Fabrication of TiN–Ni and TiN–Co Cermets by Mechanical Milling and Subsequent Pulsed Current Sintering and Their Fracture Strength

Fabrication of TiN–Ni and TiN–Co Cermets by Mechanical Milling and Subsequent Pulsed Current Sintering and Their Fracture Strength

TiN–Ni and TiN–Co cermets were fabricated by mechanical milling of TiN and Ni or Co powders, followed by pulsed current sintering. The microstructure of the TiN–Ni and TiN–Co cermet samples prepared from the non-milled powder contained a large number of pores. However, these pores were eliminated fr...

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Bibliographic Details
Published in:MATERIALS TRANSACTIONS Vol. 53; no. 6; pp. 1029 - 1033
Main Authors: Nakayama, Hiroyuki, Ozaki, Kimihiro, Kobayashi, Keizo
Format: Journal Article
Language:English
Published: Sendai The Japan Institute of Metals and Materials 2012
Japan Science and Technology Agency
Subjects:
bending strength
fracture surface
hard material
transverse rupture strength
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Summary:TiN–Ni and TiN–Co cermets were fabricated by mechanical milling of TiN and Ni or Co powders, followed by pulsed current sintering. The microstructure of the TiN–Ni and TiN–Co cermet samples prepared from the non-milled powder contained a large number of pores. However, these pores were eliminated from both the sintered samples through mechanical milling of the powders. Relative densities of over 98% were achieved. Mechanical milling also improved the three-point bending strength of the cermet samples. In this study, the samples sintered from the powders milled for 28.8 ks exhibited the maximum strength, i.e., the strength of TiN–Ni and TiN–Co ceremets was 1.4 and 1.2 GPa, respectively. The fracture surface of the sample sintered from the non-milled powders was intergranular whereas that of the sample sintered from the milled powder was both intergranular and transgranular in nature.
ISSN:1345-9678
1347-5320
DOI:10.2320/matertrans.MBW201109