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Metallurgical and Materials Transactions B

Erschienen in:

01.12.2014

Application of Electromagnetic (EM) Separation Technology to Metal Refining Processes: A Review

verfasst von: Lifeng Zhang, Shengqian Wang, Anping Dong, Jianwei Gao, Lucas Nana Wiredu Damoah

Erschienen in: Metallurgical and Materials Transactions B | Ausgabe 6/2014

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Abstract

Application of electromagnetic (EM) force to metal processing has been considered as an emerging technology for the production of clean metals and other advanced materials. In the current paper, the principle of EM separation was introduced and several schemes of imposing EM field, such as DC electric field with a crossed steady magnetic field, AC electric field, AC magnetic field, and traveling magnetic field were reviewed. The force around a single particle or multi-particles and their trajectories in the conductive liquid under EM field were discussed. Applications of EM technique to the purification of different liquid metals such as aluminum, zinc, magnesium, silicon, copper, and steel were summarized. Effects of EM processing parameters, such as the frequency of imposed field, imposed magnetic flux density, processing time, particle size, and the EM unit size on the EM purification efficiency were discussed. Experimental and theoretical investigations have showed that the separation efficiency of inclusions from the molten aluminum using EM purification could as high as over 90 pct. Meanwhile, the EM purification was also applied to separate intermetallic compounds from metal melt, such as α-AlFeMnSi-phase from the molten aluminum. And then the potential industrial application of EM technique was proposed.

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L.V.M. Antony and R.G. Reddy: “Processes for Production of High-Purity Metal Powders”, JOM, 2003, (3), pp. 14-18.CrossRef

T.H. Okabe, K.T. Jacob and Y. Waseda: Purification Process and Characterization of Ultra High Purity Metals, Application of Basis Science to Metallurgical Processing, H.W. Walter Michaeli, Eicke Weber, ed. Springer,, New York, 2001, p. 411.

B.P. Cochran, M.L. Fenyes and J.L. Jeanneret: “Flux Practice in Aluminum Melting”, AFS Trans, 1992, vol. 88, pp. 737-42.

A.R. Robert: “The Closed-Circuit Degassing/Fluxing of Liquid Aluminum Alloys by Nitrogen-Chlorine “, JOM, 1997, vol. 49 (5), pp. 21-23.CrossRef

P. Marty, A. Alemany, R. Ricou, and C. Vives: Progr. Astronaut. Aeronaut., vol. 841983, pp. 402-13.

J. Szekely, J.W. Evans, K. Blazek and N. El-Kaddah: “Magnetohydrodynamics in Process Metallurgy”, TMS, (San Diego, California), TMS, 1992.

D. Shu, B.D. Sun, K. Li, Z. Xu and Y.H. Zhou: “Continuous Separation of Nonmetallic Inclusions from Aluminum Melt using Alternating Magnetic Field”, Materials Letters, 2002, vol. 55 (5), pp. 322-26.CrossRef

G. Elmer: Diamagnetic Separation, 1900.

A. Kolin: “An Electromagnetokinetic Phenomenon Involving Migration of Neutral Particles”, Science, 1953, vol. 117 (2), pp. 134-37.CrossRef

10.

D. Leenov and A. Kolin: “Theory of Electromagnetophoresis. I. Magnetohydrodynamic Forces Experienced by Spherical and Sy mmetrically Oriented Cylindrical Particles”, J. Chem. Phys., 1954, vol. 22 (4), pp. 683-88.CrossRef

11.

N. El-Kaddah, A.D. Patel and T. T. Natarajan: “Electromagnetic Filtration of Molten Aluminum Using An Induced-current Separator”, JOM, 1995, vol. 47 (5), pp. 46-49.CrossRef

12.

N. El-Kaddah: Conference Record - IAS Annual Meeting, IEEE Industry Applications Society, 1988, vol. 35(6), pp. 1162–67.

13.

