In-situ synthesis of core-shell structure W(WC) composite grains in W-Cu composites fabricated by infiltration

•WC was synthesized in-situ by pre-sintering W compact with binder as C source.•The carbonized W-Cu composites showed pure phase composition.•W-Cu composites with WC showed improved high-temperature strength.•W-Cu composites with WC exhibited increased wear resistance. WC strengthened W-Cu composite...

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Bibliographic Details
Published in:Journal of alloys and compounds 2021-05, Vol.864, p.158633, Article 158633
Main Authors: Chen, Qiao, Li, Lvda, Man, Xucun, Sui, Han, Liu, Jinping, Guo, Shengda, Zhang, Jianbo
Format: Article
Language:English
Subjects:
Coefficient of friction
Compressive strength
Control stability
Copper
Core-shell structure
Hardness
High temperature
High-temperature compressive performance
Infiltration
Mechanical properties
Particulate composites
Phase composition
W-Cu composites
WC in-situ synthesis
Wear resistance
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Summary:•WC was synthesized in-situ by pre-sintering W compact with binder as C source.•The carbonized W-Cu composites showed pure phase composition.•W-Cu composites with WC showed improved high-temperature strength.•W-Cu composites with WC exhibited increased wear resistance. WC strengthened W-Cu composites have attracted much attention due to their high hardness, excellent wear resistance and well high-temperature mechanical properties. In this study, a convenient method was proposed to prepare WC strengthened W-Cu composites by in-situ solid-state reaction with binder as carbon source. The stable carbonization process was determined by thermodynamic calculation and experiments. By infiltrating copper into carbonized W skeleton, the W-Cu composite strengthened by core-shell structure W(WC) composite grain showed pure phase composition and uniform microstructure. The carbonized W-Cu composite with 1 wt% PF exhibited higher relative density of 99.4%, higher hardness of 259.7 HV, higher conductivity of 46.9%IACS compared with traditional W-Cu composite. The average friction coefficient (0.58) and mass loss (0.31 g) of carbonized WC-Cu composites 1 wt% PF were lower than those of conventional WC-Cu composites (0.76, 1.56 g). Meanwhile, the high-temperature compressive strength of carbonized W-Cu composite was higher than traditional W-Cu composite. The new method had high feasibility in the aspects of process stability and cost control advantage.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2021.158633