Demonstration and benchmarking of a novel powder sheet additive manufacturing approach with austenitic steel

Wenyou Zhang; Silvia Marola; Seán McConnell; Zhe Cai; Jan Mell Dugenio; Ming Li; William M. Abbott; Asli Coban; Arnoldas Sasnauskas; Shuo Yin; Ramesh Padamati Babu; Wajira Mirihanage; Riccardo Casati; Rocco Lupoi

doi:10.1016/j.matdes.2024.113301

Demonstration and benchmarking of a novel powder sheet additive manufacturing approach with austenitic steel

Wenyou Zhang, Silvia Marola, Seán McConnell, Zhe Cai, Jan Mell Dugenio, Ming Li, William M. Abbott, Asli Coban, Arnoldas Sasnauskas, Shuo Yin, Ramesh Padamati Babu, Wajira Mirihanage, Riccardo Casati, Rocco Lupoi

Research output: Contribution to journal › Article › peer-review

Abstract

A novel approach of Metal Additive Manufacturing using Powder Sheet (MAPS) is developed and demonstrated. A flexible metal particle-polymeric binder composite sheet is employed as innovative feedstock in this new method and this approach offers enhanced health and safety. MAPS successfully printed dense samples (99.99%). The chemical composition of the printed alloy resulted enriched in carbon compared to the feedstock powder due to the C pick-up during MAPS, leading to distinct microstructures and enhanced mechanical properties compared to those of laser beam powder bed fusion (PBF-LB/M) benchmark samples. In particular, the microstructural examinations of the MAPS samples show a coarser carbide network stable even after thermal treatment at high temperatures, while the tensile tests revealed that MAPS samples have a higher mechanical strength than the PBF-LB/M counterparts but possess lower ductility. The modification in the chemical composition indicates a strong potential for in-process alloying through MAPS. The demonstrated MAPS approach offers a novel avenue for manufacturing functional metal components with bespoke compositions and resulting properties.

Original language	English
Article number	113301
Journal	Materials and Design
Volume	245
DOIs	https://doi.org/10.1016/j.matdes.2024.113301
Publication status	Published - Sep 2024

Keywords

Heat treatment
Laser beam powder bed fusion
Microstructure
Powder sheet
Tensile performances

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10.1016/j.matdes.2024.113301

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Zhang, W., Marola, S., McConnell, S., Cai, Z., Dugenio, J. M., Li, M., Abbott, W. M., Coban, A., Sasnauskas, A., Yin, S., Padamati Babu, R., Mirihanage, W., Casati, R., & Lupoi, R. (2024). Demonstration and benchmarking of a novel powder sheet additive manufacturing approach with austenitic steel. Materials and Design, 245, Article 113301. https://doi.org/10.1016/j.matdes.2024.113301

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title = "Demonstration and benchmarking of a novel powder sheet additive manufacturing approach with austenitic steel",

abstract = "A novel approach of Metal Additive Manufacturing using Powder Sheet (MAPS) is developed and demonstrated. A flexible metal particle-polymeric binder composite sheet is employed as innovative feedstock in this new method and this approach offers enhanced health and safety. MAPS successfully printed dense samples (99.99\%). The chemical composition of the printed alloy resulted enriched in carbon compared to the feedstock powder due to the C pick-up during MAPS, leading to distinct microstructures and enhanced mechanical properties compared to those of laser beam powder bed fusion (PBF-LB/M) benchmark samples. In particular, the microstructural examinations of the MAPS samples show a coarser carbide network stable even after thermal treatment at high temperatures, while the tensile tests revealed that MAPS samples have a higher mechanical strength than the PBF-LB/M counterparts but possess lower ductility. The modification in the chemical composition indicates a strong potential for in-process alloying through MAPS. The demonstrated MAPS approach offers a novel avenue for manufacturing functional metal components with bespoke compositions and resulting properties.",

keywords = "Heat treatment, Laser beam powder bed fusion, Microstructure, Powder sheet, Tensile performances",

author = "Wenyou Zhang and Silvia Marola and Se{\'a}n McConnell and Zhe Cai and Dugenio, \{Jan Mell\} and Ming Li and Abbott, \{William M.\} and Asli Coban and Arnoldas Sasnauskas and Shuo Yin and \{Padamati Babu\}, Ramesh and Wajira Mirihanage and Riccardo Casati and Rocco Lupoi",

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year = "2024",

month = sep,

doi = "10.1016/j.matdes.2024.113301",

language = "English",

volume = "245",

journal = "Materials and Design",

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T1 - Demonstration and benchmarking of a novel powder sheet additive manufacturing approach with austenitic steel

AU - Zhang, Wenyou

AU - Marola, Silvia

AU - McConnell, Seán

AU - Cai, Zhe

AU - Dugenio, Jan Mell

AU - Li, Ming

AU - Abbott, William M.

AU - Coban, Asli

AU - Sasnauskas, Arnoldas

AU - Yin, Shuo

AU - Padamati Babu, Ramesh

AU - Mirihanage, Wajira

AU - Casati, Riccardo

AU - Lupoi, Rocco

PY - 2024/9

Y1 - 2024/9

N2 - A novel approach of Metal Additive Manufacturing using Powder Sheet (MAPS) is developed and demonstrated. A flexible metal particle-polymeric binder composite sheet is employed as innovative feedstock in this new method and this approach offers enhanced health and safety. MAPS successfully printed dense samples (99.99%). The chemical composition of the printed alloy resulted enriched in carbon compared to the feedstock powder due to the C pick-up during MAPS, leading to distinct microstructures and enhanced mechanical properties compared to those of laser beam powder bed fusion (PBF-LB/M) benchmark samples. In particular, the microstructural examinations of the MAPS samples show a coarser carbide network stable even after thermal treatment at high temperatures, while the tensile tests revealed that MAPS samples have a higher mechanical strength than the PBF-LB/M counterparts but possess lower ductility. The modification in the chemical composition indicates a strong potential for in-process alloying through MAPS. The demonstrated MAPS approach offers a novel avenue for manufacturing functional metal components with bespoke compositions and resulting properties.

AB - A novel approach of Metal Additive Manufacturing using Powder Sheet (MAPS) is developed and demonstrated. A flexible metal particle-polymeric binder composite sheet is employed as innovative feedstock in this new method and this approach offers enhanced health and safety. MAPS successfully printed dense samples (99.99%). The chemical composition of the printed alloy resulted enriched in carbon compared to the feedstock powder due to the C pick-up during MAPS, leading to distinct microstructures and enhanced mechanical properties compared to those of laser beam powder bed fusion (PBF-LB/M) benchmark samples. In particular, the microstructural examinations of the MAPS samples show a coarser carbide network stable even after thermal treatment at high temperatures, while the tensile tests revealed that MAPS samples have a higher mechanical strength than the PBF-LB/M counterparts but possess lower ductility. The modification in the chemical composition indicates a strong potential for in-process alloying through MAPS. The demonstrated MAPS approach offers a novel avenue for manufacturing functional metal components with bespoke compositions and resulting properties.

KW - Heat treatment

KW - Laser beam powder bed fusion

KW - Microstructure

KW - Powder sheet

KW - Tensile performances

UR - https://www.scopus.com/pages/publications/85203416591

U2 - 10.1016/j.matdes.2024.113301

DO - 10.1016/j.matdes.2024.113301

M3 - Article

AN - SCOPUS:85203416591

SN - 0264-1275

VL - 245

JO - Materials and Design

JF - Materials and Design

M1 - 113301

ER -

Demonstration and benchmarking of a novel powder sheet additive manufacturing approach with austenitic steel

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Keywords

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