Motor Control. Nandulal Gavali MINDA R&D

Similar documents
Principles of Adjustable Frequency Drives

How to Turn an AC Induction Motor Into a DC Motor (A Matter of Perspective) Steve Bowling Application Segments Engineer Microchip Technology, Inc.

Motor Fundamentals. DC Motor

Induction Motor Theory

THIS paper reports some results of a research, which aims to investigate the

Lab 8: DC generators: shunt, series, and compounded.

Sensorless Field Oriented Control (FOC) for Permanent Magnet Synchronous Motors (PMSM)

Simulation of VSI-Fed Variable Speed Drive Using PI-Fuzzy based SVM-DTC Technique

Mathematical Modelling of PMSM Vector Control System Based on SVPWM with PI Controller Using MATLAB

8 Speed control of Induction Machines

Motors and Generators

13 ELECTRIC MOTORS Basic Relations

SYNCHRONOUS MACHINES

New Pulse Width Modulation Technique for Three Phase Induction Motor Drive Umesha K L, Sri Harsha J, Capt. L. Sanjeev Kumar

SECTION 4 ELECTRIC MOTORS UNIT 17: TYPES OF ELECTRIC MOTORS

INDUCTION REGULATOR. Objective:

3-Phase BLDC Motor Control with Hall Sensors Using 56800/E Digital Signal Controllers

Principles and Working of DC and AC machines

Pulse Width Modulated (PWM) Drives. AC Drives Using PWM Techniques

Comparative Review Of PMSM And BLDCM Based On Direct Torque Control Method

Modeling and Simulation of a Novel Switched Reluctance Motor Drive System with Power Factor Improvement

DHANALAKSHMI COLLEGE OF ENGINEERING DEPARTMENT OF ELECTRICAL AND ELECTRONICS ENGINEERING EE ELECTRICAL MACHINES II UNIT-I SYNCHRONOUS GENERATOR

Simulation of Electric Drives using the Machines Library and the SmartElectricDrives Library

MODELLING AND SIMULATION OF SVPWM INVERTER FED PERMANENT MAGNET BRUSHLESS DC MOTOR DRIVE

Mathematical Modeling and Dynamic Simulation of a Class of Drive Systems with Permanent Magnet Synchronous Motors

FREQUENCY CONTROLLED AC MOTOR DRIVE

Pulse Width Modulated (PWM)

*ADVANCED ELECTRIC GENERATOR & CONTROL FOR HIGH SPEED MICRO/MINI TURBINE BASED POWER SYSTEMS

DYNAMIC MODEL OF INDUCTION MOTORS FOR VECTOR CONTROL. Dal Y. Ohm Drivetech, Inc., Blacksburg, Virginia

BALDOR ELECTRIC COMPANY SERVO CONTROL FACTS A HANDBOOK EXPLAINING THE BASICS OF MOTION

MATHEMATICAL MODELING OF BLDC MOTOR WITH CLOSED LOOP SPEED CONTROL USING PID CONTROLLER UNDER VARIOUS LOADING CONDITIONS

AC Induction Motor Slip What It Is And How To Minimize It

Modelling, Simulation and Performance Analysis of A Variable Frequency Drive in Speed Control Of Induction Motor

Comparison of Various PWM Techniques for Field Oriented Control VSI Fed PMSM Drive

Direct Current Motors

Speed Control Methods of Various Types of Speed Control Motors. Kazuya SHIRAHATA

Inductance. Motors. Generators

Fuzzy Adaptive PI Controller for Direct Torque Control Algorithm Based Permanent Magnet Synchronous Motor

Unit 33 Three-Phase Motors

Simulation and Analysis of Parameter Identification Techniques for Induction Motor Drive

Prof. Krishna Vasudevan, Prof. G. Sridhara Rao, Prof. P. Sasidhara Rao

Stepper motor I/O. Application Note DK Motion Control. A General information on stepper motors

2. A conductor of length 2m moves at 4m/s at 30 to a uniform magnetic field of 0.1T. Which one of the following gives the e.m.f. generated?

