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Separation Science and Technology Volume 40, 2005 - Issue 7
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Original Articles

Computational Fluid Dynamics Simulation of High Gradient Magnetic Separation

Hidehiko Okada National Institute for Materials Science, Tsukuna, JapanCorrespondence[email protected]
,
Kazunari Mitsuhashi University of Tokyo, Kashiwa, Japan
,
Takeshi Ohara Kanazawa Institute of Technology, Kanazawa, Japan
,
Evan R. Whitby Chimera Technologies, Inc, Minnesota, USA
&
Hiroshi Wada University of Tokyo, Kashiwa, Japan
Pages 1567-1584 | Published online: 15 Feb 2007

References

  • Kolm , H. H. US patent 3,567,026, 1971 and 3,676,337 . 1972 .
  • Oberteuffer , J. A. 1973 . High gradient magnetic separation . IEEE Trans. Magn. , MAG‐9 : 303 – 306 .
  • Kelland , D. R. 1973 . High gradient magnetic separation applied to mineral beneficiation . IEEE Trans. Magn. , MAG‐9 : 307 – 310 .
  • Iannicelli , J. 1982 . Development of high extraction magnetic filtration by the kaolin industry of Georgia . IEEE Trans. Magn. , MAG‐12 : 489
  • Yano , J. and Eguchi , I. 1978 . “ Application of high gradient magnetic separation for water treatment in steel industry ” . In Industrial Application of Magnetic Separation Edited by: Liu , Y. A. 134 – 136 . IEEE Inc . 78CH1447–2 MAG
  • Heitmann , H. G. 1978 . “ Studies of the application of electromagnetic filters in power plants ” . In Industrial Application of Magnetic Separation Edited by: Liu , Y. A. 188 – 196 . IEEE Inc .
  • Okada , H. , Fukushima , K. and Tamura , J. 1999 . Magnetic separation of fine colloidal magnetite particles by a superconducting magnet . Trans. IEE of Japan , 119‐B : 1181 – 1186 . in Japanese
  • Kitazawa , K. 2001 . Current trends of superconductivity technology . Oyo Buturi , 70 : 3 – 13 . Japanese
  • Hultgren , A. , Chen , C. S. , Meyer , G. J. and Reich , D. H. 2004 . Cell manipuration using magnetic nanowires . J. Appl. Phys. , 93 : 7554 – 7556 .
  • Thurm , S. and Oldenbach , S. 2002 . Magnetic separation of ferrofluids . J. Magn. Magn. Mater. , 252 : 247 – 249 .
  • Wang , H. , Liu , Q. , Zhang , J. and Hsu , T. Y. 2003 . The size effecton the phase stability of nanograied Fe‐12Ni powders and the magnetic separation of face‐centered‐cubic‐body centered‐cubic phases . Namotechnology , 14 : 696 – 700 .
  • Ritter , J. A. , Ebner , A. D. , Daniel , K. D. and Stewart , K. L. 2004 . Application of high gradient magnetic seapration principles to magnetic drug targeting . J. Magn. Magn. Mater. , 280 : 184 – 201 .
  • Watson , J. H.P. 1973 . Magnetic filtration . J. Appl. Phys. , 44 : 4209 – 4213 .
  • Watson , J. H.P. 1975 . Theory of capture of particles in magnetic high‐intensity filters . IEEE Trans. Magn. , MAG‐11 : 1597 – 1599 .
  • Luborsky , F. E. and Drummond , B. J. 1975 . High gradient magnetic separation: Theory versus experiment . IEEE Trans. Magn. , MAG‐11 : 1696 – 1700 .
  • Birss , R. R. , Gerber , R. and Parker , M. R. 1976 . Theory and design of axially ordered filters for high intensity magnetic separation . IEEE Trans. Magn. , MAG‐12 : 892 – 894 .
  • Uchiyama , S. , Kondo , S. , Takayasu , M. and Eguchi , I. 1976 . Performance of parallel stream type filter for HGMS . IEEE Trans. Magn. , MAG‐12 : 895 – 897 .
  • Lawson , W. F. , Simons , W. H. and Treat , R. P. 1977 . The dynamics of a particle attracted by a magnetized wire . J. Appl. Phys. , 48 : 3213 – 3224 .
  • Hayashi , K. and Uchiyama , S. 1980 . On particle trajectory and capture efficiency around many wires . IEEE Trans. Magn. , MAG‐16 : 827 – 829 .
  • Simons , W. H. and Treat , R. P. 1980 . Particle trajectories in a lattice of parallel magnetized fibers . J. Appl. Phys. , 51 : 578 – 588 .
  • Ohara , T. 1984 . Particle capture theory and experiment on an amorphous magnetic ribbon filter . IEEE Trans. Magn. , MAG‐20 : 436 – 443 .
  • Natenapit , M. 1995 . Effective medium treatment of laminar flow in magnetic filteration . J. Appl. Phys. , 78 : 4353 – 4359 .