P.J. Black: “The Sturcture of FeAl3”, Acta Cryst., 1955, vol. 8, p. 43.CrossRef

14.

E. Yamaka and K. Sawamoto: “Electrical Conductivity and Thermo-electric Motive Force in Mgo Single Crystal”, Journal of the physical society of Japan, 1955, vol. 10 (3), pp. 176-79.CrossRef

15.

M.F. Culpin: Proc. Phys. Soc., 1957, pp. 1079–87.

16.

N.A. Surplice: “The Electrical Conductivity of Calcium and Strontium Oxides”, Brit. J. Appl. Phys, 1966, vol. 17, pp. 175-80.CrossRef

17.

T.J. Lewis and A.J. Wright: “The Electrical Conductivity of Magnesium Oxide at Low Temperatures”, J. Phys. D: Appl. Phys., 1968, vol. 1, pp. 441-47.CrossRef

18.

O.R. Singleton and G.C.J. Robinson: “Refining Aluminum-silicon Alloys by Centrifuging”, Journal of the Institute of Metals, 1971, vol. 99, pp. 155-59.

19.

R. Stroll: The Analysis of Eddy Currents, Clarendon press, Oxford, 1974.

20.

U. Andres: “Magnetohydrodynamic and Magnetohydrostatic Separation-A new Prospect for Mineral Separation in the Magnetic Field “, Minerals Sci. Engng., 1975, vol. 7 (2), pp. 99-109.

21.

L.F. Mondolfo: Aluminum Alloys: Structure and Properties, Butterworth, London, 1976.

22.

A. Alemany, J.P. Argous, J. Barbet, M. Ivanes, R. Moreau, and S. Poinsot: French Patent No. 80400 4430. 1980.

23.

A. Miroshnikov: Magnitaya Gidrodinamika, 1980, vol. 1, pp. 70–78.

24.

R. Moreau: Proc. 15th Congr. Theoretical Appl. Mech., Toronto, ON, Canada, 1980, pp. 107–18.

25.

P. Marty and A. Alemany: Met. Soc (Book 305)-Proc. Symp. IUTAM, Metall. Appl. Magnetohydrodynamics, Cambridge, UK, 1984, pp. 245–59.

26.

S. Taniguchi and J.K. Brimacombe: “ Theoretical Study on the Separation of Inclusion Particles by Pinch Force from Liquid Steel Flowing in A Circular Pipe”, Tetsu-to-Hagane, 1994, vol. 80 (1), pp. 24-29.

27.

Y. Tanaka, K. Sassa, K. Iwai and S. Asai: Tetsu-to-Hagane, 1995, vol. 81(12), p. 1120–25.

28.

T. Ogasawara, N. Yoshikawa, S. Taniguchi and T. Asai: “Electromagnetic Flow around Two Non-conducting Particles and the Interaction Forces Different Diameter Cases”, ISIJ International, 2003, vol. 43 (6), pp. 862-68.CrossRef

29.

O. Takuma and Y. Noboru: “Simulation of Conducting Liquid Flow around Two Non-conducting Particles in the Presence of A DC Electromagnetic Field (oblique configuration of particles to the field)”, Modelling Simul. Mater. Sci. Eng., 2004, vol. 12, pp. 709-18.CrossRef

30.

A.D. Patel: Thesis, University of Alabama, 1997.

31.

Y. Zhong, Z. Ren, K. Deng, G. Jiang and K. Xu: J. Shanghai Univ., 1999, vol. 3(2), pp. 157-61.CrossRef

32.

D. Shu, T.X. Li, B.D. Sun, Y.H. Zhou, J. Wang and Z.M. Xu: “Numerical Calculation of the Electromagnetic Expulsive Force upon No nmetallic Inclusions in an Aluminum Melt. I. Spherical Particles”, Metallurgical and Materials Transactions B, 2000, vol. 31 (6), pp. 1527-33.CrossRef

33.