WIND TURBINE TECHNOLOGY

Design and Simulation of Z-Source Inverter for Brushless DC Motor Drive

Design and Analysis of Switched Reluctance Motors

Topics to cover: 1. Structures and Drive Circuits 2. Equivalent Circuit. Introduction

Speed Control and Power factor Correction using Bridgeless Buck Boost Converter for BLDC Motor Drive

Application Note AN-1187

WHITE PAPER. DC Motors Explained. DC Motors Explained: White Paper, Title Page

INSTRUMENTATION AND CONTROL TUTORIAL 2 ELECTRIC ACTUATORS

Digital Control of Acim Using dspic

Electronic Speed Variator for a Brushless DC Motor

Synchronous motor. Type. Non-excited motors

Design of a PM Brushless Motor Drive for Hybrid Electrical Vehicle Application

Dually Fed Permanent Magnet Synchronous Generator Condition Monitoring Using Stator Current

Technical Guide No High Performance Drives -- speed and torque regulation

Renewable Energy Sources Based Permanent Magnet Brushless DC Motor Drive

Chen. Vibration Motor. Application note

Micro-Step Driving for Stepper Motors: A Case Study

SIMULATION AND SPEED CONTROL OF INDUCTION MOTOR DRIVES

Available online at Available online at

DC Link Voltage Control

DC motors: dynamic model and control techniques

Variable Voltage Variable Frequency Speed Control of Induction Motor Using FPGA-Xilinx

Power Electronics. Prof. K. Gopakumar. Centre for Electronics Design and Technology. Indian Institute of Science, Bangalore.

FIELD ORIENTED CONTROL OF STEP MOTORS

Setup for PWM Tests of BLDC Motor

CHAPTER 4 DESIGN OF INTEGRAL SLOT AND FRACTIONAL SLOT BRUSHLESS DC MOTOR

Motor Control Application Tuning (MCAT) Tool for 3-Phase PMSM

DIRECT CURRENT GENERATORS

Control Strategies of the Doubly Fed Induction Machine for Wind Energy Generation Applications

How To Measure Power Of A Permanent Magnet Synchronous Motor

Simulation and Analysis of PWM Inverter Fed Induction Motor Drive

Lab 14: 3-phase alternator.

TORQUE RIPPLES MINIMIZATION ON DTC CONTROLLED INDUCTION MOTOR WITH ADAPTIVE BANDWIDTH APPROACH

AC generator theory. Resources and methods for learning about these subjects (list a few here, in preparation for your research):

DC Motor control Reversing

Equipment: Power Supply, DAI, Wound rotor induction motor (8231), Electrodynamometer (8960), timing belt.

1. The diagram below represents magnetic lines of force within a region of space.

Introduction. related products. Upon completion of Basics of DC Drives you will be able to: Explain the concepts of force, inertia, speed, and torque

Reliable World Class Insights Your Silicon Valley Partner in Simulation ANSYS Sales, Consulting, Training & Support

Discover the power of e-learning! The Quick Guide to AC Variable Frequency

Simple Analysis for Brushless DC Motors Case Study: Razor Scooter Wheel Motor

Design and Development of Speed Control of Induction motor drive using Pulse-Width Modulation

The VOLTECH HANDBOOK of PWM MOTOR DRIVES. Andrew Tedd

AC Generators and Motors

Transient analysis of integrated solar/diesel hybrid power system using MATLAB Simulink

DC GENERATOR THEORY. LIST the three conditions necessary to induce a voltage into a conductor.

REPORT ON CANDIDATES WORK IN THE CARIBBEAN ADVANCED PROFICIENCY EXAMINATION MAY/JUNE 2008 ELECTRICAL AND ELECTRONIC TECHNOLOGY (TRINIDAD AND TOBAGO)

Simulation of Power Control of a Wind Turbine Permanent Magnet Synchronous Generator System

Application Information

Advance Electronic Load Controller for Micro Hydro Power Plant

Influence of PWM Schemes and Commutation Methods. for DC and Brushless Motors and Drives

The following document contains information on Cypress products.

