Archivio Istituzionale della RicercaDirected energy deposition-laser beam/powder (DED-LB/Powder) is an additive manufacturing process that is gaining popularity in the manufacturing industry due to its numerous advantages, particularly in repairing operations. However, its application is often limited to case studies due to some critical issues that need to be addressed, such as the degree of internal porosity. This paper investigates the effect of the most relevant process parameters of the DED-LB/Powder process on the level and distribution of porosity. Results indicate that, among the process parameters examined, porosity is less affected by travel speed and more influenced by powder mass flow rate and laser power. Additionally, a three-dimensional finite element transient model was introduced, which was able to predict the development and location of lack-of-fusion pores along the building direction.
Evaluation of Porosity in AISI 316L Samples Processed by Laser Powder Directed Energy Deposition / Salmi, Alessandro; Piscopo, Gabriele; Pilagatti, Adriano Nicola; Atzeni, Eleonora. - In: JOURNAL OF MANUFACTURING AND MATERIALS PROCESSING. - ISSN 2504-4494. - 8:(2024). [10.3390/jmmp8040129]
Evaluation of Porosity in AISI 316L Samples Processed by Laser Powder Directed Energy Deposition
Salmi, Alessandro;Piscopo, Gabriele;Pilagatti, Adriano Nicola;Atzeni, Eleonora
2024
Abstract
Directed energy deposition-laser beam/powder (DED-LB/Powder) is an additive manufacturing process that is gaining popularity in the manufacturing industry due to its numerous advantages, particularly in repairing operations. However, its application is often limited to case studies due to some critical issues that need to be addressed, such as the degree of internal porosity. This paper investigates the effect of the most relevant process parameters of the DED-LB/Powder process on the level and distribution of porosity. Results indicate that, among the process parameters examined, porosity is less affected by travel speed and more influenced by powder mass flow rate and laser power. Additionally, a three-dimensional finite element transient model was introduced, which was able to predict the development and location of lack-of-fusion pores along the building direction.
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https://hdl.handle.net/11583/2990059