2024 Powder Metallurgy World Congress & Exhibition

Presentation information

General Sessions (Oral) » T7 AM Sinter Based Technologies

[T7] AM Sinter Based Technologies

Oral

Wed. Oct 16, 2024 2:20 PM - 4:00 PM Room A (3F 301, Conference Center)

Chairpersons: Kimihiro Ozaki (National Institute of Advanced Industrial Science and Technology (AIST), Japan), Sebastian Boris Hein (Fraunhofer Institute IFAM, Germany)

3:20 PM - 3:40 PM

[16A-T7-24] Microstructure and Mechanical Properties of M2 High-speed Steel Fabricated by Fused Filament Fabrication

*C. Wang2, Q. Pan2, W. Mai3, B. He2, C. Ou1, Q. Shi2, Z. Liu1, J. Peng1 (1.School of Materials Science and Engineering, Shanghai University, China, 2.Shanghai Dianji University, China, 3.Raise 3D Technologies, Inc., China)

Keywords:Fused Filament Fabrication, M2 high-speed steel, Microstructure, Mechanical properties

Fused Filament Fabrication (FFF) can produce highly loaded filled metal powders by extruding polymeric filaments to create green parts, and then debinding and sintering to produce metal parts. The filaments employed in this paper were prepared from M2 high-speed steel (M2 HSS) powders and polyformaldehyde -based binder, which have been less discussed in previous researches of M2 HSS in FFF printing. As prepared by FFF, the green part was first catalytic debinding under oxalic acid atmosphere, followed by thermal debinding and sintering from a protective atmosphere of N2 gas. The hardness of the specimens reached a maximum of 60.40 HRC and the average coefficient of friction (COF) was 0.481 under the condition of sintering at 1270 ℃ for 1 h, which was analyzed by microstructure. The research shows that FFF is a potential additive manufacturing technique which could fabricate M2 HSS with excellent mechanical properties.