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References (13)
-
A. Pasteur, Nils Tippkotter, P. Kampeis, R. Ulber (2014)
Optimization of High Gradient Magnetic Separation Filter Units for the Purification of Fermentation ProductsIEEE Transactions on Magnetics, 50
-
Han, Frazier (2005)
Paramagnetic capture mode magnetophoretic microseparator for blood cellsIEEE Electrical Insulation Magazine, 5
-
T. Abbasov, S. Herdem, Muhammet Köksal (1999)
Particle capture in axial magnetic filters with power law flow modelJournal of Physics D, 32
-
S. Uchiyama, S. Kondo, M. Takayasu, I. Eguchi (1976)
Performance of parallel stream type magnetic filter for HGMSIEEE Transactions on Magnetics, 12
-
Luzheng Chen (2011)
Effect of magnetic field orientation on high gradient magnetic separation performanceMinerals Engineering, 24
-
H. Ueda, K. Agatsuma, S. Fuchino, T. Imura, M. Furuse, K. Kajikawa, A. Ishiyama, T. Koizumi, S. Miyake (2010)
Improvement of a High-Gradient Magnetic Separation System for Trapping Immunoglobulin in SerumIEEE Transactions on Applied Superconductivity, 20
-
Haitao Chen, Danny Bockenfeld, D. Rempfer, M. Kaminski, Xianqiao Liu, A. Rosengart (2008)
Preliminary 3-D analysis of a high gradient magnetic separator for biomedical applications☆Journal of Magnetism and Magnetic Materials, 320
-
F. Mishima, S. Hayashi, Y. Akiyama, S. Nishijima (2012)
Development of a Superconducting High Gradient Magnetic Separator for a Highly Viscous FluidIEEE Transactions on Applied Superconductivity, 22
-
R. Birss, R. Gerber, M. Parker (1976)
Theory and design of axially ordered filters for high intensity magnetic separationIEEE Transactions on Magnetics, 12
-
R. Gerber (1978)
Theory of particle capture in axial filters for high gradient magnetic separationJournal of Physics D, 11
-
X. Li, K. Yao, Hongxiu Liu, Z. Liu (2007)
The investigation of capture behaviors of different shape magnetic sources in the high-gradient magnetic fieldJournal of Magnetism and Magnetic Materials, 311
-
D. Inglis, R. Riehn, J. Sturm, R. Austin (2006)
Microfluidic high gradient magnetic cell separationJournal of Applied Physics, 99
-
G. Hatch, Richard Stelter (2001)
Magnetic design considerations for devices and particles used for biological high-gradient magnetic separation (HGMS) systemsJournal of Magnetism and Magnetic Materials, 225
- Publisher
- Emerald Publishing
- Copyright
- Copyright © Emerald Group Publishing Limited
- ISSN
- 0332-1649
- DOI
- 10.1108/COMPEL-03-2015-0140
- Publisher site
- See Article on Publisher Site
Abstract
Purpose – The purpose of this paper is to model the particle capture of elliptic magnetic matrices for parallel stream type high magnetic separation, which can be a guidance for the development of novel elliptic cylinder matrices for high-gradient magnetic separation (HGMS). Design/methodology/approach – The magnetic field distribution around the elliptic matrices is investigated quantitatively and the magnetic field and gradient were calculated. The motion equations of the magnetic particles around the matrices were derived and the particle capture cross-section of elliptic matrices was studied and was compared with that of the conventional circular matrices. Findings – Elliptic matrices can present larger particle capture cross-section than the conventional circular matrices and can be a kind of promising matrices to be applied to HGMS. Originality/value – There is little literature investigating the magnetic characteristics and the particle capture of the elliptic matrices in HGMS, the study is of great significance for the development of novel elliptic magnetic matrices in HGMS.
Journal
COMPEL: The International Journal for Computation and Mathematics in Electrical and Electronic Engineering – Emerald Publishing
Published: Jan 4, 2016