Additive manufacturing (AM) technologies continuously evolve in materials and operational processes. However, challenges related to energy consumption, material reuse efficiency, and the integration of Circular Economy (CE) principles may impede the overall sustainability of AM processes. As many industrial sectors adopt AM technologies, there is a growing need for innovative tools, methods, and frameworks that guide companies toward more sustainable and circular production practices. This shift involves improving resource efficiency and fostering new Circular Business Models that emphasize material recovery, product lifecycle extension, and waste minimization. This study assesses current and future trends in the development of sustainable AM technologies for processing metal feedstock, based on a comprehensive patent analysis covering the period from 2004 to 2024. We specifically focus on the sustainability impacts of Electron and Laser Beam Powder Bed Fusion (PBF-EB, PBF-LB) and Direct Energy Deposition (DED), given their widespread industrial applications. Patents were categorized into three groups: materials, processes, and components. Furthermore, AM technologies were analyzed according to their role within the production cycle: materials preparation, pre-processing, manufacturing, and post-processing. This categorization allows for a detailed understanding of how innovations in AM contribute to more sustainable production and consumption practices by improving energy efficiency, material usage, circularity, and overall environmental impact.

Advancing sustainability in Electron and laser beam powder Bed Fusion technologies via Innovation: Insights from patent analysis / Devito, Fabrizia; Natalicchio, Angelo; Lavecchia, Fulvio; Dassisti, Michele. - In: COMPUTERS & INDUSTRIAL ENGINEERING. - ISSN 0360-8352. - (In corso di stampa). [10.1016/j.cie.2024.110794]

Advancing sustainability in Electron and laser beam powder Bed Fusion technologies via Innovation: Insights from patent analysis

Devito, Fabrizia
;
Natalicchio, Angelo;Lavecchia, Fulvio;Dassisti, Michele
In corso di stampa

Abstract

Additive manufacturing (AM) technologies continuously evolve in materials and operational processes. However, challenges related to energy consumption, material reuse efficiency, and the integration of Circular Economy (CE) principles may impede the overall sustainability of AM processes. As many industrial sectors adopt AM technologies, there is a growing need for innovative tools, methods, and frameworks that guide companies toward more sustainable and circular production practices. This shift involves improving resource efficiency and fostering new Circular Business Models that emphasize material recovery, product lifecycle extension, and waste minimization. This study assesses current and future trends in the development of sustainable AM technologies for processing metal feedstock, based on a comprehensive patent analysis covering the period from 2004 to 2024. We specifically focus on the sustainability impacts of Electron and Laser Beam Powder Bed Fusion (PBF-EB, PBF-LB) and Direct Energy Deposition (DED), given their widespread industrial applications. Patents were categorized into three groups: materials, processes, and components. Furthermore, AM technologies were analyzed according to their role within the production cycle: materials preparation, pre-processing, manufacturing, and post-processing. This categorization allows for a detailed understanding of how innovations in AM contribute to more sustainable production and consumption practices by improving energy efficiency, material usage, circularity, and overall environmental impact.
In corso di stampa
Advancing sustainability in Electron and laser beam powder Bed Fusion technologies via Innovation: Insights from patent analysis / Devito, Fabrizia; Natalicchio, Angelo; Lavecchia, Fulvio; Dassisti, Michele. - In: COMPUTERS & INDUSTRIAL ENGINEERING. - ISSN 0360-8352. - (In corso di stampa). [10.1016/j.cie.2024.110794]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11589/280241
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