Generation of 2.5D Deposition Strategies for LMD-based Additive Manufacturing

Additive manufacturing is a key technology of Industry 4.0. In the context of Laser Metal Deposition (LMD), the problem of automating the generation of the layer-by-layer deposition strategies is relevant because the laser path pattern and the process parameters determine the mechanical quality of t...

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Published inProcedia computer science Vol. 180; pp. 280 - 289
Main Authors Montoya-Zapata, Diego, Creus, Carles, Ortiz, Igor, Alvarez, Piera, Moreno, Aitor, Posada, Jorge, Ruiz-Salguero, Oscar
Format Journal Article
LanguageEnglish
Published Elsevier B.V 2021
Subjects
additive manufacturing
Industry 4.0
laser cladding
path-planning
path-planning
additive manufacturing
Industry 4.0
laser cladding
Online AccessGet full text
ISSN1877-0509
1877-0509
DOI10.1016/j.procs.2021.01.165

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Abstract Additive manufacturing is a key technology of Industry 4.0. In the context of Laser Metal Deposition (LMD), the problem of automating the generation of the layer-by-layer deposition strategies is relevant because the laser path pattern and the process parameters determine the mechanical quality of the resulting part and the efficiency of the process. Many of the existing approaches rely on path planning strategies created for subtractive manufacturing. However, these techniques generate path patterns not suitable for LMD. This manuscript presents deposition strategies which are specific for LMD processes, including the laser path and the process parameters at selected control points. This manuscript considers diverse infill patterns for general polygonal regions. This manuscript also reports the implementation of a 2D region avoidance algorithm, used to reposition the laser head between regions and between layers. These transitions are important because current hardware maintains the material feeding while the laser is OFF. Our implementation is validated by the fabrication and verification of actual metallic parts using our algorithms in an LMD process. Future work is required on optimization of material savings and overall process performance.
AbstractList Additive manufacturing is a key technology of Industry 4.0. In the context of Laser Metal Deposition (LMD), the problem of automating the generation of the layer-by-layer deposition strategies is relevant because the laser path pattern and the process parameters determine the mechanical quality of the resulting part and the efficiency of the process. Many of the existing approaches rely on path planning strategies created for subtractive manufacturing. However, these techniques generate path patterns not suitable for LMD. This manuscript presents deposition strategies which are specific for LMD processes, including the laser path and the process parameters at selected control points. This manuscript considers diverse infill patterns for general polygonal regions. This manuscript also reports the implementation of a 2D region avoidance algorithm, used to reposition the laser head between regions and between layers. These transitions are important because current hardware maintains the material feeding while the laser is OFF. Our implementation is validated by the fabrication and verification of actual metallic parts using our algorithms in an LMD process. Future work is required on optimization of material savings and overall process performance.
Author Creus, Carles
Posada, Jorge
Moreno, Aitor
Ruiz-Salguero, Oscar
Montoya-Zapata, Diego
Alvarez, Piera
Ortiz, Igor
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Keywords path-planning
additive manufacturing
Industry 4.0
laser cladding
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Snippet Additive manufacturing is a key technology of Industry 4.0. In the context of Laser Metal Deposition (LMD), the problem of automating the generation of the...
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SubjectTerms additive manufacturing
Industry 4.0
laser cladding
path-planning
Title Generation of 2.5D Deposition Strategies for LMD-based Additive Manufacturing
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