Differenze tra le versioni di "Direct Metal Laser Sintering, robotic applications"
| Riga 1: | Riga 1: | ||
| − | Authors and full affiliations: | + | '''Authors and full affiliations:''' |
D. Manfredi, F. Calignano, E. P. Ambrosio, M.Krishnan, R. Canali, S. Biamino, M. Pavese, E. Atzeni, L. Iuliano, P. Fino, C. Badini | D. Manfredi, F. Calignano, E. P. Ambrosio, M.Krishnan, R. Canali, S. Biamino, M. Pavese, E. Atzeni, L. Iuliano, P. Fino, C. Badini | ||
| − | Keywords: | + | '''Keywords:''' |
Additive manufacturing (AM) - Direct metal laser sintering (DMLS) - Aluminium alloy Mechanical properties - Electron microscopy - Lightweight structures | Additive manufacturing (AM) - Direct metal laser sintering (DMLS) - Aluminium alloy Mechanical properties - Electron microscopy - Lightweight structures | ||
| − | Purpose: | + | '''Purpose:''' |
This approach permits to extend significantly the freedom of design and manufacture by allowing, for example, to create an object with desired shape and internal structure in a single fabrication step | This approach permits to extend significantly the freedom of design and manufacture by allowing, for example, to create an object with desired shape and internal structure in a single fabrication step | ||
| − | Design/Methodology/Approach: | + | '''Design/Methodology/Approach:''' |
All the steps involved in the production of Al alloy pieces by DMLS; | All the steps involved in the production of Al alloy pieces by DMLS; | ||
| Riga 20: | Riga 20: | ||
| − | Findings: | + | '''Findings:''' |
Shorter time to market, higher production speed, versatility, high precision of parts, ability to produce more functionality in parts with unique design and engineered features. In particular, it allows to create fully functional parts directly from metal powders without using intermediate binders or further processing steps after the laser sintering operation | Shorter time to market, higher production speed, versatility, high precision of parts, ability to produce more functionality in parts with unique design and engineered features. In particular, it allows to create fully functional parts directly from metal powders without using intermediate binders or further processing steps after the laser sintering operation | ||
| − | Limitations/Benefits: | + | '''Limitations/Benefits:''' |
DMLS makes it possible to create fully functional parts directly from metal powders without using any intermediate binders or any additional processing steps after the laser sintering operation, except only for surface finishing depending on the single application. | DMLS makes it possible to create fully functional parts directly from metal powders without using any intermediate binders or any additional processing steps after the laser sintering operation, except only for surface finishing depending on the single application. | ||
| − | Full reference: | + | '''Full reference:''' |
MANFREDI, D., et al. Direct metal laser sintering: an additive manufacturing technology ready to produce lightweight structural parts for robotic applications. La metallurgia italiana, 2013, 10. | MANFREDI, D., et al. Direct metal laser sintering: an additive manufacturing technology ready to produce lightweight structural parts for robotic applications. La metallurgia italiana, 2013, 10. | ||
| − | Link(s): | + | '''Link(s):''' |
https://www.gruppofrattura.it/ors/index.php/aim/article/viewFile/1210/1163 | https://www.gruppofrattura.it/ors/index.php/aim/article/viewFile/1210/1163 | ||
Versione attuale delle 17:15, 9 gen 2020
Authors and full affiliations:
D. Manfredi, F. Calignano, E. P. Ambrosio, M.Krishnan, R. Canali, S. Biamino, M. Pavese, E. Atzeni, L. Iuliano, P. Fino, C. Badini
Keywords:
Additive manufacturing (AM) - Direct metal laser sintering (DMLS) - Aluminium alloy Mechanical properties - Electron microscopy - Lightweight structures
Purpose:
This approach permits to extend significantly the freedom of design and manufacture by allowing, for example, to create an object with desired shape and internal structure in a single fabrication step
Design/Methodology/Approach:
All the steps involved in the production of Al alloy pieces by DMLS; Fase 1(STL file by 3D cam model), fase 2(support structure), fase 3(slicing), fase 4(part build), fase 5(stress relieving), fase 6(shot peening), fase 7(aluminium part)
Findings:
Shorter time to market, higher production speed, versatility, high precision of parts, ability to produce more functionality in parts with unique design and engineered features. In particular, it allows to create fully functional parts directly from metal powders without using intermediate binders or further processing steps after the laser sintering operation
Limitations/Benefits:
DMLS makes it possible to create fully functional parts directly from metal powders without using any intermediate binders or any additional processing steps after the laser sintering operation, except only for surface finishing depending on the single application.
Full reference:
MANFREDI, D., et al. Direct metal laser sintering: an additive manufacturing technology ready to produce lightweight structural parts for robotic applications. La metallurgia italiana, 2013, 10.
Link(s):
https://www.gruppofrattura.it/ors/index.php/aim/article/viewFile/1210/1163
