Permanent Magnet Motor Technology Design and Applications, Third Edition

The importance of permanent magnet (PM) motor technology and its impact on electromechanical drives has grown exponentially since the publication of the bestselling second edition. The PM brushless motor market has grown considerably faster than the overall motion control market. This rapid growth makes it essential for electrical and electromechanical engineers and students to stay up-to-date on developments in modern electrical motors and drives, including their control, simulation, and CAD. Reflectinginnovations in the development of PM motors for electromechanical drives, Permanent Magnet Motor Technology: Design and Applications, Third Edition demonstrates the construction of PM motor drives and supplies ready-to-implement solutions to common roadblocks along the way. This edition supplies fundamental equations and calculations for determining and evaluating system performance, efficiency, reliability, and cost. It explores modern computer-aided design of PM motors, including the finite element approach, and explains how to select PM motors to meet the specific requirements of electrical drives. The numerous examples, models, and diagrams provided in each chapter facilitate a lucid understanding of motor operations and characteristics. This 3rd edition of a bestselling reference has been thoroughly revised to include: Chapters on high speed motors and micromotors Advances in permanent magnet motor technology Additional numerical examples and illustrations An increased effort to bridge the gap between theory and industrial applications Modified research results The growing global trend toward energy conservation makes it quite possible that the era of the PM brushless motor drive is just around the corner. This reference book will give engineers, researchers, and graduate-level students the comprehensive understanding required to develop the breakthroughs that will push this exciting technology to the forefront.

Preface1. Introduction1.1 Permanent magnet versus electromagnetic excitation 1.2 Permanent magnet motor drives 1.3 Towards increasing the motor efficiency 1.4 Classification of permanent magnet electric motors 1.5 Trends in permanent magnet motors and drives industry 1.6 Applications of permanent magnet motors 1.7 Mechatronics1.8 Fundamentals of mechanics of machines 1.9 Torque balance equation 1.10 Evaluation of cost of a PM motor 2. Permanent Magnet Materials and Circuits 2.1 Demagnetization curve and magnetic parameters 2.2 Early history of permanent magnets2.3 Properties of permanent magnets2.4 Approximation of demagnetization curve and recoil line 2.5 Operating diagram2.6 Permeances for main and leakage fluxes 2.7 Calculation of magnetic circuits with permanent magnets2.8 Mallinson-Halbach array and Halbach cylinder 3. Finite Element Analysis 3.1. Gradient, divergence and curl3.2 Biot-Savart, Faraday's, and Gauss's laws 3.3 Gauss's theorem 3.4 Stokes' theorem 3.5 Maxwell's equations 3.6 Magnetic vector potential 3.7 Energy functionals 3.8 Finite element formulation 3.9 Boundary conditions 3.10 Mesh generation 3.11 Forces and torques in electromagnetic field3.12 Inductances 3.13 Interactive FEM programs 4. Permanent Magnet d.c. Commutator Motors 4.1 Construction 4.2 Fundamental equations4.3 Sizing procedure 4.4 Armature reaction 4.5 Commutation 4.6 Starting 4.7 Speed control 4.8 Servo motors 4.9 Magnetic circuit 4.10 Applications 5. Permanent Magnet Synchronous Motors 5.1 Construction 5.2 Fundamental relationships5.3 Phasor diagram5.4 Characteristics 5.5 Starting5.6 Reactances 5.7 Rotor configurations 5.8 Comparison between synchronous and induction motors 5.9 Sizing procedure and main dimensions 5.10 Performance calculation 5.11 Dynamic model of a PM motor 5.12 Noise and vibration of electromagnetic origin 5.13 Applications 6. d.c. Brushless Motors 6.1 Fundamental equations 6.2 Commutation of PM brushless motors6.3 EMF and torque of PM brushless motors6.4 Torque-speed characteristics 6.5 Winding losses 6.6 Torque ripple6.7 Rotor position sensing of d.c. brushless motors6.8 Sensorless motors6.9 Motion Control of PM brushless motors6.10 Universal brushless motor electromechanical drives 6.11 Smart motors 6.12 Applications 7. Axial Flux Motors 7.1 Force and torque 7.2 Performance 7.3 Double-sided motor with internal PM disk rotor 7.4 Double-sided motor with one stator 7.5 Single-sided motors 7.6 Ironless double-sided motors 7.7 Multidisk motors 7.8 Applications 8. High Power Density Brushless Motors 8.1 Design considerations 8.2 Requirements 8.3 Multiphase motors 8.4 Fault-tolerant PM brushless machines 8.5 Surface PM versus salient-pole rotor8.6 Electromagnetic effects8.7 Cooling8.8 Construction of motors with cylindrical rotors8.9 Construction of motors with disk rotors8.10 Transverse flux motors8.11 Applications 9. High Speed Motors9.1 Why high speed motors? 9.2 Mechanical requirements 9.3 Construction of high speed PM brushless motors 9.4 Design of high speed PM brushless motors 9.5 Ultra high speed motors 9.6 Applications 10. Brushless Motors of Special Construction 10.1 Single-phase motors10.2 Actuators for automotive 10.3 Integrated starter-generator 10.4 Large diameter motors 10.5 Three-axis torque motor 10.6 Slotless motors 10.7 Tip driven fan motors 11. Stepping Motors 11.1 Features of stepping motors 11.2 Fundamental equations 11.3 PM stepping motors 11.4 Reluctance stepping motors 11.5 Hybrid stepping motors 11.6 Motion control of stepping motors 11.7 PM stepping motors with rotor position transducers 11.8 Single-phase stepping motors11.9Voltage Equations and Electromagnetic Torque11.10 Characteristics 11.11 Applications 12. Micromotors 12.1 What is a micromotor? 12.2 Permanent magnet brushless micromotors12.3 Applications 13. Optimization 13.1 Mathematical formulation of optimization problem 13.2 Nonlinear programming methods13.3 Population-based incremental learning 13.4 Response surface methodology 13.5 Modern approach to optimization of PM motors 14. Maintenance 14.1 Basic requirements to electric motors 14.2 Reliability 14.3 Failures of electric motors 14.4 Calculation of reliability of small PM brushless motors 14.5 Vibration and noise14.6 Condition monitoring14.7 Protection 14.8 Electromagnetic and radio frequency interference 14.9 Lubrication Appendices A. Leakage Inductance of a.c. Stator WindingsB. Losses in a.c. MotorsSymbols and Abbreviations References Index

ProfessorJacek F. Gieras, IEEE Fellow