Cast WC-Co alloy-based tool manufacturing using a polymeric mold prepared via digital light processing 3D printing

•A cost-effective and rapid method for manufacturing cutting tools is investigated.•Samples obtained from slurry cast exhibit adequate hardness and fracture toughness.•Results validate the manufacture of cutting tools without expensive metal molds.•Complex shapes can be implemented precisely in deve...

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Bibliographic Details
Published in:Materials letters 2022-01, Vol.306, p.130979, Article 130979
Main Authors: Kim, Hakhyun, Kim, Jong-Il, Ryu, Sung-Soo, Jeong, Hyeondeok
Format: Article
Language:English
Subjects:
3-D printers
Carbide tools
Cast alloy tools
Cemented carbides
Cobalt base alloys
Cutting tool
Cutting tools
DLP 3D printing
Fracture toughness
Machining
Manufacturing
Materials science
Melting points
Molds
Product development
Refractivity
Rheological properties
Slurries
Slurry casting
Slurry dispersion
Three dimensional models
Three dimensional printing
Tungsten carbide
WC-Co
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Summary:•A cost-effective and rapid method for manufacturing cutting tools is investigated.•Samples obtained from slurry cast exhibit adequate hardness and fracture toughness.•Results validate the manufacture of cutting tools without expensive metal molds.•Complex shapes can be implemented precisely in development stage via 3D printing. Tungsten carbide-Cobalt (WC-Co), also known as cemented carbide, is a widely used alloy to manufacture high-performance tools for mining, drilling, cutting, and machining applications. Due to the high melting point of WC, it is challenging to cast it to manufacture products. Therefore, in this study, we investigated a method for manufacturing cutting tools from WC-Co alloy using high-precision digital light processing-based three-dimensional (3D) printing technology. The high refractive index of WC renders it difficult to directly apply it to photocurable 3D printing. Therefore, a polymer mold was fabricated via 3D printing to obtain a WC-Co slurry cast. Rheological studies were performed to optimize the slurry composition. After slurry casting and drying, a green body was formed, which was sintered at 1400 °C to obtain a defect-free sample with a shape identical to that of the 3D model. The cast sample exhibited identical characteristics (microstructure, hardness, and fracture toughness) to those of conventional press-molded sample. The results of this study confirm that complex cutting tool manufacturing is possible without using expensive metal molds. The presented approach is expected to significantly reduce the cost and time incurred during the product development stage involving multiple designs.
ISSN:0167-577X
1873-4979
DOI:10.1016/j.matlet.2021.130979