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Main Authors: Mutswatiwa, Lovejoy, Katch, Lauren, Kizer, Nathan J., Todd, Judith A., Sun, Tao, Clark, Samuel J., Fezzaa, Kamel, Lum, Jordan, Stobbe, David M., Jones, Griffin T., Meinert, Kenneth C., Arguelles, Andrea P., Kube, Christopher M.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2407.10282
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author Mutswatiwa, Lovejoy
Katch, Lauren
Kizer, Nathan J.
Todd, Judith A.
Sun, Tao
Clark, Samuel J.
Fezzaa, Kamel
Lum, Jordan
Stobbe, David M.
Jones, Griffin T.
Meinert, Kenneth C.
Arguelles, Andrea P.
Kube, Christopher M.
author_facet Mutswatiwa, Lovejoy
Katch, Lauren
Kizer, Nathan J.
Todd, Judith A.
Sun, Tao
Clark, Samuel J.
Fezzaa, Kamel
Lum, Jordan
Stobbe, David M.
Jones, Griffin T.
Meinert, Kenneth C.
Arguelles, Andrea P.
Kube, Christopher M.
contents Ultrasonic processing of solidifying metals in additive manufacturing can provide grain refinement and advantageous mechanical properties. However, the specific physical mechanisms of microstructural refinement relevant to laser-based additive manufacturing have not been directly observed because of sub-millimeter length scales and rapid solidification rates associated with melt pools. Here, high-speed synchrotron X-ray imaging is used to observe the effect of ultrasonic vibration directly on melt pool dynamics and solidification of Al6061 alloy. The high temporal and spatial resolution enabled direct observation of cavitation effects driven by a 20.2 kHz ultrasonic source. We utilized multiphysics simulations to validate the postulated connection between ultrasonic treatment and solidification. The X-ray results show a decrease in melt pool and keyhole depth fluctuations during melting and promotion of pore migration toward the melt pool surface with applied sonication. Additionally, the simulation results reveal increased localized melt pool flow velocity, cooling rates, and thermal gradients with applied sonication. This work shows how ultrasonic treatment can impact melt pools and its potential for improving part quality.
format Preprint
id arxiv_https___arxiv_org_abs_2407_10282
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle High-speed synchrotron X-ray imaging of melt pool dynamics during ultrasonic melt processing of Al6061
Mutswatiwa, Lovejoy
Katch, Lauren
Kizer, Nathan J.
Todd, Judith A.
Sun, Tao
Clark, Samuel J.
Fezzaa, Kamel
Lum, Jordan
Stobbe, David M.
Jones, Griffin T.
Meinert, Kenneth C.
Arguelles, Andrea P.
Kube, Christopher M.
Applied Physics
Materials Science
Ultrasonic processing of solidifying metals in additive manufacturing can provide grain refinement and advantageous mechanical properties. However, the specific physical mechanisms of microstructural refinement relevant to laser-based additive manufacturing have not been directly observed because of sub-millimeter length scales and rapid solidification rates associated with melt pools. Here, high-speed synchrotron X-ray imaging is used to observe the effect of ultrasonic vibration directly on melt pool dynamics and solidification of Al6061 alloy. The high temporal and spatial resolution enabled direct observation of cavitation effects driven by a 20.2 kHz ultrasonic source. We utilized multiphysics simulations to validate the postulated connection between ultrasonic treatment and solidification. The X-ray results show a decrease in melt pool and keyhole depth fluctuations during melting and promotion of pore migration toward the melt pool surface with applied sonication. Additionally, the simulation results reveal increased localized melt pool flow velocity, cooling rates, and thermal gradients with applied sonication. This work shows how ultrasonic treatment can impact melt pools and its potential for improving part quality.
title High-speed synchrotron X-ray imaging of melt pool dynamics during ultrasonic melt processing of Al6061
topic Applied Physics
Materials Science
url https://arxiv.org/abs/2407.10282