D. Shu, T.X. Li, B.D. Sun, Y.H. Zhou, J. Wang and Z.M. Xu: “Numerical Calculation of the Electromagnetic Expulsive Force upon No nmetallic Inclusions in an Aluminum Melt. II. Cylindrical Particles”, Metall. Mater. Trans. B, 2000, vol. 31 (6), pp. 1535-40.CrossRef

34.

Z. Xu, T. Li, D. Shu and Y. Zhou: “Electromagnetic Filtration of Primary Fe-rich Phases from Al-Si Alloy Melt”, Cailiao Kexue Yu Jishu, 2001, vol. 17, pp. 306-10.

35.

Z. Xu, T. Li and Y. Zhou: “Elimination of Fe in Al-Si Cast Alloy Scrap by Electromagnetic Filtration”, Journal of Materials Science, 2003, vol. 38 (22), pp. 4557-65.CrossRef

36.

T.X. Li, Z.M. Xu, B.D. Sun, D. Shu and Y.H. Zhou: “Electromagnetic Separation of Primary Iron-rich Phases from Aluminum-silicon Melt”, Transactions of the Nonferrous Metals Society of China, 2003, vol. 13 (1), pp. 121-25.

37.

T.X. Li, Z.M. Xu, X.P. Zhang, B.D. Sun and Y.H. Zhou: “Reducing Iron Content In Al-Si alloy by Electromagnetic Seperation”, Journal of Shanghai Jiao Tong University, 2001, vol. 35 (5), pp. 664-67.

38.

A.D. Patel and N. El-Kaddah: Light Met.: Proc. Sessions, TMS Ann. Meet., The Minerals, Metals, and Materials Society, Warrendale, PA, 1997, pp. 1013–18.

39.

S. Makarov, R. Ludwig and D. Apelian: “Inclusion Removal in Molten Aluminum: Mechanical, Electromagnetic, and Acoustic Techniques”, Trans. Am. Foundrymen’s Soc., 1999, vol. 107, pp. 727-35.

40.

J. Barglik and C. Sajdak: “Purification of Liquid Aluminum from Non-Metallic Inclusions in the Electromagnetic Field”, Elektrowarme International, 1985, vol. 43B (2), pp. 77-80.

41.

T. Li: PhD Thesis, Shanghai Jiao Tong University, 2004.

42.

K. Li, J. Wang, D. Shu, T.X.Sun, B.D. Sun and Y.H. Zhou: “Theoretical and Experimental Investigation of Aluminum Melt Cleaning using Alternating Electromagnetic Field”, Materials Letters, 2002, vol. 56 (3), pp. 215-20.CrossRef

43.

D. Shu, B.D. Sun, J. Wang, T.X. Li and Y.H. Zhou: “Study of Electromagnetic Separation of No nmetallic Inclusions from Aluminum Melt”, Metall. Mater. Trans. A, 1999, vol. 30A (11), pp. 2979-88.CrossRef

44.

M. Li and R.I.L. Guthrie: “Numerical Studies of the Motion of Particles in Current-carrying Liquid Metals Flowing in a Circular Pipe”, Metall. Mater. Trans. B, 2000, vol. 31 (2), pp. 357-64.CrossRef

45.

D. Shu, B. Sun, K. Li and Y. Zhou: “Particle Trajectories in Aluminum Melt flowing in A Square Channel under an Alternating Magnetic Field Generated by A Solenoid”, Scripta Materialia, 2003, vol. 48, pp. 1385-90.CrossRef

46.

D. Shu: “Effects of Secondary Flow on the Electromagnetic Separation of Inclusions from Aluminum Melt in a Square Channel by a Solenoid “, ISIJ, 2002, vol. 42 (11), pp. 1241-50.CrossRef

47.

S. Makarov, R. Ludwig and D. Apelian: “Electromagnetic Separation Techniques in Metal Casting. II. Separation with Superconduting Coils”, IEEE Transactions on Magnetics, 2001, vol. 37 (2), pp. 1024-31.CrossRef

48.

