电磁复合场制备匀质Zn-Bi偏晶合金的物理模拟

王江; 钟云波; 汪超; 王志强; 任忠鸣; 徐匡迪

doi:10.7498/aps.60.076101

摘要

本文通过物理模拟的方法研究了强磁场复合交变电流作用对过偏晶合金凝固组织的影响机理,考察了电磁复合场下第二相初生液滴直径的演变规律,以及洛伦兹力作用下已分层少数相被"打碎"进入基体相的过程.结果表明:电磁体积力的增加,有利于液滴初始直径的减小;而交变电流频率的影响存在最佳值,偏离该值对初生液滴直径的抑制效果下降,这与实际试验规律一致;在电磁复合场作用下,已经分层的两液相可以重新实现均匀混合.这些效应有效缓解了偏晶合金凝固前第二相由于各种因素导致的偏聚,模拟结果直观地揭示了电磁复合场制备匀质偏晶合金的主要机理

关键词:

Abstract

Through physical simulation, we study the influence mechanism of electromagnetic field on the solidification structure of homogeneous Zn-Bi monotectic alloy, the transformation rule of the diameter of molten secondary phase under the compound field, and the process of the shattering of the layered structure into matrix by the Lorentz force. The results show that the diameter of the secondary drop decreases with AC current density and magnetic field increasing. The influence of AC frequency has an optimal value from which the deviation can weaken the suppression of diameter, which accords with the experimental result. The layered metal liquid can be uniformly mixed under the action of electromagnetio field. The above effects can effectively release segregation of the second phase of monotectic alloy. The simulation results show the main factors of preparing the homogeneous monotectic alloy in an electromagnetic field intuitively.

Keywords:

作者及机构信息

1.
上海大学上海市现代冶金与材料制备重点实验室,上海 200072

基金项目: 国家自然科学基金(批准号:50974085),上海市人才发展基金(批准号:2009046),教育部博士点基金(批准号:20093108110012)和教育部创新团队(批准号:IRT0739)资助的课题.

Authors and contacts

1.
Shanghai Key Laboratory of Modern Metallurgy & Material Processing, Shanghai University, Shanghai, 200072, China

参考文献

[1]	Uenishi K, Kawaguchi H, Kobayashi K F 1994 Journal of Materials Science 29 860
[2]	Ratke L, Diefenbach S 1995 Mater. Sci. Eng. 15R 263
[3]	Creuze J, Bertheer F, Tetor R, Legrand B 2001 Phys. Rev. Lett. 86 5735
[4]	Zhao JZ, Gao LL, He J, Wang JT, Chen GY 2006 Acta Metallurgica Sinica 42 113(in Chinese)[赵九州、高玲玲、何杰、王江涛、陈桂云 2006 金属学报 42 113 Inoue A,Yano N, Matsuzaki K, Masumoto T 1987 Journal of Materials Science 22 123 〖6] Thieringer W K, Ratke L 1987 Acta Metall 35 1237
[5]	Dhindaw B K, Stefanescu D M, Singh A K 1988 Metallurgical Transactions A 19 2839
[6]	Xu J F, Dai F P, Wei B B 2007 Acta Phys. Sin. 56 3996(in Chinese)[徐锦锋、代富平、魏炳波 2007 56 3996]
[7]	Majumdar B, Chattopadhyay K 2000 Metallurgical and Materials Transactions A 31 1834
[8]	Carlberg T, Fredriksson H 1980 Metallurgical Transactions A 11 1665
[9]	Fudll H, Kimura T, Kitaguchi H 1995 Journal of Materials Science 30 3429
[10]	Chen HM 1998 Journal of Ningxia University 19 241(in Chinese)[陈焕铭 1998 宁夏大学学报 19 241]
[11]	Hong Z Z, Lü Y J, Xie W J, Wei B B 2006 Chinese Science Bulletin 51 2714(in Chinese)[洪振宇、吕勇军、解文军、魏炳波 2006 科学通报 51 2714]
[12]	Rogers J R, Davis R H 1990 Metallurgical Transactions A 21 59
[13]	Yin HY, Lu XY 2008 Acta Phys. Sin. 57 4341(in Chinese)[殷涵玉、鲁晓宇 2008 57 4341 Xu J F, Fan Y F, Chen W, Zhai Q Y 2009 Acta Phys. Sin. 58 644(in Chinese)〖徐锦锋、范于芳、陈娓、翟秋亚 2009 58 644]
[14]	Yang S,Huang W D,Jia J 2000 Materials for Mechanical Engineering 24 5(in Chinese)[杨森、黄卫东、贾均 2000 机械工程材料 24 5]
[15]	Zhang H W,Xian A P 1999 Acta Metallurgica Sinica 35 1187(in Chinese)[张宏闻、冼爱萍 1999 金属学报 35 1187]
[16]	Zhang H W,Xian A P 2000 Acta Metallurgica Sinica 36 347(in Chinese)[张宏闻、冼爱萍 2000 金属学报 36 347]
[17]	Yasuda H, Ohnaka I, Kawakami O, Ueno K, Kishio K 2003 ISIJ Int. 43 942
[18]	Yasuda H, Ohnaka I, Fujimoto S, Takezawa N, Tsuchiyama A 2006 Sci. Mater 54 527
[19]	Zhang L, Wang E G, Zhuo X W, He J C 2008 Acta Metallurgica Sinica 44 165(in Chinese)[张林、王恩刚、左小伟、赫冀成 2008 金属学报 44 165]
[20]	Shi J F,Zhong Y B,Ren Z M,Deng K,Xu K D 2006 Shanghai Metals 28 22(in Chinese)[史俊芳、钟云波、任忠鸣、邓康、徐匡迪 2006 上海金属 28 22\]
[21]	Wang J, Zhong YB, Ren WL, Lei ZS, Ren ZM, Xu KD 2009 Acta Phys. Sin. 58 893(in Chinese)[王江、钟云波、任维丽、雷作胜、任忠鸣、徐匡迪 2009 58 893\]
[22]	Dong M H 2002 Journal Harbin Univ. Sci & Tech 7 114(in Chinese)[董孟环 2002 哈尔滨理工大学学报 7 114\]
[23]	Eric A Brandes Smithells Metals Reference Book. London:Boston Singapore Sydney Wellington Durban Toronto,1983.19-1
[24]	Lei Z S 2004 Ph. D. Dissertation (Shanghai University) 34(in Chinese)[雷作胜 2004 学位论文(上海大学) 34\]
[25]	Zhong Y B 2000 Ph. D. Dissertation (Shanghai University) 22—44(in Chinese)[钟云波 2000 学位论文(上海大学) 22—24\]

