• Title/Summary/Keyword: 0.14C-6.5Mn TRIP steel

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Effect of Fabrication Processes on the Mechanical Properties of 0.14C-6.5Mn TRIP Steels (0.14C-6.5Mn TRIP강의 기계적 성질에 미치는 제조공정의 영향)

  • Lee, O-Yeon;Ryu, Seong-Il
    • Korean Journal of Materials Research
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    • v.11 no.5
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    • pp.431-437
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    • 2001
  • This research was examined the effect of intercritical heat treatment on the mechanical Properties and retained austenite formation in 0.1C-6.5Mn steels for the development of a high strength high ductility steel. using of transformation induced plasticity due to retained austenite. The stability of retained austenite is very important for the good ductility and it depend on diffusion of carbon and manganese during reverse transformation. It is effective to heat treat at$ 645^{\circ}C$ in order to obtain over 30 vol.% of retained austenite. However, it is more desirable to heat treat at $620^{\circ}C$, considering the volume fraction and mechanical stability of retained austenite. The strength-elongation combination in cold rolled steel sheets after reverse transformed at $620^{\circ}C$ for 1hr was about 4000k9/mm7, but it decreased rapidly with increasing holding time at high temperature due to the decrease of ductility. The addition of 1.1%Si in 0.14C-6.5Mn TRIP steel does not improve the mechanical properties and retained austenite formation.

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Effect of Reverse Transformation on the Microstructure and Retained Austenite Formation of 0.14C-6.SMn Alloy Steel (0.14C-6.5Mn 합금강의 미세조직과 잔류오스테나이트 형성에 미치는 역변태처리의 영향)

  • Song, K.H.;Lee, O.Y.
    • Journal of the Korean Society for Heat Treatment
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    • v.13 no.4
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    • pp.253-258
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    • 2000
  • The present study aimed to develop the TRIP(transformation induced plasticity) aided high strength low carbon steel sheets using reverse transformation process. The cold-rolled 0.14C-6.5Mn steel was reverse-transformed by slow heating to intercritical temperature region and air cooling to room temperature. An excellant combination of tensile strength and elongation of $98.3kgf/mm^2$ and 44.4% appears. This combination comes from TRIP phenomena of retained austenite during deformation. The stability of retained austenite Is very Important for the good ductility and it depends on diffusion of carbon and manganese during reverse transformation. The air cooling after holding at intercritical temperature retards the formation of pearlite and provides the carbon enrichment in retained austenite, resulting the increase of elongation in cold-roiled TRIP steel.

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Effect of Reverse Transformation Treatment on the Formation of Retained Austenite and Mechanical Properties of C-Mn TRIP Steels (C-Mn계 TRIP강의 잔류오스테나이트 생성과 기계적 성질에 미치는 역변태처리의 영향)

  • You J. S;Hong H;Lee O. Y;Jin K. G;Kim S. J
    • Korean Journal of Materials Research
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    • v.14 no.2
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    • pp.126-132
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    • 2004
  • The high strength steel sheets has been widely used as the automobile parts to reduce the weight of a vehicle. The aim of this research is to develop the TRIP aided high strength low carbon steels using reverse transformation process. The 0.15C-4Mn and 0.15C-6.5Mn steel sheets were reversely transformed by slow heating to intercritical temperature region and air cooling to room temperature. The stability of retained austenite depends on the enrichment of carbon and manganese by diffusion during the reverse transformation. The amount of retained austenite formed after reversely transformed at $645^{\circ}C$ for 12 hrs. was about 46vol.% in hot rolled 0.lC-6.5Mn steel. The change in volume fraction of retained austenite with a holding temperature was consistent with the changes in elongation and the strength-ductility combination. The tendency of tensile strength to increase with increasing the holding temperature was due to the decrease of retained austenite after cooling from the higher temperature of $670 ^{\circ}C$. The maximum strength-ductility combination was about 4,250 kg/$\textrm{mm}^2$ㆍ% when the hot rolled 0.lC-6.5Mn steel was reversely transformed at $645^{\circ}C$ for 12 hrs.