AN470 APPLICATION NOTE

Outline Servo Control

LOSSELESS STARTING METHOD FOR THE WOUND ROTOR INDUCTION MOTOR

Transcription:

Motor Control Nandulal Gavali MINDA R&D

Outline of the Presentation 4/9/2 DC Motor Basics & Control Stepper Motor Basics & Control Induction Motor Control BLDC Motor Control PMSM Motor Control 2

DC Motor Basics & Control Types of DC Motors Separately Excited DC Motor Series Excited DC Motor Shunt Excited DC Motor Cumulatively Compound Speed Control of DC Motor Fundamentals Rectifier Controlled Chopper Controlled 4/9/2 3

Separately Excited DC Motor If Eb = Ke f wm Vdc = Eb + Ia Ra Idc Vdc Vf Te = Ke f Ia Eb Motor Back EMF wm Ke Motor Constant wm f Flux per pole Te Electromagnetic Torque Developed By the Motor 4/9/2 T 4

Shunt DC Motor If Eb = Ke f wm Vdc = Eb + Ia Ra Idc Vdc Te = Ke f Ia Eb Motor Back EMF wm Ke Motor Constant w f Flux per pole Te Electromagnetic Torque Developed By the Motor T 4/9/2 5

Series DC Motor Eb = Ke f wm Idc Vdc = Eb + Ia Ra Vdc Te = Ke f Ia Eb Motor Back EMF wm Ke Motor Constant f Flux per pole Te Electromagnetic Torque Developed By the Motor T 4/9/2 6

Compound DC Motor No load speed is depends upon strength of shunt field and slope of characteristic is depends on series field Used in applications where high starting torque is needed and also the no load speed will remain in safe zones Pressing machines are typical examples of the application Idc Vdc wm T 4/9/2 7

DC Motor Control Fundamentals I I Target Error 4/9/2 E E EI I I EI 8

Rectifier Controlled DC Motor 4/9/2 9

Chopper Controlled DC Motor Buck converter can be used as single quadrant converter for DC motor control. For multi-quadrant converter bridge converters are being used 4/9/2

Stepper Motor Fundamentals A stepper motor is an electric machine that rotates in discrete angular increments or steps when applied a current pulse. Each pulse applied to the motor causes its shaft to move a certain angle of rotation, called a stepping angle. The stepper motor has salient poles on both the stator and the rotor, and normally only the stator poles hold the poly-phase windings called the control windings. Types of Stepper Motors Permanent Magnet Rotor Reluctance type Rotor Hybrid type 4/9/2

Stepper Motor Fundamentals Operating Principal of Hybrid Stepper Motor The operation of the stepper motor relies on the simple principle of magnetic attraction. This principle states that opposite magnetic poles attract while like poles repel each other. Fig shows construction of 4 phase 6 pole stepper hybrid motor If winding A or C is excited, pole or pole 3 is energized as south. If winding B or D is excited, pole 2 or pole 4 is energized as north. 4/9/2 2

Stepper Motor Driving Topology Unipolar Drive A B C D Motor Windings A F D B C Vector Diagram 4/9/2 3

Stepper Motor Driving Topology Bipolar Drive A B C D Motor Windings Vector Diagram 4/9/2 4

Stepper Motor Driving Mode Full Step Driving Mode A B C D Rotor Mode Mode 2 2 Mode 3 3 Mode 4 4 A F D C B Vector Diagram 4/9/2 5

Stepper Motor Driving Mode Half Step Driving Mode A B C D Mode Mode 2 Mode 3 Mode 4 Mode 5 Mode 6 Mode 7 Mode 8 Rotor /2 3 / 2 2 5 / 2 3 7 / 2 Vector Diagram 4/9/2 6

Stepper Motor Driving Mode Micro Stepping Driving Mode In full step and half step mode, the same amount of current flows through the energized stator windings. However, if the currents are not equal, the rotor will be shifted toward the stator pole with the higher current. The amount of deviation is proportionate to the values of the currents in each winding. Refer ZaberWiki for further understanding 4/9/2 7

Induction Motor Fundamentals Stator has 3 phase sinusoidaly distributed winding. Rotor consists of 3 phase windings with shorted copper bars at the end Rotating magnetic field is generated in the stator if 3 phase balance supply is applied to the stator This rotating magnetic field induces voltage in the rotor by transforming action The rotor current produces the rotor magnetic field which rotates with relative angular velocity which is called as slip (S) velocity 4/9/2 8

Induction Motor Fundamentals Induction Motor Speed-Torque Characteristics 4/9/2 9

