Numerical Study on Particle Behavior and Deposition Accuracy in Cold Spray Additive Manufacturing

Cold Spray additive manufacturing (CSAM) is an emerging technique to fabricate freestanding objects by depositing solid-state layers of materials. Thanks to its remarkable deposition rate and maneuverability, it can be tailored to manufacturing intricate geometries in aerospace industries. In compar...

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Bibliographic Details
Published inCoatings (Basel) Vol. 12; no. 10; p. 1546
Main Authors Garmeh, Saeed, Jadidi, Mehdi
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.10.2022
Subjects
3D printing
Accuracy
Additive manufacturing
Aerospace industry
Aluminum
Boundary conditions
Cold
Deposition
Gas flow
Geometry
Impact velocity
Maneuverability
Manufacturing
Mathematical models
Nozzles
Particle size
Powders
Production processes
Shock waves
Solid state
Spray guns
Substrates
Supersonic flow
Three dimensional models
Turbulence models
Velocity
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Summary:Cold Spray additive manufacturing (CSAM) is an emerging technique to fabricate freestanding objects by depositing solid-state layers of materials. Thanks to its remarkable deposition rate and maneuverability, it can be tailored to manufacturing intricate geometries in aerospace industries. In comparison to other additive manufacturing techniques, it is the processing speed, solid-state deposition, and the cost that make CSAM unique. In this study, CSAM process was modeled for a system comprised of a high-pressure cold spray gun with axial powder injection. To represent the flow structure around the already built objects and the deposited layers of CSAM, three walls with different profiles are placed on a flat substrate. In this work, the gas-particle behaviors are studied at the vicinity of these non-axisymmetric objects that can be generalized to more complex geometries and the applications of CSAM. The model is 3D and aluminum and copper powders were used for the feedstock. The particles’ conditions upon impact, such as particles’ footprint and normal impact velocities are studied. The numerical results show that the deviation of particles which is caused by the supersonic flow inside the nozzle and the shock waves outside the nozzle defines the accuracy of the deposition. Furthermore, the results manifest the particle’s material and size have a significant influence on the acquired velocities and trajectories of the particles, and consequently on the resolution of the process. It is found that the profile of the deposited layers has some effects on the gas flow near the substrate which plays a role in the dispersion of fine particles.
ISSN:2079-6412
2079-6412
DOI:10.3390/coatings12101546