S. Taniguchi and J.K. Brimacombe: “Application of Pinch Force to the Separation of Inclusion Particles From Liquid Steel”, ISIJ International, 1994, vol. 34 (9), pp. 722-31.CrossRef

49.

S. Makarov, R. Ludwig and D. Apelian: “Electromagnetic Separation Techniques in Metal Casting. I. Conventional Methods”, IEEE Transactions on Magnetics, 2000, vol. 36 (4), pp. 2015-21.CrossRef

50.

A.P. Dong, D. Shu, J. Wang and B.D. Sun: “Identification of Fe-Al-Zn Dross Phase in Galvanised Zinc Bath and Its Separation by Method of Alternating Magnetic Field”, Iro nmaking and Steelmaking, 2008, vol. 35 (8), pp. 633-37.CrossRef

51.

A.P. Dong, D. Shu, and J. Wang: Mater. Sci. Technol. Lond, 2008, vol. 24 (1), pp. 40–44.CrossRef

52.

A.P. Dong, S. Da, J. Wang and B.D. Sun: “Separation Behaviour of Zinc Dross from Hot dip Galvanising Melts of Different Aluminium Concentrations by Alternating Magnetic Field”, Iro nmaking and Steelmaking, 2009, vol. 36 (4), pp. 316-20.CrossRef

53.

M.R. Afshar, M.R. Aboutalebi, M. Isac and R.I.L. Guthrie: “Mathematical Modeling of Electromagnetic Separation of Inclusions from Magnesium Melt in a Rectangular Channel”, Materials Letters, 2007, vol. 61 (10), pp. 2045-49.CrossRef

54.

M.R. Afshar and M.R. Aboutalebi: Int. J. Mech. Sci., 2010, vol. 52(9), 1107–14.CrossRef

55.

L.N.W. Damoah and L. Zhang: 3rd International Symposium on High-Temperature Metallurgical Processing—TMS 2012 Annual Meeting and Exhibition, Orlando, FL, Minerals, Metals and Materials Society, 2012, pp. 271–78.

56.

L. Zhang, E. Øvrelid, S. Senanu, B. Agyei-Tuffour and A.N. Femi: REWAS2008: 2008 Global Symposium on Recycling, Waste Treatment and Clean Technology, CANCUN, MEXICO, TMS, Warrendale, PA, 2008, pp. 1011–26.

57.

L. Zhang and A. Ciftja: “Recycling of Solar Cell Silicon Scraps through Filtration, Part I: Experimental Investigation”, Solar Energy Materials and Solar Cells, 2008, vol. 92 (11), pp. 1450-61.CrossRef

58.

Y. Tian, L. Zhang, S. Wang and L.N.W. Damoah: National Metallurgical Reaction Engineering Conference of China, 2013, pp. 878–84.

59.

M. Kadkhodabeigi, J. Safarian, H. Tveit, M. Tangstad and S.T. Johansen: “Removal of SiC Particles from Solar Grade Silicon Melts by Imposition of High Frequency Magnetic Field”, Trans. Nonferr. Met. Soc. China, 2012, vol. 22 (11), pp. 2813-21.CrossRef

60.

S. Wang, L. Zang, S. Yang, Y. Chen, and Y. Li: J. Iron Steel Res. Int., 2012, vol. 19, pp. 866-78.

61.

S. Wang, L. Zhang, and Y. Tian: Removal of Non-metallic Inclusions from Molten Steel Using a High Frequency Magnetic Field, TMS, pp. 651–58, 2014.

62.

S. Asai: “Recent Development and Prospect of Electromagnetic Processing of Materials”, Science and Technology of Advanced Materials, 2000, vol. 1, pp. 191-200.CrossRef

63.

K. Takahashi and S. Taniguchi: “Electromagnetic Separation of No nmetallic Inclusion from Liquid Metal by Imposition of High Frequency Magnetic Field”, ISIJ International, 2003, vol. 43 (6), pp. 820-27.CrossRef

64.

