Phase Transformation Mechanism of Fe-Cu Alloys
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概要
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Fe-(0.5-4)mass%Cu alloys were cooled from γ field under various cooling conditions (water-quenching, air-cooling, furnace-cooling) and phase transformation mechanisms were investigated by means of microstructural examinations and dilatometry. In all of the cooling conditions, hardness of Fe-Cu alloys becomes higher with increasing Cu content. Effect of cooling conditions on hardness tends to be significant in alloys with Cu more than 1 mass%. TEM observation shows that strength of alloys depends not only on a difference of matrix; martensite or ferrite, but also on dispersion of ε-Cu particles. In the case of air-cooling for an Fe-4mass%Cu alloy, the alloy undergoes preferentially γ→α massive transformation and then ε-Cu particles precipitates finely within the massive ferrite matrix. This leads to a large strengthening with a moderate ductility. Strength of Cu bearing steels can easily be controlled by varying cooling condition after a solution-treatment: Steels are soft enough to be deformed and machined after furnace-cooling, but strengthened after resolution-treatment followed by air-cooling.
- 社団法人 日本鉄鋼協会の論文
- 1997-03-15
著者
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Takaki Setsuo
Department of Materials Science and Engineering, Kyushu University
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KIMURA Yuuji
Department of Materials Science and Engineering, Kyushu University
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Kimura Y
Kyushu Univ. Fukuoka‐ken Jpn
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Kimura Yuuji
Structural Metals Center National Institute Of Materials Science
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Kimura Yuuji
Department Of Materials Science And Engineering Kyushu University
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Kimura Yuuji
Materials Engineering Group Department Of Materials Physics And Chemistry Graduate School Of Enginee
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Takai S
Department Of Materials Science And Engineering Faculty Of Engineering Kyushu University
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Takaki Setsuo
Department Of Material Science And Engineering Kyushu University
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Kimura Yuuji
Structural Metals Center National Institute For Materials Science
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