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ABSTRACT

In this thesis, a current source inverter fed squirrel cage induction motor drive at constant air gap flux is presented. The drive scheme is conceived to take advantage of the short circuit withstand capability of the current source inverter and the ruggedness (even under harsh conditions) of the squirrel cage induction motor. The variable inverter input dc link current is derivable from either a controlled ac to dc converter or a controlled dc to dc converter. The constant motor air gap flux control drive scheme has inner dc link current control loop and an outer motor speed control loop that maintains the motor slip frequency constant for a given motor load torque. The closed loop control parameters are selected such that negligible torque pulsation and relatively fast motor speed response are obtained without the need for an inverter output capacitor filter. A 400V, 10hp, 1440rpm, 50Hz squirrel cage induction motor is used to simulate the motor drive scheme in Matlab-Simulink environment. For step changes in demand (reference) speed at no load torque and at load torque equals to or less than the motor rated torque, the drive response has relatively fast settling time and acceptably low overshoot/undershoot over the motor speeds not exceeding the rated value.

 

 

TABLE OF CONTENTS

Approval Page………………………………………………………………………………………………I

Certification………………………………………………………………………………………………..II

Title ……………………………………………………………………………. …III

Dedication ……………………………………………….………………………….IV

Acknowledgement ………………………………………………….……………… V

Abstract ……………………………………………………….………………. VII

Table of contents ……………………………………………….……………. …VIII

List of Figures ……………………………………………….…………………… XII

List of Tables ……………………………………………….…………………… XV

List of Appendix ………………………………………………………………. XVI

Definition of Terms and Nomenclature……………………………………………………..XVII

 

CHAPTER ONE: Introduction

1.0     Introduction ……………………………………………………….. …………1

1.1     Overview of the study………………………………………………………………………….2

1.2     Objectives of the Study………………………………………………………………………..5

1.3       Thesis Arrangement………….………………………….…..…….……….…5

 

CHAPTER TWO: Literature Review.

2.0 An outline to current Source inverter –Fed Induction Motor Drives ……………7

 

CHAPTER THREE: Analysis of Squirrel Cage Induction Motor with Current Source Inverter Input.

3.0     Introduction …………………….…………………………………………19

3.1     Dynamic State Analyses……………………………………………………20

3.2     Motor Steady State Equation Analysis…………………………………….23

3.3     Developed Mechanical Power……………………………………………. 25

3.4     Developed Mechanical Torque ………………………………………25

 

CHAPTER FOUR: THE CURRENT SOURCE INVERTER

4.1 The Power Circuit………………………………………………………………………………… 32

4.1.1 The power circuit with non-self-turn off switch…………………………………….. 32

4.1.2  Power circuit with self-turn off switch………………………………………………… 33

4.2     Current Source Inverter Control Requirement……………………………………….34

4.2.1 Switch Sequence for Six Pulse Output Signal……………………………………… 34

4.2.2  Resultant Line Current Waveform………………………………………… 37

4.3 The Control Logic Design…………………………………………………………………….  38

4.3.1  Karnaugh Maps……………………….…………………………………..  41

4.4     The Open Circuit Performance with Specified Load……………………… 46

4.4.1  Current Source Inverter with Resistive Load………………………………47

4.4.2  Current Source Inverter with Induction Motor Load…..…………………. 48

4.5     Control Methods of the Input Current to the Current Source Inverter.……. 51

4.5.1  Pulse Width Modulated (PWM) DC to DC Converter …………………… 52

4.5.2  Fully Control AC to DC Converter Scheme …………………………….. 55

4.5.3  Matlab Implementation Of The Firing Signal Of Six Pulse Thyristor Base Ac To Dc Converter ………………………………………………………………..58

 

CHAPTER FIVE: The Closed Loop Current Fed Speed Controlled Induction Motor.

5.0 Introduction………………………………………………………………………………………… 61

5.1 Principle of Variable Frequency Drive of Constant Air Gap Flux and At Constant Torque……………………………………………………………………………………….. 61

5.2 Maximum and Minimum Torque……………………………………………. 65

5.3 Constant Flux Control Drive Scheme for a Squirrel Cage Induction Motor….73

5.4 Matlab- Simulink Implementation of the Drive Scheme……………..………. 75

5.5 Graph Result Analysis………………………………………………………………………….. 80

 

CHAPTER SIX: Conclusions and Recommendations

  • Conclusion ……………………………………………………………………82

6.1 Recommendations…………………………………………………………… 83

 

REFERENCES

6.0     References …………………………………………………………………..84

 

 

CHAPTER ONE

INTRODUCTION

1.0 Introduction:

This research work is concerned with the study of current source inverter (CSI) fed- induction motor drive with constant air gap flux control.

