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興津 貴隆*; 北條 智彦*; 諸岡 聡; 宮本 吾郎*
鉄と鋼, 110(3), p.260 - 267, 2024/02
We have investigated the dynamic tensile properties of 4, 5, 6-mass%-Mn-containing low carbon steels with multi-phase microstructures containing retained austenite. The five materials used were classified into two groups. The first group of materials, with around 10% of retained austenite, showed normal strain rete dependence of yield strength (YS) and tensile strength (TS) as in conventional high strength steels. The second group of materials, containing 25-36% of retained austenite, exhibited L
ders elongation showed also normal strain rate dependence in YS and flow stress at Lders deformation, but TS varied in a complex manner. Among the second group, in the 4 Mn steel, TS was nearly constant at strain rates below 1 s
but increased slightly at higher strain rates. In the 5 and 6 Mn steels, TS once decreased up to the strain rate of 1 or 10 s, and then began to increase at higher strain rates. These behaviors were discussed in terms of temperature rise during plastic deformation causing suppression of martensitic transformation, and thermal stability of retained austenite. In the 4 Mn steel with relatively unstable retained austenite, almost all the austenite transforms regardless of strain rate. In the 5 and 6 Mn steels, where the retained austenite is moderately stable, strain induced transformation of austenite continues up to high plastic strain, providing a good balance of strength and ductility. At high strain rate, TS decreases slightly due to temperature rise, but at higher strain rates than 1 s, the strain rate sensitivity of flow stress in ferrite become prominent and the flow stress increases.
neutron diffraction study on the deformation of a TRIP-assisted multi-phase steel composed of ferrite, austenite and martensiteLavakumar, A.*; Park, M. H.*; Gao, S.*; 柴田 曉伸*; 興津 貴隆*; Gong, W.; Harjo, S.; 辻 伸泰*
IOP Conference Series; Materials Science and Engineering, 580, p.012036_1 - 012036_6, 2019/09
被引用回数:3 パーセンタイル:83.68(Engineering, Mechanical)Multi-phase steels showing transformation induced plasticity (TRIP), can exhibit an excellent combination of high strength and good ductility by the aid of martensitic transformation during deformation. Even though TRIP-assisted multi-phase steels have been widely used in industry, the role of each phase in the enhancement of mechanical properties is still unclear given their complicated microstructures. In order to understand better the nature of the TRIP effect, the mechanical interaction between different phases at the micro-scale should be clarified. In the present study, the mechanical behavior of a transformation induced plasticity (TRIP) assisted multi-phase steel, has been characterized by 
neutron diffraction during tensile testing. The result of strain partitioning between the different phases obtained from the neutron analysis revealed that the martensite phase took much more elastic strain than the ferrite and retained austenite phases, which suggests that the work hardening behavior in the present steel is affected by the higher load borne by deformation-induced martensite.
小山 元道*; 北條 智彦*; 宮本 吾郎*; 諸岡 聡; 山下 享介; 澤口 孝宏*; 峯 洋二*; 眞山 剛*; 興津 貴隆*; 榊原 睦海*; et al.
no journal, ,
高強度-高延性鋼を開発するために近年盛んに研究されてきた対象は、高Mn鋼と変態誘起塑性(TRIP)鋼である。高Mn鋼の研究を通して、Mn利用による積層欠陥エネルギーおよび相変態挙動の制御の重要性が再認識された。また、素材コストも睨みながら、従来の延性強度バランスを打破するには、未変態オーステナイトのTRIP効果を利用することが有効であるとの見方も広く受け入れられてきた。これら高Mn鋼とTRIP鋼の研究が合流する形で、TRIP効果を示す中Mn鋼が注目されている。中Mn鋼は優れた延性強度バランスを示す。しかし、複相であること、化学組成や熱処理条件に敏感であること、変形誘起マルテンサイト変態を示すこと、大きなリューダース変形を示すこと、応力ひずみ応答においてセレーションが現れること等に起因して、非常に複雑な塑性変形挙動を呈する。そのため、その優れた力学特性発現の機構は未だ不明瞭である。本講演では、その優れた力学特性の原因を組織発達および塑性変形挙動解析に基づいて明らかとするための研究戦略を示し、その妥当性と応用展開を広く議論する。
