Electric Motor Control DC, AC, and BLDC Motors
Auteur : Kim Sang-Hoon
Electric Motor Control: DC, AC, and BLDC Motors introduces practical drive techniques of electric motors to enable stable and efficient control of many application systems, also covering basic principles of high-performance motor control techniques, driving methods, control theories and power converters.
Electric motor drive systems play a critical role in home appliances, motor vehicles, robotics, aerospace and transportation, heating ventilating and cooling equipment?s, robotics, industrial machinery and other commercial applications.
The book provides engineers with drive techniques that will help them develop motor drive system for their applications.
1. Fundamentals of Electric Motors2. Control of Direct Current Motors3. Alternating Current Motors: Synchronous Motor and Induction Motor4. Modeling of Alternating Current Motors and Reference Frame Theory5. Vector Control of Alternating Current Motors6. Current Regulator of Alternating Current Motors7. Pulse Width Modulation Inverter8. High-Speed Operation of Alternating Current Motors9. Speed Estimation and Sensorless Control of Alternating Current Motors10. Brushless Direct Current Motors
Primarily a reference book for industry engineers in the electric motor drive fields such as home appliances, motor vehicles, robotics, aerospace and transportation, heating ventilating and cooling equipment’s, industrial machinery, and other commercial applications. Graduate students and researchers in drive methods of electric motors.
- Includes practical solutions and control techniques for industrial motor drive applications currently in use
- Contains MATLAB/Simulink simulation files
- Enables engineers to understand the applications and advantages of electric motor drive systems
Date de parution : 05-2017
Ouvrage de 438 p.
19x23.3 cm
Thème d’Electric Motor Control :
Mots-clés :
Anti-windup control; BLDC motors; Base speed; Bipolar and unipolar PWM; Bipolar and unipolar switching schemes; Capability curve; Classification of electric motors; Constant power region; Constant volts per Hertz control; Current control; Current regulator; Cylindrical (or nonsalient pole) type and salient pole type; DC motor; Dead-time compensation; Decoupling control; Direct vector control and indirect vector control; Discontinuous PWM techniques; Drive methods of BLDC motors; D-q axes model of an induction motor; D-q model of a permanent magnet synchronous motor; Equivalent circuit; Feedforward control; Field-weakening method; Flux estimation methods; Flux-weakening control; Flux-weakening region II; Fundamental rotation principle; Generalized PWM techniques-based offset voltage; High-speed operations; IP controller; IPMSM; Induction motors; Load modeling; MTPA operation; Modeling of AC motors; Modeling of BLDC motors; Motor drive system; Overmodulation; PI controller; PI gains selection method; PWM inverter; Position sensors; Reference frame transformation; Resolver; Rotary encoder; Rotating machine; SPMSM; SVPWM technique; Sensorless control of AC motors; Sensorless control schemes; Speed control; Speed estimation methods; Synchronous d-q frame PI current regulator; Synchronous motors; The speed and current control of a BLDC motor; Torque ripple during commutations; Vector control of SPMSMs and IPMSMs; Vector control of an induction motor