Effect of deep cryogenic treatment on the fracture toughness and wear resistance of WC-Co cemented carbides

The main failure causes of cemented carbide tools are fracture and wear. However, for the most of cemented carbide materials, fracture toughness can usually be increased at the expense of wear resistance by traditional modification technologies. In the present investigation, a novel method, deep cry...

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Bibliographic Details
Published in:International journal of refractory metals & hard materials 2019-12, Vol.85, p.105059, Article 105059
Main Authors: Weng, Zeju, Gu, Kaixuan, Wang, Kaikai, Liu, Xuanzhi, Cai, Huikun, Wang, Junjie
Format: Article
Language:English
Subjects:
Carbide tools
Cemented carbides
Cobalt
Cryogenic effects
Cryogenic engineering
Cryogenic properties
Cryogenic treatment
Deep cryogenic treatment
Densification
Fracture mechanics
Fracture toughness
Martensitic transformations
Microcracks
Microstructures
Morphology
Optical microscopy
Optical properties
Scanning electron microscopy
Spalling
Tool wear
Tungsten carbide
WC-20Co cemented carbides
Wear resistance
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Summary:The main failure causes of cemented carbide tools are fracture and wear. However, for the most of cemented carbide materials, fracture toughness can usually be increased at the expense of wear resistance by traditional modification technologies. In the present investigation, a novel method, deep cryogenic treatment, is conducted to optimize the properties of WC-20Co cemented carbides. The methods of optical microscopy (OM) and scanning electron microscopy (SEM) are used to detect and analyze the fracture paths, fractographic features and worn surfaces of cemented carbides before and after deep cryogenic treatment. The changes of microstructure are examined by SEM and X-ray diffractometer (XRD). The results show that deep cryogenic treatment can improve both fracture toughness and wear resistance of WC-20Co cemented carbides successfully. Compared to the as-sintered specimens, there exist more trans-crystalline fracture, micro-cracks and torn metallic zones in the fracture morphology, and less wear and spalling on the worn surfaces in cryogenically treated specimens. The enhancement of fracture toughness can be attributed to densification and homogenization caused by deep cryogenic treatment. The main reason for the improved wear resistance is that deep cryogenic treatment has promoted the martensitic transformation of fcc α-Co into hcp ε-Co. •Both fracture toughness and wear resistance were improved by deep cryogenic treatment.•Optimal cryogenic processes for specific properties were obtained.•Using systematic methods to reveal the strengthening mechanisms
ISSN:0263-4368
2213-3917
DOI:10.1016/j.ijrmhm.2019.105059