intensity ultrasonic cleaning (HIUC) for post-processing additively manufactured metal components |
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The high energy phenomenon of cavitation bubble collapses has enabled numerous applications, including cleaning. In ultrasonic cleaning, cavitation intensity is typically lower than in other applications, such as sonochemistry and material processing. However, there has been an emerging application in intense cleaning of metal additively manufactured (AM) components. The presence of partially melted powders on AM surfaces is undesirable, contributing to high surface roughness and posing contamination risks during usage. We designed a high-intensity cavitation cleaning process that has significantly higher inertial cavitation intensity - i.e., erosion potential - than a conventional ultrasonic cleaning tank. Through acoustic signal characterisation, we showed that placing transducer sets on four sides of the tank could effectively focus and generate high-amplitude pressure waves directed towards the central region. Strong subharmonic signals indicate intensely inertial cavitation throughout the tank. Cavitation intensities were measured at various locations to understand the wave transmission characteristics and distribution patterns. Our results show that the cavitation intensity distribution is highly dependent on the height position. Finally, we demonstrated that the high intensity ultrasonic cleaning (HIUC) process could remove partially melted powders from an AM surface - which was not possible through conventional ultrasonic cleaning. HIUC could lead to higher cleaning efficiency and enhanced AM specimen cleanliness. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Tan, W. X. Tan, Kwan Wee Tan, Kai Liang |
| format |
Article |
| author |
Tan, W. X. Tan, Kwan Wee Tan, Kai Liang |
| author_sort |
Tan, W. X. |
| title |
Developing high intensity ultrasonic cleaning (HIUC) for post-processing additively manufactured metal components |
| title_short |
Developing high intensity ultrasonic cleaning (HIUC) for post-processing additively manufactured metal components |
| title_full |
Developing high intensity ultrasonic cleaning (HIUC) for post-processing additively manufactured metal components |
| title_fullStr |
Developing high intensity ultrasonic cleaning (HIUC) for post-processing additively manufactured metal components |
| title_full_unstemmed |
Developing high intensity ultrasonic cleaning (HIUC) for post-processing additively manufactured metal components |
| title_sort |
developing high intensity ultrasonic cleaning (hiuc) for post-processing additively manufactured metal components |
| publishDate |
2022 |
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https://hdl.handle.net/10356/163052 |
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1773551382752657408 |