研究者業績
基本情報
- 所属
- 兵庫県立大学 工学研究科材料・放射光工学専攻 助教 (博士(工学))
- 学位
- 博士(工学)(京都大学)
- J-GLOBAL ID
- 201801010710306129
- researchmap会員ID
- B000322889
研究分野
1経歴
1-
2017年4月 - 現在
学歴
3-
2013年4月 - 2017年3月
-
2009年4月 - 2011年3月
-
2005年4月 - 2009年3月
受賞
2論文
16-
日本金属学会誌 87(9) 249-257 2023年9月1日 査読有り
-
Materials Performance and Characterization 11(2) 315-331 2022年6月 査読有り
-
International Journal of Automation Technology 16(1) 95-103 2022年1月 査読有り
-
Materials Science and Engineering: A 826 141972 2021年9月 査読有り
-
Materials Characterization 179 111379 2021年8月 査読有り
-
Scripta Materialia 200 113896 2021年4月 査読有り
-
Mechanics of Materials 157 103816 2021年3月 査読有り
-
Materials Science and Engineering: A 794 139984 2020年9月 査読有り
-
MATERIALS TRANSACTIONS 61(3) 522-527 2020年3月 査読有り
-
Materials Research Express 6 2018年10月 査読有り
-
Materials Science Forum 941 MSF 346-351 2018年© 2018 Trans Tech Publications, Switzerland. Medium manganese steels are nowadays energetically investigated as the third generation advanced high strength steels (AHSS) because of their excellent balance between material cost and mechanical properties. However, the phase transformation and microstructure evolution in medium manganese steels during various heat treatments and thermomechanical processing are still unclear. The present study firstly examined kinetics of static phase transformation behavior and microstructural change in a 3Mn-0.1C medium manganese steel. Hot compression tests were also carried out to investigate the influences of high-temperature thermomechanical processing on the microstructure evolution. It was found that ferrite transformation was quite slow in static conditions but greatly accelerated by hot compression in (austenite and ferrite) two phase region. Dual phase microstructures composed of martensite and ferrite with ferrite grain sizes of 1~2 μm were obtained, which exhibited superior mechanical properties.
-
THERMEC 2018: 10TH INTERNATIONAL CONFERENCE ON PROCESSING AND MANUFACTURING OF ADVANCED MATERIALS 941 346-351 2018年Medium manganese steels are nowadays energetically investigated as the third generation advanced high strength steels ( AHSS) because of their excellent balance between material cost and mechanical properties. However, the phase transformation and microstructure evolution in medium manganese steels during various heat treatments and thermomechanical processing are still unclear. The present study firstly examined kinetics of static phase transformation behavior and microstructural change in a 3Mn-0.1C medium manganese steel. Hot compression tests were also carried out to investigate the influences of high-temperature thermomechanical processing on the microstructure evolution. It was found that ferrite transformation was quite slow in static conditions but greatly accelerated by hot compression in ( austenite and ferrite) two phase region. Dual phase microstructures composed of martensite and ferrite with ferrite grain sizes of 1 similar to 2 mu m were obtained, which exhibited superior mechanical properties.
-
Materials Science Forum 879 90-94 2017年As third generation advanced high strength steels (AHSS) managing both high strength and good ductility/formability, medium manganese steels containing 3-7 wt% Mn have attracted attentions recently. However, the fundamental microstructure evolution during thermomechanical processing and heat treatments in medium-Mn steels is still unclear. In the present study, changes in microstructure and mechanical properties during various heat treatments and thermomechanical processes of 4Mn-0.1%C steel were studied. It was clarified from dilatometric measurements thatferrite transformation in the 4Mn-0.1C steel was quite slow, so that fully martensitic structures were obtained in many cases after cooling from austenite. On the other hand, hot-deformation of austenite greatly accelerated ferrite transformation, and dual phase microstrcutures composed of ferrite and martensite could be obtained. The dual phase steel showed good combinations of high strength and adequate tensile ductility.
MISC
3-
ISIJ International 60(4) 764-773 2020年4月15日Ultrafine ferrite + austenite steels with the chemical composition of 0.1%C-2%Si-5wt%Mn show excellent strength (TS=1200 MPa) and high ductility (TEl=25%) balance, compared to conventional TRIP steels. This steel is expected as the third generation advanced high-tensile strength steels (AHSS). This steel can be produced by a simple intercritical annealing, however, longer annealing time is necessary to obtain appropriate ferrite + austenite structure. It is difficult to produce this steel by continuous annealing process. If the annealing time can be drastically reduced, this new TRIP steels can be commercialized. We focused on the effect of the prior microstructures before annealing on the formation of ferrite + austenite structure. The effect of the prior structure is not clear. Therefore, in this study, two kind of prior structures, ultrafine grained ferrite + cementite and martensite were used in 0.1%C-2%Si-5wt%Mn steels. It was found that the prior structure of ferrite + cementite can form large amount (20%) of austenite in a very short time (600 s). This is because cementite finely dispersed in the structure effectively acts as a preferential nucleation site of reverse transformed austenite and C and Mn are concentrated in cementite to enable a short time formation of austenite. Excellent strength-ductility balance (32000 MPa%) which is superior to conventional TRIP steels is also obtained.
講演・口頭発表等
48共同研究・競争的資金等の研究課題
1-
日本学術振興会 科学研究費助成事業 2022年4月 - 2025年3月