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Vol.55, No.12, 825 ~ 836, 2017
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| Title |
| Effect of Cooling Rate on the Microstructure and Mechanical Properties of Fe-Mn-Al-C Light-Weight Steels |
| 박준영 Jun Young Park , 박성준 Seong-jun Park , 이재현 Jae-hyun Lee , 문준오 Joonoh Moon , 이태호 Tae-ho Lee , 정경재 Kyeong Jae Jeong , 한흥남 Heung Nam Han , 신종호 Jong-ho Shin |
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| Abstract |
| The effects of cooling after solution heat treatment on the microstructure and mechanical properties of light-weight steels were investigated using Fe-30Mn-xAl-0.9C alloys containing 9.0-12.8 wt% Al. Lab-scale specimens (thickness: 10 mm) of the alloys were cooled by different cooling rates from -337 to -0.053 ℃/s using water, air, and furnace cooling. As the cooling rate decreased, hardness of the alloys increased due to precipitation of κ-carbides. However, reduction of the cooling rate induced the growth of intergranular κ-carbides. This resulted in the decrease of impact absorbed energy of the alloys at room temperature, and exhibited intergranular brittle fracture behavior. The 12.8 wt% Al alloy cooled at the slowest cooling rate in particular showed the formation of β-Mn. To estimate the cooling rates of large-scale slabs of light-weight steels, finite element simulations were conducted. The cooling rates at the center of the slab under air and water cooling (free convection) were calculated to be -0.049 and -0.15 ℃/s, respectively. The results indicated that water cooling could prevent the excessive formation of κ-carbides/β-Mn during fabrication of large-scale slabs of alloys containing an Al content lower than 10.5 wt%.
(Received September 1, 2017; Accepted September 20, 2017) |
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| Key Words |
| light-weight steel, microstructure, cooling rate, κ-carbide, β-Mn |
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