Inconel718合金高温氧化行为
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摘要
为探究电渣重熔冶炼Inconel718合金过程中电极氧化机理,研究了Inconel718合金在1 150℃下的高温氧化行为。结果表明,在1 150℃下,Inconel718合金氧化动力学曲线遵循线性关系。在高温氧化期间,Cr和Ni等合金元素会快速氧化形成富Ni和Fe及Cr的Cr_2O_3、Fe_2O_3、3Cr_2O_3·Fe_2O_3和含Ni的尖晶石Cr_2O_3·NiO。随着氧化时间的增加,Ti元素发生氧化形成TiO_2,Ti元素向外扩散的同时在氧化层间形成孔隙,加速氧元素向基体内部扩散,进而加速了其他合金元素的氧化。
In order to explore oxidation mechanism of Inconel718 alloy electrode in the smelting process of electroslag remelting,high-temperature oxidation behavior of Inconel718 alloy at 1 150 ℃ was investigated.The results show that,at 1 150 ℃,Inconel718 alloy oxidation kinetic curves follow linear relationships. During high-temperature oxidation,alloy elements such as Cr and Ni,etc.,quickly form Fe-,Ni-and Cr-rich compounds like Cr_2O_3,Fe_2O_3,and 3 Cr_2O_3· Fe_2O_3 as well as Ni-containing spinel Cr_2O_3· NiO. With the increase of oxidation time,Ti element is oxidized to form TiO_2,and as the Ti element diffuses outwards,pores are left inside the oxide layer,which accelerate oxygen to penetrate further into the substrate leading to speed-up of oxidation of other alloying elements.
In order to explore oxidation mechanism of Inconel718 alloy electrode in the smelting process of electroslag remelting,high-temperature oxidation behavior of Inconel718 alloy at 1 150 ℃ was investigated.The results show that,at 1 150 ℃,Inconel718 alloy oxidation kinetic curves follow linear relationships. During high-temperature oxidation,alloy elements such as Cr and Ni,etc.,quickly form Fe-,Ni-and Cr-rich compounds like Cr_2O_3,Fe_2O_3,and 3 Cr_2O_3· Fe_2O_3 as well as Ni-containing spinel Cr_2O_3· NiO. With the increase of oxidation time,Ti element is oxidized to form TiO_2,and as the Ti element diffuses outwards,pores are left inside the oxide layer,which accelerate oxygen to penetrate further into the substrate leading to speed-up of oxidation of other alloying elements.
引文
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[5]王信才. GH3030合金电渣重熔Al、Ti成分控制分析[J].特钢技术,2006,11(2):7-9.
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[10]LENGLET M,GUILLAMET R,LOPITAUX J,et al.Caracterisation des premieres etapes de l'oxydation de l'alliage inconel 718 par spectrometrie I.R.F.T[J]. Materials Research Bulletin,1990,25(6):715-722.
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[12]魏鑫,赵龙海,谭毅,等.电子束精炼Inconel718合金的高温氧化行为[J].机械工程材料,2018,42(5):1-8.
[13]张松,王琦,赵小书,等. K444铸造镍基高温合金的高温氧化行为[J].沈阳工业大学学报,2010,32(2):136-140.
[2]罗恒军,谢静,程槿. GH4169合金涡轮盘锻件晶粒度分析和控制[J].大型铸锻件,2010(6):17.
[3]李正邦,傅杰.电渣重熔技术在中国的应用和发展[J].特殊钢,1999,20(2):7-13.
[4]李少华,巴俊洲,蒋亚雄,等. IN 718合金高温氧化行为的研究进展[J].舰船防化,2008(2):8-14.
[5]王信才. GH3030合金电渣重熔Al、Ti成分控制分析[J].特钢技术,2006,11(2):7-9.
[6]郭建亭,师昌绪.铝和钛对一种35镍15铬型铁基高温合金组织结构和力学性能的影响[J].金属学报,1978,14(3):227-238.
[7]崔彤,王介强,王晓轩,等. GH4169合金高温氧化特征[J].腐蚀科学与防护技术,2004,16(4):192-195.
[8]GREENE G A,FINFROCK C C. Oxidation of inconel718 in air at temperatures from 973K to 1620K[J]. Oxidation of Metals,2000,55(5-6):505-521.
[9]崔彤GH4169合金高温氧化[J]钢铁研究学报,2003,15(7):53-57.
[10]LENGLET M,GUILLAMET R,LOPITAUX J,et al.Caracterisation des premieres etapes de l'oxydation de l'alliage inconel 718 par spectrometrie I.R.F.T[J]. Materials Research Bulletin,1990,25(6):715-722.
[11]司家勇,刘锋.δ相对Inconel718合金组织与疲劳性能影响的研究进展[J].材料导报,2013,27(7):89-92.
[12]魏鑫,赵龙海,谭毅,等.电子束精炼Inconel718合金的高温氧化行为[J].机械工程材料,2018,42(5):1-8.
[13]张松,王琦,赵小书,等. K444铸造镍基高温合金的高温氧化行为[J].沈阳工业大学学报,2010,32(2):136-140.
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