Induction Motor Control Sine-Triangle PWM Control Modulation Index DC Bus utilization is 78% 4/9/2 m VS VT 2

Induction Motor Control Space Vector PWM Control UAB UBC UCA Vector c b a U U U6 UDC UDC U2 U8 U24 U3 U UDC UDC UDC UDC 4/9/2 UDC UDC UDC UDC UDC UDC 2

Induction Motor Control Space Vector PWM Control Works on the constant volt-seconds principal T ma TPWM sin( ) 3 T2 ma TPWM sin T TPWM (T T2 ) TPWM T 4/9/2 T T2 T T T2 T T ma = Modulation Index 22

Induction Motor Control Space Vector PWM Control 4/9/2 23

Reference Frame Theory The inductances of the rotating machines are time varying quantities and depends on the speed of the motor All time varying inductances can be eliminated by referring stator and rotor variables to a frame of reference which may rotate at any angular velocity called arbitrary reference frame (w) When w = ; the reference frame is stationary When w = we; the reference frame is synchronously rotating reference frame and the transformation is known is as Park s Transformation When w = wr; the reference frame is fixed in the rotor 4/9/2 24

Reference Frame Theory 4/9/2 25

Reference Frame Theory 4/9/2 26

Scalar V/F Control of Induction Motor Simple implementation : Just need a 3 sine modulated PWM applied to VSI (Voltage Source Inverter) No Position Information is needed Doesn t deliver a good dynamic response 4/9/2 27

Vector Control of Induction Motor FOC or Vector Control involves controlling the components of the motor stator currents, represented by a vector, in a rotating reference frame (with a d-q coordinate system) In a arbitrary reference frame the electromagnetic torque is similar to the torque expression of the separately excited DC motor Torque and Speed are decoupled using FOC algorithm Gives better dynamic response compare to scalar control 4/9/2 28

Vector Control of Induction Motor ref iqref PI G idref Flux Controller Vqref PI Vdref PI d, q, V SVM V Inverse Park Transformation VSI Inverse Clarke Transformation r iq id d, q, i i, a, b, c Clarke Transformation Park Transformation Current Model ia ib Induction Motor m 4/9/2 29

BLDC Motor Control Fundamentals Stator has 3 phase uniformly distributed winding. Rotor consists of permanent magnets Torque speed curve is similar to DC shunt motor hence BLDC motor essentially is constant torque machine 4/9/2 wm T 3

Sensor based BLDC Control Upper or Lower switches can be controlled by PWM Generally Upper switches are controlled by PWM due to the limited bootstrapping time 4/9/2 3

Sensor based BLDC Control 4/9/2 32

Sensor based BLDC Control 4/9/2 33

Sensorless BLDC Control Current commutation is done without Hall Sensors Calculate an appropriate point at which the next vector applied The switching point can be find out where the Back-EMF of the phase crosses zero potential 4/9/2 34

BLDC Controller for E-Bike BLDC Hub type motor is being used in E-bike application Main aim to maintain torque from rated speed to zero speed I I 4/9/2 35

PMSM Motor Control Fundamentals A PMSM rotates at a fixed speed in synchronization with the frequency of the power source independent of the load, provided an adequate field current is applied on the motor windings. 4/9/2 36

PMSM Motor Control Fundamentals A PMSM and a BLDC motor have no intrinsic differences. The winding function of the BLDC motor is trapezoidal (uniformly distributed) while the winding function of the PMSM is sinusoidal (sinusoidaly distributed) 4/9/2 37

PMSM Motor Scalar Control The PMSM Motor operating frequency f and amplitude A is controlled using the V/F curve. The phase is synchronized by the hall sensors Actually hall sensor gives the sector information for V/F curve 4/9/2 38

PMSM Motor Scalar Control The PMSM Motor operating frequency f and amplitude A is controlled using the V/F curve. The phase is synchronized by the hall sensors Actually hall sensor gives the sector information for V/F curve 4/9/2 39

PMSM Motor Field Oriented Control ref iqref Vqref idref Vdref iq id V d, q, V i d, q, i, ia ib a, b, c V V 4/9/2 idref ~ I I q ji d 4

Thank You 4/9/2 4

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information