Investigation of microstructure and mechanical properties at low and high temperatures of WC–6wt% Co

Investigation of microstructure and mechanical properties at low and high temperatures of WC–6wt% Co

The correlations of the microstructure, room temperature hardness and toughness, and high temperature compressive stress and strain of a series of WC–6wt% Co materials with grain sizes at sub-micrometer ranges (<0.30μm) have been investigated. It is found that the average size and size distributi...

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Bibliographic Details
Published in:International journal of refractory metals & hard materials Vol. 58; pp. 172 - 181
Main Authors: Emani, Satyanarayana V., Ramos dos Santos, Ana Flavia C., Shaw, Leon L., Chen, Zheng
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-08-2016
Subjects:
Compressive properties
Fracture mechanics
Fracture toughness
Grain size
Grain size distribution
Hardness
High temperature properties
Microstructure
Strain
Stresses
Toughness
WC-Co
Grain size
High temperature properties
Toughness
WC-Co
Hardness
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Summary:The correlations of the microstructure, room temperature hardness and toughness, and high temperature compressive stress and strain of a series of WC–6wt% Co materials with grain sizes at sub-micrometer ranges (<0.30μm) have been investigated. It is found that the average size and size distribution of WC grains play a critical role in both room temperature and high temperature (600 and 800°C) properties. Furthermore, the maximum compressive stresses at 600 and 800°C increase with increasing the room temperature hardness and decreasing grain sizes. However, the fracture strain in compression at 600 and 800°C cannot be predicted from the room temperature toughness. This absence of a relationship is attributed to the facts that the fracture strain of compressive tests at high temperatures is dictated by significant plastic flow of the Co phase, whereas the toughness at room temperature is controlled by crack propagation with little plasticity. In general, small grain sizes (at ~0.20μm) with or without a bi-modal grain size distribution are beneficial to the maximum compressive stress and fracture strain at 600 and 800°C. In contrast, grain sizes at ~0.27μm with a bi-modal grain size distribution are good for room temperature toughness, but offer inferior high temperature compressive stresses and fracture stains. Thus, the design of the microstructure at a fixed Co composition depends on the intended applications. •Properties of WC–6wt% Co with grain sizes at submicrometer ranges are studied.•Grain size and size distribution play a critical role in high temperature properties.•Compressive stresses at 600 and 800°C increase with the room temperature hardness.•Fracture strains at 800°C are not related to the room temperature toughness.•Small grain sizes (~0.20μm) are beneficial to properties at both 600 and 800°C.
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ISSN:0263-4368
2213-3917
DOI:10.1016/j.ijrmhm.2016.04.009