Y.S. Jennifer: Thesis, University of Toronto, 1997.

65.

J.P. Park, A. Morihira, K. Sassa and S. Asai: “Elimination of Non-metallic Inclusions Using Electromagnetic Force”, Tetsu-to-Hagane, 1994, vol. 80 (5), pp. 31-36.

66.

E.P. Yoon, J.P. Choi, J.H. Kim, T.W. Nam and S. Kitaoka: “Continuous Elimination of Al2O3 Particles in Molten Aluminium using Electromagnetic Force”, Materials Science and Technology, 2002, vol. 18 (9), pp. 1027-35.CrossRef

67.

Y. Yutaka, N. Tutomu and H. Yasuhiro: “Decreasing Non-metallic Inclusions in Molten Steel by Use of Tundish Heating System in Continuous Casting”, Tetsu-to-Hagane, 1985, vol. 71 (11), pp. 1474-81.

68.

S. Taniguchi and J.K. Brimacombe: “Numerical Analysis on the Separation of Inclusion Particles by Pinch Force from Liquid Steel Flowing in a Rectangular Pipe”, Tetsu-to-Hagane, 1994, vol. 80 (4), pp. 312-17.

69.

J.P. Park, K. Sassa and S. Asal: Metallurgical Processes for the Early Twenty First Century Vol. I. Basic Principles, (Warrendale PA), TMS, 1994, vol. 1, pp. 221-30.

70.

Y. He, Q. Li and W. Liu: “Effect of Combined Magnetic Field on the Eliminating Inclusions from Liquid Aluminum Alloy”, Materials Letters, 2011, vol. 65 (8), pp. 1226-28.CrossRef

71.

S. Yesilyurta, S. Motakef, R. Grugel and K. Mazuruk: “The Effect of the Traveling Magnetic Field (TMF) on the Buoyancy-induced Convection in the Vertical Bridgman Growth of Semiconductors”, Journal of Crystal Growth, 2004, vol. 263, pp. 80-89.CrossRef

72.

A.D. Patel and N. El-Kaddah: Int. Sym. Electromagn. Process. Mater., ISIJ, Nogoya, 1994.

73.

V.M. Korovin: “Separation of Particles, Suspended in a Conducting Liquid with the Help pf an Alternating Electromagnetic Field”, Magnetohydrodynamics, 1985, vol. 21 (3), pp. 321-26.

74.

V.M. Korovin: “Motion of A Drop in A Conducting Liquid under the Action of A Variable Electromagnetic Field”, Magnetohydrodynamics, 1986, vol. 22 (1), pp. 17-19.

75.

S. Taniguchi: “Inclusion Separation from Liquid Metal by Simultaneous Imposition of AC Current and Magnetic Field”, CAMP-ISIJ, 1998, vol. 11, p. 893.

76.

J.X. Jin, S.X. Dou and H.K. Liu: “Magnetic Separation Techniques and HTS Magnets”, Suprecond. Sci. Technol., 1998, vol. 11, pp. 1071-74.CrossRef

77.

R.L.L. Guthrie and M. Li: “In Situ Detection of Inclusions in Liquid Metals. II. Metallurgical Applications of LiMCA Systems”, Metallurgical and Materials Transactions B, 2001, vol. 32 (6), pp. 1081-93.CrossRef

78.

F. Yamao, K. Sassa, K. Iwai and S. Asai: “Separation of Inclusions in Liquid Metal Using Fixed Alternating Magnetic Field”, Tetsu-to-Hagane, 1997, vol. 83 (1), pp. 30-35.

79.

L.H. Schwartz: “Sustainability: The Materials Role”, Metall. Mater. Trans. B, 1999, vol. 30B (2), pp. 157-70.CrossRef

80.

