Fabrication and characterization of ultra-fine grained pure tungsten by two fast resistance sintering technologies

Chin J Mater Res

2009, Vol. 23

Issue (2): 113-117 DOI:

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Fabrication and characterization of ultra-fine grained pure tungsten by two fast resistance sintering technologies

ZHOU Zhangjian; DU Juan; MA Yao

School of Materials Science and Engineering; University of Science and Technology Beijing; Beijing 100083

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ZHOU Zhangjian DU Juan MA Yao. Fabrication and characterization of ultra-fine grained pure tungsten by two fast resistance sintering technologies. Chin J Mater Res, 2009, 23(2): 113-117.

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Abstract

Pure tungsten with ultra-fine grain size has been fabricated by a novel sintering method combined resistance sintering with ultra high pressure in the absence of any additives. The relative density of the fabricated material is 97.9% and the average grain size is less than 1 μm. the density of the sintered sample is mainly contributed by the applied ultra high pressure, while the resistance sintering benefit for high mechanical properties of the sintered material. Compared to another fast resistance sintering technology spark plasma sintering, resistance sintering under ultra high pressure shows the advantage of not only retaining the fine grain size, but also further refining the grain size during consolidation.

Key words: metallic materials tungsten ultra fine grain resistance sintering ultra high pressure

Received: 22 October 2008

ZTFLH:

TG146

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Supported by National Nature Science Foundation of China No.50634060 and the National Basic Research Program of China under grant No.2007ID102.

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https://www.cjmr.org/EN/ OR https://www.cjmr.org/EN/Y2009/V23/I2/113

1 R.M.German, J.Ma, X.Wang, E.Olevsky, Processing model for tungsten powders and extension to nanoscale
size range, Powder Metallurgy, 49(1), 19(2006)
2 ZOU Fangleng, Patent status of nano scale tungsten products of China, China Molybdenum Industry, 29(1), 11(2005)
(邹仿棱, 国内纳米钨系列产品的专利状况浅析, 中国钼业, 29(1), 11(2005))
3 YE Tuming, YI Jianhong, PENG Yundong, HU Lifu, LV Yuxiang, Progress in research on nano-crystalline high density tungsten-based alloys, Rare Metal, 28, 726 (2004)
(叶途明, 易健宏, 彭元东, 胡礼福, 吕豫湘, 纳米晶高密度钨合金的研究进展, 稀有金属, 28, 726(2004))
4 QU Xuanhui, FAN Jinglian, Powder injection molding and solid-state sintering of nano-crystalline tungsten heavy alloy, Chinese Journal of Materials Research, 15, 130(2001)
(曲选辉, 范景莲, 纳米晶钨基重合金粉末的注射成型与固相烧结, 材料研究学报, 15, 130(2001))
5 J.Mohit, S.Ganesh, M.Krista, K.Deepak, C.Kyu, K.Bradley, D.Robert, A.Dinesh, J.Cheng, Microwave sintering: A new approach to fine-grain tungsten-I, International Journal of Powder Metallurgy, 42(2), 45(2006)
6 Y.Kitsunai, H.Kurishita, H.Kayano, Y.Hiraoka, T.Igarashi, T.Takida, Microstructure and impact properties of ultra-fine grained tungsten alloys dispersed with TiC, Journal of Nuclear Materials, 271-272, 423(1999)
7 J.Mohit, S.Ganesh, M.Krista, C.Kyu, K.Bradley, D.Robert, K.Deepak, A.Dinesh, J.Cheng, Microwave sintering: A new approach to fine-grain tungsten-II, International Journal of Powder Metallurgy, 42(2), 253(2006)
8 Z.A.Munir, U.Anselmi-tamburini, M.Ohyanagi, The effect of electric field and pressure on the synthesis and consolidation of materials: A review of the spark plasma sintering method, Journal of Materials Science, 41, 763(2006)
9 K.Moon, H.Park, K.Lee, Consolidation of nanocrystalline Al-5at.% Ti alloy powders by ultra high-pressure hot pressing, Materials Science and Engineering A, 323, 293(2002)
10 WANG Zhifa, JIANG Guoshen, LIU Zhengchun, Ultrapressure Forming and Low-Temperature Sintering of Tungsten, Rare Metal Materials and Engineering, 27(5), 290(1998)
(王志法, 姜国圣, 刘正春, 钨的超高压成型与低温烧结, 稀有金属材料与工程, 27(5), 290(1998))
11 ZHOU Yusong, WU Xijun, LI Binghan, XU Guoliang, Synthesis of bulk samples of nanocrystalline tungsten, Chinese Journal of High Pressure Physics, 14(3), 291(2000)
(周宇松, 吴希俊, 李冰寒, 许国良, 采用真空热压技术制备纳米金属钨块体材料, 高压物理学报, 14(3), 291(2000))
12 Z.Zhou, J.Du, S.Song, C.Ge, Microstructural Characterization of W-Cu Functionally Graded Materials by one step resistance sintering method, Journal of Alloy and Compound, 428, 146(2007)

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