Structure and properties of components made by the powder bed fusion (PBF) additive manufacturing (AM) are often optimized by trial and error. This procedure is expensive, time consuming and does not provide any assurance of optimizing product quality. A recourse is to build, test and utilize a numerical model of the process that can estimate the most important metallurgical variables from the processing conditions and alloy properties. Here we develop and test a three-dimensional, transient, heat transfer and fluid flow model to calculate temperature and velocity fields, build shape and size, cooling rates and the solidification parameters during PBF process. This model considers temperature dependent properties of the powder bed consideri...
Metal additive manufacturing (AM) is a fast-evolving technology aiming to efficiently produce comple...
In laser based powder-bed fusion of metals (PBF-LB/M), parts are fabricated by melting layers of pow...
Microstructure evolution in metal additive manufacturing (AM) is a complex multi-physics and multi-s...
The most important metallurgical variables that affect the structure and properties of components pr...
The field of metal additive manufacturing holds great promise in several industries for its potentia...
This survey aims to provide a review on the application of finite element method to optimize process...
The increasing interest in additively manufactured metallic parts from industry has issued a formida...
Laser-powder bed fusion (L-PBF) additive manufacturing involves complex physics such as heat transf...
One of the most important ingredients in a numerical model of Additive Manufacturing (AM) is a heat ...
Temperature distribution gradient in metal powder bed additive manufacturing (MPBAM) directly contro...
In order to learn how to modify additive manufacturing designs and processes to ensure lab-scale sp...
In this work, we have developed a two-scale (finite element + phase field) model for simulating the ...
This study investigates the effects of convection heat transfer during the laser-powder bed fusion ...
Additive Manufacturing (AM) of copper and copper alloys has opened new frontiers in heat transfer ap...
The powder bed fusion (PBF) process is widely adopted in many manufacturing industries because of it...
Metal additive manufacturing (AM) is a fast-evolving technology aiming to efficiently produce comple...
In laser based powder-bed fusion of metals (PBF-LB/M), parts are fabricated by melting layers of pow...
Microstructure evolution in metal additive manufacturing (AM) is a complex multi-physics and multi-s...
The most important metallurgical variables that affect the structure and properties of components pr...
The field of metal additive manufacturing holds great promise in several industries for its potentia...
This survey aims to provide a review on the application of finite element method to optimize process...
The increasing interest in additively manufactured metallic parts from industry has issued a formida...
Laser-powder bed fusion (L-PBF) additive manufacturing involves complex physics such as heat transf...
One of the most important ingredients in a numerical model of Additive Manufacturing (AM) is a heat ...
Temperature distribution gradient in metal powder bed additive manufacturing (MPBAM) directly contro...
In order to learn how to modify additive manufacturing designs and processes to ensure lab-scale sp...
In this work, we have developed a two-scale (finite element + phase field) model for simulating the ...
This study investigates the effects of convection heat transfer during the laser-powder bed fusion ...
Additive Manufacturing (AM) of copper and copper alloys has opened new frontiers in heat transfer ap...
The powder bed fusion (PBF) process is widely adopted in many manufacturing industries because of it...
Metal additive manufacturing (AM) is a fast-evolving technology aiming to efficiently produce comple...
In laser based powder-bed fusion of metals (PBF-LB/M), parts are fabricated by melting layers of pow...
Microstructure evolution in metal additive manufacturing (AM) is a complex multi-physics and multi-s...