M. Garnier: Proc. 3rd Int. Symp. Electromagn. Process. of Mater., ISIJ, Tokyo, 2000, p. 3.

81.

Y. Koichi and H. Kohmei: “Materials Development for A Sustainable Society”, Materials and Design, 2001, vol. 22 (2), pp. 143-46.CrossRef

82.

T. Ogasawara, N. Yoshikawa and S. Taniguchi: “Flow of Conducting Liquid Around Two Nonconducting Particles in DC Electromagnetic Field and the Electromagnetic Migration Force”, Metall. & Mater. Trans., 2004, vol. 35B (5), pp. 847-55.CrossRef

83.

M. Li and R.I.L. Guthrie: “Numerical Studies of the Motion of Spheroidal Particles Flowing with Liquid Metals Through an Electric Sensing Zone”, Metall. Mater. Trans. B, 2000, vol. 31 (4), pp. 855-66.CrossRef

84.

S. Taniguchi and A. Kikuchi: Proc. 3rd Int. Symp. EPM, EPM2000, ISIJ, Tokyo, 2000, p. 315.

85.

M. Li and R.I.L. Guthrie: “On the Detection and Selective Separation of Inclusions in Liquid Metal Cleanliness Analyzer (LiMCA) Systems”, Metallurgical and Materials Transactions B, 2000, vol. 31B (4), pp. 767-77.CrossRef

86.

M. Li and R.I.L. Guthrie: “Liquid Metal Cleanliness Analyzer (LiMCA) in Molten Aluminum”, ISIJ International, 2001, vol. 41 (2), pp. 101-10.CrossRef

87.

Z. Sun, M. Guo, J. Vleugels and O.V.D. Biest: “Numerical Calculation on Inclusion Removal from Liquid Metals under Strong Magnetic Fields”, Progress In Electromagnetics Research, 2009, vol. 98, pp. 359-73.CrossRef

88.

Y. Kubota, N. Yoshikawa and S. Taniguchi: “Electromagnetic Migration Force Acting on Two Non-conducting Particles in DC Electromagnetic Force Field”, Tetsu to Hagane, 2001, vol. 87 (3), pp. 113-20.

89.

T. Ogasawara, N. Yoshikawa, S. Taniguchi and T. Asai: “Flow of Conducting Liquid around Two Nonconducting Particles in DC Electromagnetic Field and the Electromagnetic Migration Force”, Metallurgical and Materials Transactions B, 2004, vol. 35 (5), pp. 847-55.CrossRef

90.

B. Zhang, Z. Ren and J. Wu: “Continuous Electromagnetic Separation of Inclusion from Aluminum Melt using Alternating Current”, T Nonferr Met. SOC. China, 2006, vol. 16, pp. 33-38.CrossRef

91.

K. Li, D. Shu, J. Wang, Z. Du, B. Sun and Y. Zhou: “Theoretical Study on Separation of No nmetallic Inclusion Particles from a Hollow Cylindrical Melt in Alternating Electromagnetic Field”, ISIJ International, 2004, vol. 44 (4), pp. 647-52.CrossRef

92.

K. Takahashi and S. Taniguchi: Proc. Electromagn. Process. Mater. Int. Conf. 2003, 2003.

93.

Q. Guo, Z. Cao and Z. Zhang: “Separation Efficiency of Alumina Particles in Al Melt under High Frequency Magnetic Field”, Trans. Nonferrous Met. Soc. China, 2010, vol. 20, pp. 153-57.CrossRef

94.

B. Zhang, Z. Ren and J. Wu: “Continuous Electromagnetic Separation of Inclusion from Aluminum Melt using Alternating Current.”, Trans. Nonferr. Met. Soc. China, 2006, vol. 16, pp. 33-38.CrossRef

95.

T. Yosikawa and K. Morita: “Refining of Si by the Solidification of Si-Al Melt with Electromagnetic Force”, ISIJ Internetional, 2005, vol. 45 (7), pp. 967-71.CrossRef

96.