There are many electromechanical systems where it is important to control their torque, speed and position with high level of precision. These machines are used daily to increase human efficiency in our day to day activities, these include elevators in high rise buildings, mechanical robots in automated factories, which are crucial for industrial competitiveness. Others are used in general purpose applications of adjustable speed drives, such as pumps, compressor systems and advanced electric drives are also needed in wind electric systems to generate electricity and hybrid electric vehicles and trains which represent an important application of advanced electric drives in immediate future [1,2,3,4].

In the past, many applications requiring motion control utilized DC-motor drives. With the application of solid state industrial drive and the availability of fast signal processing capability, the role of DC- motor drive is being replaced by AC-motor drives [1, 5].

There are three major AC-drives that are widely used today. These are, induction motor drives, permanent magnetic motor drives and switch reluctance motor drives [1].

In this work, induction motor drive is adopted to achieve the constant air gap flux control, due to its ruggedness, low cost of purchase and its robustness.

1.1 Overview of the Study:

In the early drive scheme, AC drives are used for fixed speed operation, because it is not easy to obtain variable frequency supply. The efficiency of the drive was low when fixed frequency and variable voltage supply is used to control the speed of the motors. However, variable DC supply could be easily obtained. Consequently, DC drives are widely used for variable speed operation. Speed control is achievable in AC drives because variable frequency can be obtained using power electronic converter. DC drives were replaced with AC in variable speed applications which do not require high performance operations. AC drives uses AC motors hence require less maintenance e.g. squirrel cage Induction motors require minimum maintenance since no contact brushes are used. With the advancement of power semiconductor devices and powerful microprocessors, it is possible to control the AC motors that will give comparable performance to that of DC drives.AC drives utilizing control techniques such as field-oriented control (F.O.C) and Direct Torque Control (DTC) are now gradually replacing DC drives in high performance applications. [6]

Basically, there are two circuits used for power conversion in induction motor drive. These are the voltage source inverters (VSI) and current source inverters (CSI). For reasons such as its stability at no load and open loop control, voltage source inverter (VSI) were used more often than the current source inverter (CSI). Nowadays, the development of power electronics devices has enormous influence on applications of systems based on the CSI and creates new possibilities.

In the 1980s the current source inverters were the main commonly used electric machinefeeding devices [7]. Characteristic features of those drives were the motor electromagnetic torque pulsations, the voltage and current with large content of higher harmonics. The current source inverter was constructed of a thyristor bridge and large inductance and large commutation capacitors. Serious problems in such drive systems were unavoidable overvoltage cases during the thyristor commutation, as the current source inverter current is supplied in a cycle from a DC-link circuit to the machine phase winding. The thyristor CSI has been replaced by the transistor reverse blocking IGBT devices (RBIGBT), where the diode is series-connected and placed in one casing with transistor. The power transistors like RBIGBT or Silicon Carbide (SiC) used in the modern CSIs guarantee superior static and dynamic drive characteristics.

The electric drive development trends are focused on the high quality system. The use ofcurrent sources for the electric machine control ensures better drive properties than in case of voltage sources, where it may be necessary to use more passive filter at the inverter output. The Pulse width modulation (PWM) with properly chosen DC-link inductor and input-output capacitors result in sinusoidal inverter output currents and voltages.

One advantage of the drive is that regenerative braking is easy because the rectifier and inverter can reverse their operation modes. Six-step machine current, however, causes large harmonic heating and torque pulsation, which may be quite harmful at low-speed operation. Another disadvantage is that the converter system cannot be controlled in open loop like a voltage-fed inverter. [6]

 

 

1.2Objectives of the Study.

This drive scheme is aimed at achieving the following

  1. To develop a current source inverter scheme that will drive a squirrel cage induction motor and controlling the speed within a wide range of value below or equal to the motor rated speed value of 1440rpm at constant rated air gap flux with no additional output filters.
  2. To adopt a control mechanism that will minimize steady torque pulsation within the speed range chosen.
  • To design a drive that has a fast settling time and low percentage overshoot.

1.3   Thesis Organization.

Chapter 1 is a vivid introduction of the thesis, it also contains an overview to the study and the objective of the study.

Chapter 2 reviewed literatures on previous works done on induction motor drive- especially areas covered by the work.

Chapter 3 looked at the introduction of induction motor, discuss the fundamental equations of the dynamics and steady state analysis as well as the developed mechanical and torque analysis of the induction motor respectively.

Chapter 4 is an overview of current source inverter with the novel method of designing the firing signals of the switches and its MATLAB/ Simulink simulation. The performances of the designed current source inverter on some specified load was also discussed.

In chapter 5, the closed loop current fed speed controlled induction motor was analysed. A detail description of how the work was carried out and the result obtain was discussed

Finally, Chapter 6 offers a conclusion on the work and how the prototype was able to meet the objective, discussions and recommendations.

 

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