Removal of primary iron rich phase from aluminum-silicon melt by centrifugal separation 被引量：10

Removal of primary iron rich phase from aluminum-silicon melt by centrifugal separation

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摘要 Recycling is a major consideration in continued aluminum use due to the enormous demand for high quality products. Some impurity elements gradually accumulate through the repetitive reuse of aluminum alloy scrap. Of them, the iron content should be suppressed under the allowed limit. In the present research, a novel separation method was introduced to remove primary iron-rich intermetallic compounds by centrifugation during solidification of AI-Si-Fe alloys. This method does not use the density difference between two phases as in other centrifugal methods, but uses the order of solidification in AI-Si-Fe alloys, because iron promotes the formation of intermetallic compounds with other alloying elements as a primary phase. Two AI-Si-Fe alloys which have different iron contents were chosen as the starting materials. The iron-rich phase could be efficiently removed by centrifuging under a centrifugal force of 40 g. Coarse intermetallic compounds were found in the sample inside the crucible, while rather fine intermetallic compounds were found in the sample outside the crucible. Primary intermetallic compounds were linked to each other via aluminum-rich matrix, and formed like a network. The highest iron removal fraction is 67% and the lowest one is 7% for AI-12Si-1.7Fe alloy. And they are 82% and 18% for AI-12Si-3.4Fe alloy, respectively. Recycling is a major consideration in continued aluminum use due to the enormous demand for high quality products. Some impurity elements gradually accumulate through the repetitive reuse of aluminum alloy scrap. Of them, the iron content should be suppressed under the allowed limit. In the present research, a novel separation method was introduced to remove primary iron-rich intermetallic compounds by centrifugation during solidification of Al-Si-Fe alloys. This method does not use the density difference between two phases as in other centrifugal methods, but uses the order of solidification in Al-Si-Fe alloys, because iron promotes the formation of intermetallic compounds with other alloying elements as a primary phase. Two Al-Si-Fe alloys which have different iron contents were chosen as the starting materials. The iron-rich phase could be efficiently removed by centrifuging under a centrifugal force of 40 g. Coarse intermetallic compounds were found in the sample inside the crucible, while rather fine intermetallic compounds were found in the sample outside the crucible. Primary intermetallic compounds were linked to each other via aluminum-rich matrix, and formed like a network. The highest iron removal fraction is 67% and the lowest one is 7% for Al-12Si-1.7Fe alloy. And they are 82% and 18% for Al-12Si-3.4Fe alloy, respectively.

作者 Seong Woo Kim Un Ho Im Hyeong Cheol Cha Se Hyeong Kim Ji Eun Jang Ki Young Kim

机构地区 School of Energy

出处《China Foundry》 SCIE CAS 2013年第2期112-117,共6页 中国铸造（英文版）

基金 supported by the Basic Science Research Program through the National Research Foundation of Korea(NRF)funded by the Ministry of Education,Science and Technology(No.2012R1A1A2007476) the authors express their gratitude for the financial support from Korea University of Technology and Education

关键词 Al-Si alloys iron removal centrifugal separation

分类号 TG146.21 [金属学及工艺—金属材料]