L. Zhang: Chinese Patent, No. 201220416982.9, 2012.

97.

L. Zhang: Chinese Patent, No. 201220417818.X, 2012.

98.

K. LI, J. Wang, D. Shu, Z. Du, B. Sun and Y. Zhou: “In-situ Al/Mg2Si Functional Graded Materials (FGMs) Prepared by Electrom a gnetic Separation”, Journal of Shanghai Jiaotong University, 2004, vol. 38 (9), pp. 1433-37.

99.

C. Song, Z. Xu and G. Jian: “In-situ Al/Al3Ni Functionally Graded Materials by Electromagnetic Separation Method”, Materials and Engineering A, 2007, vol. 445, pp. 148-54.CrossRef

100.

C. Song, Z. Xu, G. Liang and J. Li: “Study of in situ Al/Mg2Si Functionally Graded materials by Eelectromagnetic Sseparation Method”, Materials Science and Engineering A, 2006, vol. 424, pp. 6-16.CrossRef

101.

C. Song, Z. Xu, and J. Li: Mater. Des., 2007, vol. 28, pp. 1012–15.CrossRef

102.

P.N. Crepeau: AFS Trans, 1995, vol. 103, p. 361.

103.

J.H. Kim and E.P. Yoon: “Elimination of Fe Element in A380 Aluminum Alloy Scrap by Electromagnetic Force”, Journal of Materials Science Letters, 2000, vol. 19 (3), pp. 253-55.CrossRef

104.

G.C. Yao, Z.Q. Sun and Z.X. Qiu: “Electromagnetic Separation of Iron-rich Phases from Molten Aluminium”, Journal of Northeastern University, Natural Science, 2001, vol. 22 (2), pp. 127-29.

105.

L. Zhang, W.-L. Jiao, H. Wei and G.-C. Yao: “Effects of the Shape of Fe Enrichment Phase on Purification of Liquid Al in Electromagnetic Field”, Special Casting & Nonferrous Alloys (Chinese), 2005, vol. 25 (3), pp. 131-32.

106.

W. Jiao and L. Zhang: “Purification of Iron Rich Impurity from Aluminum-Silicon Alloy by Electromagnetic Seperation”, Foundry Technology (Chinese), 2006, vol. 27 (3), pp. 269-72.

107.

L. Zhang, W. Jiao, H. Wei and G. Yao: “Electromagnetic Seperation of Magnetic Purity Particles in Aluminum Melt”, Materials Science & Technology (China), 2006, vol. 14 (5), pp. 524-26.

108.

L.N.W. Damoah and L. Zhang: “High Frequency Electromagnetic Separation of Inclusions from Aluminum”, Light Metals 2012, 2012, pp. 1069-76.

109.

P. Li, S. Zuo and T. Li: “Electromagnetic Separation of Oxide Inclusions from Copper Alloy”, Special Casting and Nonferrous Alloys, 2010, vol. 32 (2), pp. 176-79.

110.

D. Shu, B. Sun, K. Li, J. Wang and Y. Zhou: “Effects of Secondary Flow on the Electromagnetic Separation of Inclusions from Aluminum Melt in a Square Channel by a Solenoid”, ISIJ International, 2002, vol. 42 (11), pp. 1241-50.CrossRef

111.

A. Dong: Theoretical and Experimental Study on Electromagnetic Separation of Zinc Dross from Galvanizing Zinc Melt, Ph.D Thesis, Shanghai Jiao Tong University, 2009.

112.

K. Cukierski and B.G. Thomas: “Flow Control with Local Electromagnetic Braking in Continuous Casting of Steel Slabs”, Metallurgical and Materials Transactions B, 2008, vol. 39B (1), pp. 94-107.CrossRef

113.

J.K. Srivastava, M. Prasad and J.B. Wagner: “Electrical Conductivity of Silicon Dioxide Thermally Grown on Silicon”, J. Electrochem. Soc.: Solid-state Science and Technology, 1985, vol. 132 (4), pp. 955-63.CrossRef

114.

