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Power magnetic devices : a multi-objective design approach / S.D. Sudhoff

Author
Sudhoff, Scott D.
Published
Hoboken, New Jersey : IEEE Press / Wiley, [2013]
Physical Description
1 online resource
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Contents
Series Page; Title Page; Copyright; Dedication; Preface; Chapter 1: Optimization-Based Design; 1.1 Design Approach; 1.2 Mathematical Properties of Objective Functions; 1.3 Single-Objective Optimization Using Newton's Method; 1.4 Genetic Algorithms: Review of Biological Genetics; 1.5 The Canonical Genetic Algorithm; 1.6 Real-Coded Genetic Algorithms; 1.7 Multi-Objective Optimization and the Pareto-Optimal Front; 1.8 Multi-Objective Optimization Using Genetic Algorithms; 1.9 Formulation of Fitness Functions for Design Problems; 1.10 A Design Example; References; Problems., Chapter 2: Magnetics and Magnetic Equivalent Circuits2.1 Ampere's Law, Magnetomotive Force, and Kirchhoff's Mmf Law for Magnetic Circuits; 2.2 Magnetic Flux, Gauss's Law, and Kirchhoff's Flux Law for Magnetic Circuits; 2.3 Magnetically Conductive Materials and Ohm's Law for Magnetic Circuits; 2.4 Construction of the Magnetic Equivalent Circuit; 2.5 Translation of Magnetic Circuits to Electric Circuits: Flux Linkage and Inductance; 2.6 Representing Fringing Flux in Magnetic Circuits; 2.7 Representing Leakage Flux in Magnetic Circuits; 2.8 Numerical Solution of Nonlinear Magnetic Circuits., 2.9 Permanent Magnet Materials and Their Magnetic Circuit Representation2.10 Finite Element Analysis; References; Problems; Chapter 3: Introduction to Inductor Design; 3.1 Common Inductor Architectures; 3.2 DC Coil Resistance; 3.3 DC Inductor Design; 3.4 Case Study; 3.5 Closing Remarks; References; Problems; Chapter 4: Force and Torque; 4.1 Energy Storage in Electromechanical Devices; 4.2 Calculation of Field Energy; 4.3 Force from Field Energy; 4.4 Co-Energy; 4.5 Force From Co-Energy; 4.6 Conditions for Conservative Fields; 4.7 Magnetically Linear Systems; 4.8 Torque., 4.9 Calculating Force Using Magnetic Equivalent CircuitsReferences; Problems; Chapter 5: Introduction to Electromagnet Design; 5.1 Common Electromagnet Architectures; 5.2 Magnetic, Electric, and Force Analysis of an Ei-Core Electromagnet; 5.3 Ei-Core Electromagnet Design; 5.4 Case Study; References; Problems; Chapter 6: Magnetic Core Loss; 6.1 Eddy Current Losses; 6.2 Hysteresis Loss and The B-H Loop; 6.3 Empirical Modeling of Core Loss; 6.4 Time Domain Modeling of Core Loss; References; Problems; Chapter 7: Transformer Design; 7.1 Common Transformer Architectures., and 7.2 T-Equivalent Circuit Model7.3 Steady-State Analysis; 7.4 Transformer Performance Considerations; 7.5 Core-Type Transformer Configuration; 7.6 Core-Type Transformer Mec; 7.7 Core Loss; 7.8 Core-Type Transformer Design; 7.9 Case Study; 7.10 Closing Remarks; References; Problems; Chapter 8: Distributed Windings and Rotating Electric Machinery; 8.1 Describing Distributed Windings; 8.2 Winding Functions; 8.3 Air-Gap Magnetomotive Force; 8.4 Rotating MMF; 8.5 Flux Linkage and Inductance; 8.6 Slot Effects and Carter's Coefficient; 8.7 Leakage Inductance; 8.8 Resistance.
Summary
Presents a multi-objective design approach to the many power magnetic devices in use today Power Magnetic Devices: A Multi-Objective Design Approach addresses the design of power magnetic devices-including inductors, transformers, electromagnets, and rotating electric machinery-using a structured design approach based on formal single- and multi-objective optimization. The book opens with a discussion of evolutionary-computing-based optimization. Magnetic analysis techniques useful to the design of all the devices considered in the book are then set forth. This material is then used for inductor design so readers can start the design process. Core loss is next considered; this material is used to support transformer design. A chapter on force and torque production feeds into a chapter on electromagnet design. This is followed by chapters on rotating machinery and the design of a permanent magnet AC machine. Finally, enhancements to the design process including thermal analysis and AC conductor losses due to skin and proximity effects are set forth. Power Magnetic Devices: Focuses on the design process as it relates to power magnetic devices such as inductors, transformers, electromagnets, and rotating machinery Offers a structured design approach based on single- and multi-objective optimization Helps experienced designers take advantage of new techniques which can yield superior designs with less engineering time Provides numerous case studies throughout the book to facilitate readers' comprehension of the analysis and design process Includes Powerpoint-slide-based student and instructor lecture notes and MATLAB-based examples, toolboxes, and design codes Designed to support the educational needs of students, Power Magnetic Devices: A Multi-Objective Design Approach also serves as a valuable reference tool for practicing engineers and.
Designers. MATLAB examples are available via the book support site.
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ISBN
9781118824634 (ePub)
1118824636 (ePub)
9781118824597 (Adobe PDF)
1118824598 (Adobe PDF)
9781118824603
1118824601
1306412242
9781306412247
1118489993
9781118489994
9781118489994 (cloth)
Bibliography Note
Includes bibliographical references.
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