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参考文献20

1Kaye A and Street A. Die Casting Metallurgy. London: Butterworth Scientific, 1982: 30.
2EAAJOAA Recycling Division. Aluminium Recycling in Europe; The Road to High Quality Products. European Aluminum Association and Organization of European Aluminum Refiners and Re-melters, 2006: 5.
3De Moraes H L, De Oliveira J R, Espinosa D C R, et al. Removal of iron from molten recycled aluminum through intermediate phase filtration. Mater. Trans., 2006, 47: 1731- 1736.
4Han Q and Viswanathan S. Analysis of the Mechanism of Die Soldering in Aluminum Die Casting. Metall. Mater. Trans., 2003, 34A: 139-146.
5Apelian D. Worldwide Report Aluminum Cast Alloys: Enabling Tools for Improved Performance. NADCA, 2009: 7.
6ASM Handbook. 9th Ed. Vol. 15, Casting. ASM Inter., 1988: 1627.
7Matsubara J, Izawa N, and Nakanishi M. Macroscopic segregation in AI-11 mass%Si alloy containing 2mass%Fe solidified under centrifugal force. Japan Ins. Light Metals, 1998,48: 93-97.
8Shen H, Yang W D, Liang H, et al. Research Advance in Harmful Effects and Removal of Impurity Fe from AI and AI Alloys. Advan. Mater. Research, 2011, 295-297: 751-759.
9Kim H J and Yoon E P. Elimination of Fe element in A380 aluminum alloy scrap by electromagnetic force. J. Mater. Sci. Lett., 2000, 19: 253-255.
10Xu Z, Li T, and Zhou Y. Elimination of Fe in AI-Si cast alloy scrap by electromagnetic filtration. J. Mater. Sci., 2003, 38: 4557-4565.

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2Yuan Cheng,Xinbao Zhao,Wanshun Xia,Qinghai Pan,Quanzhao Yue,Yuefeng Gu,Ze Zhang.Effects of Mo addition on microstructure of a 4th generation Ni-based single crystal superalloy[J].Progress in Natural Science:Materials International,2022,32(6):745-751. 被引量：4
3叶珍,郑长清,葛素静,鲁园园,张少文,苗赛男,刘永昌,周亚伟,马朝利.再生铝超净化处理与微合金化技术在低压铸造铝车轮中的应用[J].特种铸造及有色合金,2022,42(1):77-82. 被引量：5
4钱东伶,芦富敏,余忠土,张恒华,杨弋涛.汽车底盘用铸造铝合金的研究进展[J].特种铸造及有色合金,2020,40(10):1077-1082. 被引量：16
5林虹,曹开颜,曹国庆.2019年中国电池行业运行概况[J].电池工业,2020,0(1):43-46. 被引量：6
6Xin Tong,Guoqiang You,Jingchuan Luo,Mahmoud Ebrahimi,Guohua Wu.Rapid cooling effect during solidification on macro-and micro-segregation of as-cast Mg-Gd alloy[J].Progress in Natural Science:Materials International,2021,31(1):68-76. 被引量：5
7李天晓,许振明,孙宝德,疏达,周尧和.Electromagnetic separation of primary iron-rich phases from aluminum-silicon melt[J].中国有色金属学会会刊：英文版,2003,13(1):121-125. 被引量：6
8张磊,焦万丽,尉海军,姚广春.锰结合预先热处理对铝硅合金中富铁相组织和力学性能的影响[J].中国有色金属学报,2005,15(3):368-373. 被引量：38
9李春生,刘海鸥,赫微,郝志刚,赵涛,张雷.铝合金熔体的粘度及其影响因素[J].轻合金加工技术,2005,33(10):22-25. 被引量：11
10赵岩,齐锦刚,刘兴江,王建中.分子动力学模拟技术及其在金属熔体结构研究中的应用[J].金属热处理,2006,31(1):13-16. 被引量：3

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6GAO Bo CHEN Lei YU Fuxiao SUN Shuchen TU Ganfeng.Effect of DH treatment on microstructure and mechanical properties of an LM28-0.3wt.%Nd hypereutectic aluminum silicon alloy[J].Rare Metals,2007,26(6):578-583. 被引量：3
7向艳旭.酒钢炉卷轧机液压APC系统建模与仿真研究[J].冶金设备,2009(S3):1-3.
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9于鹏飞,张坤,解宵,岳伟,张锦标,张慧鹏.曲柄滑块机构的优化设计及运动仿真[J].运城学院学报,2015,33(6):47-49. 被引量：5
10BI Wenzhen,JIN Xinyan,WANG Li.Investigation of a novel spot defect on a hot dip galvanized high-silicon AHSS sheet[J].Baosteel Technical Research,2015,9(3):54-60. 被引量：1

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Removal of primary iron rich phase from aluminum-silicon melt by centrifugal separation 被引量：10

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