Rietveld refinement, microstructure, mechanical properties and oxidation characteristics of Fe-28Mn-x Al-1C (x = 10 and 12 wt. %) low-density steels

IF 3.1 2区 材料科学 Q1 METALLURGY & METALLURGICAL ENGINEERING
Zhen-yi Huang , A-long Hou , Yue-shan Jiang , Ping Wang , Qi Shi , Qing-yu Hou , Xiang-hua Liu
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引用次数: 5

Abstract

The quantitative relationship between microstructure and properties of austenitic Fe-28Mn-xAl-1C (x=10 and 12 wt. %) low-density steels was evaluated using Rietveld method to refine X-ray diffraction (XRD) patterns. The results showed that a typical three-phase austenitic steel was obtained in the forged Mn28Al10 (i. e. Fe-28Mn-10Al-1C) steel, which included about 92.85 wt. % γ-Fe(Mn, Al, C) (austenite), 5.28 wt. % (Fe, Mn)3 AlC0.3 (κ-carbide), and 1.87 wt. % α-Fe(Al, Mn) (ferrite). For the forged Mn28Al12 (i. e. Fe-28Mn-12Al-1C) steel, nevertheless, only about 76.64 wt. % austenite, 9.63 wt. % κ-carbide, 9.14 wt. % ferrite and 4.59 wt. % Fe3 Al (DO3) could be obtained. Nanometer κ-carbide and DO3 were mainly distributed in austenite grains and at the interface between austenite and ferrite, respectively. The forged Mn28Al10 steel had a better combination of strength, ductility and specific strength as compared with the forged Mn28Al12 steel. The ductility of the forged Mn28Al12 steel was far lower than that of the forged Mn28Al10 steel. The oxidation kinetics of Mn28Al10 steel oxidized at 1323 K for 5–25 h had two-stage linear rate laws, and the oxidation rate of the second stage was faster than that of the first stage. Although the oxidation kinetics of Mn28Al12 steel under this condition also had two-stage linear rate laws, the oxidation rate of the second stage was slower than that of the first stage. When the oxidation temperature increased to 1373 K, the oxidation kinetics of the two steels at 5–25 h had only one-stage linear rate law, and the oxidation rates of the two steels were far faster than those at 1323 K for 5–25 h. The oxidation resistance of Mn28Al12 steel was much better than that of Mn28Al10 steel. Ferrite layer formed between the austenite matrix and the oxidation layer of the two Fe-Mn-Al-C steels oxidized at high temperature.

Fe-28Mn-x Al-1C (x = 10和12 wt. %)低密度钢的Rietveld细化、显微组织、机械性能和氧化特性
采用Rietveld法对Fe-28Mn-xAl-1C (x=10 wt. %和12 wt. %)奥氏体低密度钢的显微组织和性能之间的定量关系进行了评价。结果表明:锻造后的Mn28Al10(即Fe- 28mn - 10al - 1c)钢为典型的三相奥氏体钢,包括92.85 wt. % γ-Fe(Mn, Al, C)(奥氏体)、5.28 wt. % (Fe, Mn) 3alc0.3 (κ-碳化物)和1.87 wt. % α-Fe(Al, Mn)(铁素体)。然而,对于锻造的Mn28Al12(即Fe-28Mn-12Al-1C)钢,只能得到76.64 wt. %的奥氏体,9.63 wt. %的碳化物,9.14 wt. %的铁素体和4.59 wt. %的Fe3 Al (DO3)。纳米碳化物和DO3分别主要分布在奥氏体晶粒和奥氏体与铁素体的界面中。锻造后的Mn28Al10钢比锻造后的Mn28Al12钢具有更好的强度、塑性和比强度组合。锻造后的Mn28Al12钢的塑性远低于锻造后的Mn28Al10钢。Mn28Al10钢在1323 K下氧化5 ~ 25 h的氧化动力学具有两阶段线性速率规律,第二阶段的氧化速率比第一阶段快。Mn28Al12钢在此条件下的氧化动力学虽然也具有两阶段的线性速率规律,但第二阶段的氧化速率比第一阶段慢。当氧化温度升高至1373 K时,两种钢在5 ~ 25 h的氧化动力学仅为一段线性速率规律,且两种钢在5 ~ 25 h的氧化速率远快于1323 K时的氧化速率,Mn28Al12钢的抗氧化性能明显优于Mn28Al10钢。两种Fe-Mn-Al-C钢经高温氧化后,在奥氏体基体与氧化层之间形成铁素体层。
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来源期刊
CiteScore
4.30
自引率
0.00%
发文量
2879
审稿时长
3.0 months
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