A.T. Dinsdale and P.E. Quested: Proc. 2003 Int. Symp. Liquid Met., 2004, vol. 39, pp. 7221–28.

115.

J.M. Molina, R. Prieto, J. Narciso and E. Louis: “The Effect of Porosity on the Thermal Conductivity of Al–12 wt% Si/SiC Composites”, Scripta Materialia, 2009, vol. 60, pp. 582-85.CrossRef

116.

L.A. Shipilova and A.A. Kas’yanenko: “Electrophysical Properties of A Porous Silicon Carbide Ceramic “, Powder Metallurgy and Metal Ceramics, 1993, vol. 32 (4), pp. 361-65.CrossRef

117.

V. Savolainen, J. Heikonen and J. Ruokolainen: “Simulation of Large-scale Silicon Melt Flow in Magnetic Czochralski Growth”, Journal of Crystal Growth, 2003, vol. 243, pp. 243-60.CrossRef

118.

H. Sasaki, E. Tokizaki and X. Huang: “Temperature Dependence of the Viscosity of Molten Silicon Measured by the Oscillating Cup Method”, Jpn. J. Appl. Phys., 1995, vol. 34, pp. 3432-36.CrossRef

119.

X. Cao and J. Campbell: “The Solidification Characteristics of Fe-rich Intermetallics in Al-11.5Si-0.4Mg Cast Alloys”, Metall. Mater. Trans. a-Physical Metallurgy and Materials Science, 2004, vol. 35A (5), pp. 1425-35.CrossRef

120.

X. Cao, N. Saunders and J. Campbell: “Effect of Iron and Manganese Contents on Convection-free Precipitation and Sedimentation of Primary Alpha-Al(FeMn)Si Phase in Liquid Al-11.5Si-0.4Mg Alloy”, J. Mater. Sci., 2004, vol. 39 (7), pp. 2303-14.CrossRef

121.

A. Flores, M. Sukiennik, A.H. Castillejos, F.A. Acosta and J.C. Escobedo: “A Kinetic Study on the Nucleation and Growth of the Al8FeMnSi2 Intermetallic Compound for Aluminum Scrap Purification”, Intermetallics, 1998, vol. 6 (3), pp. 217-27.CrossRef

122.

A. Flores, J. Escobedo, J. Mendez and M. Mendez: Light Met., 1992, pp. 845–50.

123.

G.H. Nijhof, H.M. van der Donk, C.A.M. Castelijns, S. Bouvet and Y. Bertaud: Light Met., 1996, pp. 1065–69.

124.

H.M. Van der Donk: Method for Refining an Aluminum Scrap Smelt, 1998.

125.

H.L. de Moraes, J.R. de Oliveira, D.C.R. Espinosa and J.A.S. Tenorio: “Removal of Iiron from Molten Recycled Aluminum through Intermediate Phase Filtration”, Materials Transactions, 2006, vol. 47 (7), pp. 1731-36.CrossRef

126.

H. Matsubara, N. Izawa and M. Nakanishi: “Macroscopic Segregation in Al-11 Mass% Si Alloy Containing 2 Mass% Fe Solidified under Centrifugal Force”, Journal of Japan Institute of Light Metals, 1998, vol. 48 (2), pp. 93-97.CrossRef

Titel: Application of Electromagnetic (EM) Separation Technology to Metal Refining Processes: A Review
verfasst von: Lifeng Zhang
Shengqian Wang
Anping Dong
Jianwei Gao
Lucas Nana Wiredu Damoah
Publikationsdatum: 01.12.2014
Verlag: Springer US
Erschienen in: Metallurgical and Materials Transactions B / Ausgabe 6/2014
Print ISSN: 1073-5615
Elektronische ISSN: 1543-1916
DOI: https://doi.org/10.1007/s11663-014-0123-y

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