  • Badescu , V. , Murariu , V. , Rotariu , N. and Rezlescu , N. 1996 . A new modeling of the initinal buildup evolution on a wire in an axial HGMF filter . J. Magn. Magn. Mater. , 163 : 225 – 231 .
  • Badescu , V. , Rotariu , O. , Murariu , V. and Rezlescu , N. 1997 . Transverse high gradient magnetic filter cell with bounded flow field . IEEE Trans. Magn. , Mag‐33 : 4439 – 4444 .
  • Natenapit , M. and Sanglek , W. 1998 . Capture radius of magneitc particles in random cylindrical matrices in high gradient magnetic separation . J. Appl. Phys. , 85 : 660 – 664 .
  • Markus , F. and Franzereb , M. 1998 . Determination of the capture radii of magnetite bearig hydroide flocs in magneitc filtaration . IEEE Trans. Mag. , Mag‐34 : 3902 – 3909 .
  • Murariu , N. , Rezlescu , V. , Rotariu , N. and Badescu , V. 1998 . Concentration influence on recovery in a high gradient magneitc separation axial filter . IEEE Trans. Mag. , Mag‐34 : 695 – 699 .
  • Murariu , N. , Rezlescu , V. , Rotariu , N. and Badescu , V. 1998 . The effect of suspension concentration on the buildup evolution in a HGMF‐axial magneit filter . Eur. Phys. J. Ap. , 1 : 39 – 44 .
  • Abbasov , T. , Herdem , S. and Koeksal , M. 1999 . Praticle capture in axial magneitc filters with power law flow model . J. Phys. D. , 32 : 1097 – 1103 .
  • Herdem , S. , Abbasov , T. and Koeksal , M. 1999 . Modelling of the buildup process of particles in pores of high gradient magneitc filters using the Fokker‐Planck equation . J. Phys. D. , 32 : 3146 – 3150 .
  • Vincent‐Viry , O. , Mailfert , A. , Gillet , G. and Diot , F. 2000 . Magnetic percolation phenomenon in high‐field high‐gradient separators . IEEE Trans. Mag. , Mag‐36 : 3947 – 3952 .
  • Sido , N. M. , Mailfert , A. , Gillet , G. and Colteu , A. 2003 . Study of high intensity magneitc separation process in grooved palte matrix . Eur. Phys. J. Appl. , 24 : 201 – 207 .
  • Takayasu , M. , Gerber , R. and Friedlaender , F. J. 1983 . Magnetic separation of submicron particles . IEEE Trans. Magn. , MAG‐19 : 2112 – 2114 .
  • Gerber , R. , Takayasu , M. and Friedlaender , J. F. 1983 . Genaralization of HGMS theory: The capture of ultra‐fine praticles . IEEE Trans. Magn. , MAG‐19 : 2115 – 2117 .
  • Gerber , R. 1984 . Magnetic separation of ultra‐fine particles . IEEE Trans. Magn. , MAG‐20 : 1159 – 1164 .
  • Kramer , A. J. , Janssen , J. J.M. and Prenboom , J. A.A.J. 1990 . Single‐wire HGMS of colloidal particles: The evolution of concentration profiles . IEEE Trans. Magn. , MAG‐26 : 1858 – 1860 .
  • Davies , L. P. and Gerber , R. 1990 . 2‐D simulation of ultra‐fine particle capture by a single‐wire magnetic collector . IEEE Trans. Magn. , MAG‐26 : 1867 – 1869 .
  • Patankar , S. V. 1980 . Numerical Heat Transfer and Fluid Flow Taylor and Francis .
  • Patankar , S. V. 1980 . A calculation procedure for two‐dimensional elliptic situations . Numerical Heat Transfer, , 4 : 409
  • Watson , J. H. and Bahaj , P. A.S. 1989 . Vortex capture in high gradient magnetic separators at moderate reynolds number . IEEE Trans. Magn. , Mag‐25 : 3803 – 3805 .
  • Li , Z. and Watson , J. H.P. 1996 . Technical notes an experimental study with a vortex magnetic separation (VMS) device . Minerals Engineering , 9 : 367 – 371 .
  • Watson , J. and Li , H. P.Z. 1997 . Vortex magnetic separation . Proc. Inst. Mech. Enginrs. , 211, Part E : 31 – 42 .
  • Karki , K. C. , Whitby , E. R. , Patankar , S. V. , Winstead , C. , Ohara , T. and Wang , X. 2001 . A numerical model for magneitc chormatgraphy . Appl. Math. Model. , 25 : 355 – 373 .
  • Mitsuhashi , K. , Yoshizaki , R. , Ohara , T. , Matsumoto , F. , Nagai , H. and Wada , H. 2002 . Retension of ions in a magnetic chromatograph using high‐intensity and high‐gradient magnetic fields . Sep. Sci. Tech. , 37 : 3635 – 3645 .
  • Uchiyama , S. and Hayashi , K. 1978 . Industrial Application of Magnetic Separation Edited by: Liu , Y. A. 169 New York : IEEE Inc .

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