Resumen
The consequences of gravity and the nozzle inclination angle in the powder-fed Directed Energy Deposition (DED) process were examined in this study. We also sought to define guidelines and manufacturing strategies, depending on the DED system configuration and the nozzle type. To do so, two nozzle types were used: a continuous coaxial nozzle with a slit of 0.5 mm and a four-stream discrete coaxial nozzle. Although the main effects of the configurations and the nozzles are well-known, their effects on the clad characteristics and the deposition strategy are as yet unclear. In this paper, measurements of a single clad and the effects of different deposition strategies on cladding applications and inclined walls are presented, and the consequences for manufacturing processes are discussed. Based on a complete study of a single clad, working vertically, five different tilted deposition strategies were applied: three to a single clad and two to an inclined wall. The results for both the single clad and the inclined wall reflect a pattern of changes to height, width, area, and efficiency, at both small and large nozzle angles and deposition strategies. The inclined wall presents a maximum horizontal displacement that can be reached per layer, without geometrical distortions. The amount of material per layer has to be adapted to this limitation.
Idioma original | Inglés |
---|---|
Número de artículo | 560 |
Páginas (desde-hasta) | 560 |
Número de páginas | 1 |
Publicación | Metals |
Volumen | 10 |
N.º | 5 |
DOI | |
Estado | Publicada - abr 2020 |
Palabras clave
- Directed Energy Deposition
- Continuous nozzle
- Discrete nozzle
- Gravity effect
- Tilting effect
- Powder
- Alloy 718
Project and Funding Information
- Project ID
- info:eu-repo/grantAgreement/EC/H2020/723440/EU/A Productive, Affordable and Reliable solution for large scale manufacturing of metallic components by combining laser-based ADDItive and Subtractive processes with high Efficiency/PARADDISE
- Funding Info
- This research was funded by the European Commission through the project "PARADDISE: a_x000D_ Productive, Affordable and Reliable solution for large scale manufacturing of metallic components by combining_x000D_ laser-based Additive and Subtractive processes with high Efficiency” (Grant Agreement 723440), an initiative of_x000D_ the Public–Private Partnership “Photonics and Factories of the Future”. This research was also funded by _x000D_ European Institute of Innovation & Technology (EIT), through the project "DEDALUS: Directed Energy_x000D_ Deposition machines with integrated process ALgorithms Under dedicated monitoring and control System” (ID_x000D_ 20094), and by the vice-counseling of technology, innovation and competitiveness of the Basque Government_x000D_ (Eusko Jaurlaritza), under the ELKARTEK Program, PROCODA project, grant number KK-2019/00004.