Abstract
create a melt pool on the substrate. A nozzle is used to carry metal powder within a gas flow until the melt pool, concentrating the flow at the same point. Coaxial nozzles usually have also a shield gas flow to prevent oxidation and an internal flow to protect the optical system. A right flow configuration must be selected to avoid high turbulence at the nozzle exit, leading to an efficient, inexpensive, and high-quality process. Due to the complexity of the process, CFD – Computer Fluid Dynamics are becoming necessary to understand the behaviour of those gas flows in DED processes. CFD can offer results close to reality and may allow an optimization of the whole nozzle designs, besides selecting the best gas flows for each application. The present work develops a CFD simulation of the gas flow behaviour in a coaxial nozzle with three internal annular channels (internal, carrier and shield). An initial set of gas flow was selected, based on previous experience of the manufacturer, and then improved. It searches for the low gas consumption, to form a focal point coinciding with the laser focus and a low velocity, which favours the deposition quality. To check the accuracy of the proposed CFD model, experimental measurements of gas velocity were performed and compared with simulated results.
Highlights
Additive manufacturing is a process by which 3D object can be produced, starting directly from their 3D CAD
Directed Energy Deposition (DED) is considered a disruptive manufacturing method, since it allows the use of different materials in the same process and compared to the traditional manufacturing process, is considered a more profitable process due to the short time it demands and its flexibility [4]
Powder metal is the most used raw material due to its versatility and the fact that most materials can be transformed into powder
Summary
Additive manufacturing is a process by which 3D object can be produced, starting directly from their 3D CAD. In processes using metal powder, a nozzle is responsible to deliver the powder into the melt pool, using inter gas flows. Designs with three flows use nozzle, carrier and shield channels. The carrier gas flows through a middle channel and carries the powder flow to the melt pool. The shield flow comes an outer channel and is used to protect the melt pool against oxidation. (Some author refers to the nozzle gas as axial gas and the shield gas as shape gas) The combination of those three coaxial gas flows is strictly related with the DED process efficiency
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