Irrinki, Harish
(Materials Innovation Guild, University of Louisville, Louisville, KY 40292, United States)
,
Jangam, John Samuel Dilip
(Materials Innovation Guild, University of Louisville, Louisville, KY 40292, United States)
,
Pasebani, Somayeh
(Oregon State University, Corvallis, OR 973302, United States)
,
Badwe, Sunil
(North American Hö)
,
Stitzel, Jason
(ganä)
,
Kate, Kunal
(s, Johnstown, PA 15935, United States)
,
Gulsoy, Ozkan
(Metal Technologies Incorporated, Albany, OR 97322, United States)
,
Atre, Sundar V.
(Materials Innovation Guild, University of Louisville, Louisville, KY 40292, United States)
Abstract The effects of powder characteristics (powder shape, size and type) and processing conditions (laser power and scanning speed) on the mechanical properties and microstructures of laser powder bed fusion (L-PBF) 17-4 PH stainless steel were studied using four types of powders. The % theoret...
Abstract The effects of powder characteristics (powder shape, size and type) and processing conditions (laser power and scanning speed) on the mechanical properties and microstructures of laser powder bed fusion (L-PBF) 17-4 PH stainless steel were studied using four types of powders. The % theoretical density, ultimate tensile strength, hardness of L-PBF parts are sensitive to energy density and starting powder shape, size and type. The density and mechanical properties of both water and gas-atomized powders increased with increased energy density. The gas-atomized (D 50 = 13 μm) powders which are spherical in shape and water-atomized (D 50 = 17 μm) powders of high tap density produced low-porosity and high-density (~97% density) L-PBF parts at low energy densities of 64 and 80 J/mm3. The increase in energy density to 104 J/mm3 resulted in high dense (97 ± 0.5%) water- and gas-atomized powders L-PBF parts. However, even at a high % theoretical density (97 ± 1%), the properties of L-PBF parts varied over a relatively large range (UTS: 500–1100 MPa; hardness: 25–39 HRC; elongation: 10–25%). This large variation in mechanical properties could be attributed the martensite and austenite phase as well as grain size in the L-PBF parts. Furthermore, the martensite and austenite phase content and of the L-PBF parts were also sensitive to the energy density and starting powder type. Highlights 17-4PH particle characteristics strongly influence densification in L-PBF parts. Irregular shaped powders with high tap density can produce near full density parts. Mechanical properties and microstructures are sensitive to powder characteristics. A large variation in mechanical properties was observed for highly dense parts. Water-atomized parts of UTS 1100 MPa were produced at energy density 104 J/mm3. Graphical abstract [DISPLAY OMISSION]
Abstract The effects of powder characteristics (powder shape, size and type) and processing conditions (laser power and scanning speed) on the mechanical properties and microstructures of laser powder bed fusion (L-PBF) 17-4 PH stainless steel were studied using four types of powders. The % theoretical density, ultimate tensile strength, hardness of L-PBF parts are sensitive to energy density and starting powder shape, size and type. The density and mechanical properties of both water and gas-atomized powders increased with increased energy density. The gas-atomized (D 50 = 13 μm) powders which are spherical in shape and water-atomized (D 50 = 17 μm) powders of high tap density produced low-porosity and high-density (~97% density) L-PBF parts at low energy densities of 64 and 80 J/mm3. The increase in energy density to 104 J/mm3 resulted in high dense (97 ± 0.5%) water- and gas-atomized powders L-PBF parts. However, even at a high % theoretical density (97 ± 1%), the properties of L-PBF parts varied over a relatively large range (UTS: 500–1100 MPa; hardness: 25–39 HRC; elongation: 10–25%). This large variation in mechanical properties could be attributed the martensite and austenite phase as well as grain size in the L-PBF parts. Furthermore, the martensite and austenite phase content and of the L-PBF parts were also sensitive to the energy density and starting powder type. Highlights 17-4PH particle characteristics strongly influence densification in L-PBF parts. Irregular shaped powders with high tap density can produce near full density parts. Mechanical properties and microstructures are sensitive to powder characteristics. A large variation in mechanical properties was observed for highly dense parts. Water-atomized parts of UTS 1100 MPa were produced at energy density 104 J/mm3. Graphical abstract [DISPLAY OMISSION]
※ AI-Helper는 부적절한 답변을 할 수 있습니다.