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100   $a20121119d2013      uy         0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aPractical design of magnetostatic structure using numerical simulation /$fQiuliang Wang
205   $a1st ed.
210   $aHoboken, N.J. $cJohn Wiley & Sons Inc.$d2013
215   $a1 online resource (498 p.)
300   $aDescription based upon print version of record.
311   $a1-118-39814-9 
320   $aIncludes bibliographical references and index.
327   $aPractical Design of Magnetostatic Structure Using Numerical Simulation; Contents; Foreword; Preface; 1 Introduction to Magnet Technology; 1.1 Magnet Classification; 1.2 Scientific Discoveries in High Magnetic Field; 1.3 High Field Magnets for Applications; 1.3.1 Magnets in Energy Science; 1.3.2 Magnets in Condensed Matter Physics; 1.3.3 Magnets in NMR and MRI; 1.3.4 Magnets in Scientific Instruments and Industry; 1.4 Structure of Magnets; 1.4.1 Configuration of Solenoid Magnet; 1.4.2 Racetrack and Saddle-Shaped Magnets; 1.4.3 Structure of Other Complicated Magnets
327   $a1.5 Development Trends in High Field Magnets1.6 Numerical Methods for Magnet Design; 1.7 Summary; References; 2 Magnetostatic Equations for the Magnet Structure; 2.1 Basic Law of Macroscopic Electromagnetic Phenomena; 2.1.1 Biot-Savart Law; 2.1.2 Faraday's Law; 2.2 Mathematical Basis of Classical Electromagnetic Theory; 2.2.1 Gauss's Theorem; 2.2.2 Stokes' Theorem; 2.2.3 Green's Theorem; 2.2.4 Helmholtz's Theorem; 2.3 Equations of Magnetostatic Fields; 2.3.1 Static Magnetic Field Generated by Constant Current in Free Space; 2.3.2 Basic Properties of Static Magnetic Field
327   $a2.3.3 Magnetic Media in Static Magnetic Field2.3.4 Boundary Conditions of Magnetostatic Field; 2.3.5 Boundary-Value Problem of Static Magnetic Field; 2.3.6 Summary of Equations of Magnetostatic Problem; 2.4 Summary; References; 3 Finite Element Analysis for the Magnetostatic Field; 3.1 Introduction; 3.1.1 Basic Concept of the FEM; 3.1.2 Basic Steps of the FEM; 3.2 Functional Construction for Static Magnetic Field; 3.3 Discretization and Interpolation Function of Solution Domain; 3.3.1 Principle of Selecting Subdivisions in the Domain; 3.3.2 Selection of Interpolation Function
327   $a3.3.3 Unified Expressions of Interpolation Function3.4 Formulation of System Equations; 3.4.1 Two-Dimensional Cartesian Coordinate System; 3.4.2 Three-Dimensional Cartesian Coordinate System; 3.4.3 Axially Symmetric Scalar Potential System; 3.5 Solution of System Equation for the FEM; 3.6 Applied FEM for Magnet Design; 3.6.1 Magnetic Field for a Superconducting Magnet with LTS and HTS; 3.6.2 Magnetic Field for a Superferric Dipole Magnet; 3.6.3 Force Characteristics of a Superconducting Ball in Magnetic Field; 3.7 Summary; References; 4 Integral Method for the Magnetostatic Field
327   $a4.1 Integral Equation of Static Magnetic Field4.2 Magnetic Field from Current-Carrying Conductor; 4.2.1 Magnetic Field Generated by Rectangular Conductor; 4.2.2 Magnetic Field of Arc-Shaped Winding; 4.2.3 Magnetic Field Generated by Solenoid Coil; 4.2.4 Magnetic Field of Elliptical Cross-Section Winding; 4.2.5 Parallel Plane Field; 4.2.6 Magnetic Field ofWedge-Shaped Current Block with Triangular Cross-Section; 4.2.7 Magnetic Field of Wedge-Shaped Structure with Rectangular Cross-Section; 4.3 Magnetic Field with Anisotropic Magnetization
327   $a4.3.1 Subdivision of Three-Dimensional Ferromagnetic Media
330   $a"Covers extensively the magnet design and computation aspects from theories to practical applications, emphasizing design methods of practical structures such as superconducting, electromagnetic and permanent magnet for use in various scientific instruments, industrial processing, biomedicine and special electrical equipments"--$cProvided by publisher.
606   $aSuperconductors$xMagnetic properties
606   $aMagnetic instruments$xDesign and construction$xMathematics
606   $aMagnetic instruments$xMathematical models
606   $aSuperconducting magnets
615  0$aSuperconductors$xMagnetic properties.
615  0$aMagnetic instruments$xDesign and construction$xMathematics.
615  0$aMagnetic instruments$xMathematical models.
615  0$aSuperconducting magnets.
676   $a621.3/5
686   $aSCI022000$2bisacsh
700   $aWang$b Qiuliang$01698412
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910818175703321
996   $aPractical design of magnetostatic structure using numerical simulation$94079839
997   $aUNINA