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binder jet
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Series: ASM Handbook
Volume: 23A
Publisher: ASM International
Published: 12 September 2022
DOI: 10.31399/asm.hb.v23A.a0006903
EISBN: 978-1-62708-392-8
... Abstract Additive manufacturing (AM) technologies print three-dimensional (3D) parts through layer-by-layer deposition based on the digital input provided by a computer-aided design file. This article focuses on the binder jet printing process, common biomaterials used in this AM technique...
Abstract
Additive manufacturing (AM) technologies print three-dimensional (3D) parts through layer-by-layer deposition based on the digital input provided by a computer-aided design file. This article focuses on the binder jet printing process, common biomaterials used in this AM technique, and the clinical applications relevant to these systems. It reviews the challenges and future directions of binder-jetting-based 3D printing.
Series: ASM Handbook
Volume: 24
Publisher: ASM International
Published: 15 June 2020
DOI: 10.31399/asm.hb.v24.a0006571
EISBN: 978-1-62708-290-7
... Abstract The highly irregular morphologies of ceramic powder particles due to their process history present a challenge to binder jetting additive manufacturing (BJ-AM) ceramic powder feedstock processability, but knowledge of powder metallurgy of ceramics benefits the development and analysis...
Abstract
The highly irregular morphologies of ceramic powder particles due to their process history present a challenge to binder jetting additive manufacturing (BJ-AM) ceramic powder feedstock processability, but knowledge of powder metallurgy of ceramics benefits the development and analysis of the BJ-AM ceramic processes. Understanding BJ-AM process principles and ceramics processing challenges requires reviewing a number of fundamental principles, which this article delineates. The discussion covers the processability considerations, a brief summary of some fundamental aspects of modeling of liquid permeation in the powder bed, and process capabilities and advantages of BJ-AM technology.
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in Failures Related to Metal Additive Manufacturing
> Analysis and Prevention of Component and Equipment Failures
Published: 30 August 2021
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Published: 15 June 2020
Fig. 10 Advanced mold design for sand casting enabled by binder jet additive manufacturing. Source: Ref 49
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Published: 15 June 2020
Fig. 1 Binder-jet process cycle. Top left image from Ref 27 . Other images adapted from Ref 28 .
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Published: 15 June 2020
Fig. 2 (a) Image of a layer of powder in mid-print in the binder jet process and (b) depowdering after the curing step. Source: Ref 29
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Published: 15 June 2020
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Published: 15 June 2020
Fig. 7 Consumer and industrial products created using the ExOne binder jet system. Source: Ref 45
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Published: 15 June 2020
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in Additive Manufacturing of Tungsten, Molybdenum, and Cemented Carbides
> Additive Manufacturing Processes
Published: 15 June 2020
Fig. 6 Morphology of a typical WC-12%Co powder (GTP AM WC701) for binder jet three-dimensional printing
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in Additive Manufacturing of Tungsten, Molybdenum, and Cemented Carbides
> Additive Manufacturing Processes
Published: 15 June 2020
Fig. 7 Etched microstructures of binder-jet-printed WC-12%Co pressure sintered at 1485 °C (2705 °F) for 30 min
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in Additive Manufacturing of Tungsten, Molybdenum, and Cemented Carbides
> Additive Manufacturing Processes
Published: 15 June 2020
Fig. 10 Plot showing wear resistance of binder jet three-dimensional printing (BJ3DP)-processed WC-12%Co compared to standard grades. Source: Ref 20
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in Additive Manufacturing of Tungsten, Molybdenum, and Cemented Carbides
> Additive Manufacturing Processes
Published: 15 June 2020
Fig. 11 Mud pump component fabricated by binder jet three-dimensional printing using WC-12% Co (GTP AM WC701) powder
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Published: 15 June 2020
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Published: 15 June 2020
Fig. 14 Micrographs showing binder jet copper (a) after sintering and (b) after hot isostatic pressing (HIP). Some grain coarsening is evident after HIP. Source: Ref 43
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Published: 15 June 2020
Fig. 45 Improvement in copper purity for binder jet additive-manufactured components sintered in a reducing atmosphere consisting of hydrogen. The sintering conditions for each median powder size were 1000 °C (1830 °F) for 4 h for 75 μm powder, 1060 °C (1940 °F) for 2 h for 16 μm powder
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Published: 15 June 2020
Fig. 46 Density and volumetric shrinkage of binder-jet-consolidated copper powder (15 μm median size, 96.3% purity) sintered at 1060 °C (1940 °F) for 2 h in both reducing and nonreducing atmospheres. Source: Ref 42
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in Binder Jet Additive Manufacturing of Biomaterials
> Additive Manufacturing in Biomedical Applications
Published: 12 September 2022
Fig. 1 Binder jet printing. (a) Photographs and schematic diagram of a typical binder jetting process. Reprinted from Ref 8 with permission from Elsevier. Schematic depiction of two different types of powder-feeding techniques: (b) A hopper. Reprinted from Ref 9 under Creative Commons
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Published: 12 September 2022
Fig. 3 Schematic diagrams of (a) binder jet printing and (b) piezoelectric direct inkjetting in the manufacturing of bone tissue engineered scaffolds and soft tissue engineered prevasculated scaffolds. (a) Reprinted from Ref 1 with permission. Copyright © 2019 American Chemical Society. (b
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Published: 12 September 2022
Fig. 9 (a, b) Osteoblast cell metabolic activity and proliferation on binder-jet-printed Ti-6Al-4V scaffolds showed either equivalent or better results in all time-points of culture. (c) Similar trends were exhibited by fibroblasts in terms of proliferation on the binder-jet-printed Ti-6Al-4V
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