Enviar artigo por via de e-mail Microstructures and Properties of Fe–Co–Cu Pre-Alloyed Powder for Geological Diamond Bits
- Autores: Xie D.1, Qin H.1, Lin F.1, Pan X.1, Chen C.1, Xiao L.1, Chen J.1, Mo P.1
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Afiliações:
- Guangxi Key Laboratory of Superhard Materials, Chinese National Engineering Research Center for Special Mineral Materials
- Edição: Volume 41, Nº 5 (2019)
- Páginas: 302-309
- Seção: Production, Structure, Properties
- URL: https://journals.rcsi.science/1063-4576/article/view/186593
- DOI: https://doi.org/10.3103/S1063457619050022
- ID: 186593
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Resumo
For geological diamond bits Fe–Co–Cu alloys are the a generation of metal matrix. In this paper, the Fe–Co–Cu pre-alloys with various chemical compositions were synthesized using the co-precipitation method, which were subsequently sintered at different temperatures. The structural, thermal and properties of the powders and its sintered materials were characterized by various techniques. X-ray diffraction studies indicated that solid solutions were formed for the alloys during co-precipitation process. Microstructures of these pre-alloyed powders exhibited that the sintering process was facilitated by the irregular shapes, interconnected fine particles as well as the large surface areas. The thermal effects of the pre-alloyed powders were explored by differential scanning calorimetry. The optimal sintering temperature for each pre-alloyed powder was determined by the mechanical analysis. Scanning electron microscopic results show that the composition ratio of Fe and Cu had a significant impact on the microstructures of the sintered materials, and the 65%Fe-20%Cu-15%Co alloy reached the best surface coverage over the diamond bits. The drilling performances for various pre-alloyed powders were verified by micro-drilling experiments. Those results suggested that the 65%Fe-20%Cu-15%Co alloy exhibited the optimal performance for application in geological diamond drilling bits.
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Sobre autores
Delong Xie
Guangxi Key Laboratory of Superhard Materials, Chinese National Engineering Research Center for Special Mineral Materials
Autor responsável pela correspondência
Email: xiedelonghn@foxmail.com
República Popular da China, Guilin, 541004
Haiqing Qin
Guangxi Key Laboratory of Superhard Materials, Chinese National Engineering Research Center for Special Mineral Materials
Email: xiedelonghn@foxmail.com
República Popular da China, Guilin, 541004
Feng Lin
Guangxi Key Laboratory of Superhard Materials, Chinese National Engineering Research Center for Special Mineral Materials
Email: xiedelonghn@foxmail.com
República Popular da China, Guilin, 541004
Xiaoyi Pan
Guangxi Key Laboratory of Superhard Materials, Chinese National Engineering Research Center for Special Mineral Materials
Email: xiedelonghn@foxmail.com
República Popular da China, Guilin, 541004
Chao Chen
Guangxi Key Laboratory of Superhard Materials, Chinese National Engineering Research Center for Special Mineral Materials
Email: xiedelonghn@foxmail.com
República Popular da China, Guilin, 541004
Leyin Xiao
Guangxi Key Laboratory of Superhard Materials, Chinese National Engineering Research Center for Special Mineral Materials
Email: xiedelonghn@foxmail.com
República Popular da China, Guilin, 541004
Jiarong Chen
Guangxi Key Laboratory of Superhard Materials, Chinese National Engineering Research Center for Special Mineral Materials
Email: xiedelonghn@foxmail.com
República Popular da China, Guilin, 541004
Peicheng Mo
Guangxi Key Laboratory of Superhard Materials, Chinese National Engineering Research Center for Special Mineral Materials
Email: xiedelonghn@foxmail.com
República Popular da China, Guilin, 541004
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