Investigation on preparation and mechanical properties of W–Cu–Zn alloy with low W–W contiguity and high ductility

In order to improve the mechanical properties of the W–Cu alloy, the W–Cu–Zn alloys with low W–W contiguity were fabricated by three different preparation methods. For the first method, the mixed powder of copper-coated tungsten powder and Zn powder was sintered by SPS (Spark Plasma Sintering) proce...

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Bibliographic Details
Published in:Materials & design 2015-12, Vol.86, p.297-304
Main Authors: Zheng, Lingling, Liu, Jinxu, Li, Shukui, Wang, Guohui, Guo, Wenqi
Format: Article
Language:English
Subjects:
COMPRESSIVE PROPERTIES
Compressive strength
COPPER ZINC ALLOYS
Density
Ductility
Dynamic mechanical properties
FAILURE
Infiltration
MECHANICAL PROPERTIES
Precipitation hardening
PROPERTIES
SINTERING
Spark plasma sintering
SPARK SINTERING
Tungsten
TUNGSTEN ALLOYS (50 TO 99 W)
Tungsten base alloys
W–Cu–Zn alloy
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Summary:In order to improve the mechanical properties of the W–Cu alloy, the W–Cu–Zn alloys with low W–W contiguity were fabricated by three different preparation methods. For the first method, the mixed powder of copper-coated tungsten powder and Zn powder was sintered by SPS (Spark Plasma Sintering) process. For the second method, the mixed powder was processed by CIP (Cold Isostatic Pressing) before SPS. For the third method, a skeleton of the copper-coated tungsten powder was prepared by CIP, and then the skeleton was infiltrated with H70 brass. The microstructure, mechanical properties and failure mechanism of the prepared W–Cu–Zn alloys were investigated. The results show that the W–Cu–Zn alloy fabricated by the third method achieves a high relative density of 98.4% and a low W–W contiguity of 10%. The alloy exhibits a high dynamic compressive strength of 1000MPa, with a high critical failure strain of 0.7. The Cu-Zn matrix of the alloy fabricated by the third method is composed of α-phase Cu–Zn alloy and Cu3Zn particles. The homogeneous distribution of Zn in the matrix manifests good solution strengthening effect and the uniformly distributed Cu3Zn particles has a strong precipitation strengthening effect, which are both responsible for the evidently enhanced mechanical properties. The preparation process of infiltration method. [Display omitted] •Electroless plating, CIP and infiltration are combined as a new preparing method.•A method for preparing the W–Cu–Zn alloy with low W–W contiguity was proposed.•The failure mechanism of the W–Cu–Zn alloy was revealed.•The W–Cu–Zn alloy with low W content and high mechanical properties was fabricated.
ISSN:0264-1275
1873-4197
DOI:10.1016/j.matdes.2015.07.106