施引文献

[1]	Uenishi K, Kawaguchi H, Kobayashi K F 1994 Journal of Materials Science 29 860
[2]	Ratke L, Diefenbach S 1995 Mater. Sci. Eng. 15R 263
[3]	Creuze J, Bertheer F, Tetor R, Legrand B 2001 Phys. Rev. Lett. 86 5735
[4]	Zhao JZ, Gao LL, He J, Wang JT, Chen GY 2006 Acta Metallurgica Sinica 42 113(in Chinese)[赵九州、高玲玲、何杰、王江涛、陈桂云 2006 金属学报 42 113 Inoue A,Yano N, Matsuzaki K, Masumoto T 1987 Journal of Materials Science 22 123 〖6] Thieringer W K, Ratke L 1987 Acta Metall 35 1237
[5]	Dhindaw B K, Stefanescu D M, Singh A K 1988 Metallurgical Transactions A 19 2839
[6]	Xu J F, Dai F P, Wei B B 2007 Acta Phys. Sin. 56 3996(in Chinese)[徐锦锋、代富平、魏炳波 2007 56 3996]
[7]	Majumdar B, Chattopadhyay K 2000 Metallurgical and Materials Transactions A 31 1834
[8]	Carlberg T, Fredriksson H 1980 Metallurgical Transactions A 11 1665
[9]	Fudll H, Kimura T, Kitaguchi H 1995 Journal of Materials Science 30 3429
[10]	Chen HM 1998 Journal of Ningxia University 19 241(in Chinese)[陈焕铭 1998 宁夏大学学报 19 241]
[11]	Hong Z Z, Lü Y J, Xie W J, Wei B B 2006 Chinese Science Bulletin 51 2714(in Chinese)[洪振宇、吕勇军、解文军、魏炳波 2006 科学通报 51 2714]
[12]	Rogers J R, Davis R H 1990 Metallurgical Transactions A 21 59
[13]	Yin HY, Lu XY 2008 Acta Phys. Sin. 57 4341(in Chinese)[殷涵玉、鲁晓宇 2008 57 4341 Xu J F, Fan Y F, Chen W, Zhai Q Y 2009 Acta Phys. Sin. 58 644(in Chinese)〖徐锦锋、范于芳、陈娓、翟秋亚 2009 58 644]
[14]	Yang S,Huang W D,Jia J 2000 Materials for Mechanical Engineering 24 5(in Chinese)[杨森、黄卫东、贾均 2000 机械工程材料 24 5]
[15]	Zhang H W,Xian A P 1999 Acta Metallurgica Sinica 35 1187(in Chinese)[张宏闻、冼爱萍 1999 金属学报 35 1187]
[16]	Zhang H W,Xian A P 2000 Acta Metallurgica Sinica 36 347(in Chinese)[张宏闻、冼爱萍 2000 金属学报 36 347]
[17]	Yasuda H, Ohnaka I, Kawakami O, Ueno K, Kishio K 2003 ISIJ Int. 43 942
[18]	Yasuda H, Ohnaka I, Fujimoto S, Takezawa N, Tsuchiyama A 2006 Sci. Mater 54 527
[19]	Zhang L, Wang E G, Zhuo X W, He J C 2008 Acta Metallurgica Sinica 44 165(in Chinese)[张林、王恩刚、左小伟、赫冀成 2008 金属学报 44 165]
[20]	Shi J F,Zhong Y B,Ren Z M,Deng K,Xu K D 2006 Shanghai Metals 28 22(in Chinese)[史俊芳、钟云波、任忠鸣、邓康、徐匡迪 2006 上海金属 28 22\]
[21]	Wang J, Zhong YB, Ren WL, Lei ZS, Ren ZM, Xu KD 2009 Acta Phys. Sin. 58 893(in Chinese)[王江、钟云波、任维丽、雷作胜、任忠鸣、徐匡迪 2009 58 893\]
[22]	Dong M H 2002 Journal Harbin Univ. Sci & Tech 7 114(in Chinese)[董孟环 2002 哈尔滨理工大学学报 7 114\]
[23]	Eric A Brandes Smithells Metals Reference Book. London:Boston Singapore Sydney Wellington Durban Toronto,1983.19-1
[24]	Lei Z S 2004 Ph. D. Dissertation (Shanghai University) 34(in Chinese)[雷作胜 2004 学位论文(上海大学) 34\]
[25]	Zhong Y B 2000 Ph. D. Dissertation (Shanghai University) 22—44(in Chinese)[钟云波 2000 学位论文(上海大学) 22—24\]

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