Natural variable modeling and performance of interior permanent magnet motor with concentrated and distributed windings

 

Table Of Contents


Chapter ONE

INTRODUCTION

  • 1.1Introduction
  • 1.2Background of Study
  • 1.3Problem Statement
  • 1.4Objective of Study
  • 1.5Limitation of Study
  • 1.6Scope of Study
  • 1.7Significance of Study
  • 1.8Structure of the Research
  • 1.9Definition of Terms

Chapter TWO

LITERATURE REVIEW

  • 2.1Overview of Interior Permanent Magnet Motor
  • 2.2Historical Development of Interior Permanent Magnet Motor
  • 2.3Types of Windings in Electric Motors
  • 2.4Concentrated Windings in Interior Permanent Magnet Motors
  • 2.5Distributed Windings in Interior Permanent Magnet Motors
  • 2.6Performance Metrics in Electric Motors
  • 2.7Modeling Techniques for Interior Permanent Magnet Motors
  • 2.8Advantages and Disadvantages of Concentrated Windings
  • 2.9Advantages and Disadvantages of Distributed Windings
  • 2.10Comparative Analysis of Concentrated and Distributed Windings

Chapter THREE

RESEARCH METHODOLOGY

  • 3.1Research Methodology Overview
  • 3.2Selection of Interior Permanent Magnet Motor Models
  • 3.3Data Collection Methods
  • 3.4Performance Measurement Metrics
  • 3.5Modeling Software Utilization
  • 3.6Experimental Setup for Testing
  • 3.7Data Analysis Techniques
  • 3.8Validation Methods for Results

Chapter FOUR

DATA PRESENTATION AND ANALYSIS

  • 4.1Performance Analysis of Concentrated Windings
  • 4.2Efficiency Comparison of Concentrated and Distributed Windings
  • 4.3Torque Characteristics of Interior Permanent Magnet Motors
  • 4.4Heat Dissipation in Concentrated vs. Distributed Windings
  • 4.5Power Factor Analysis
  • 4.6Voltage Regulation in Different Winding Configurations
  • 4.7Noise and Vibration Analysis
  • 4.8Reliability and Maintenance Considerations

Chapter FIVE

SUMMARY, CONCLUSION AND RECOMMENDATIONS

  • 5.1Summary of Findings
  • 5.2Conclusion and Recommendations
  • 5.3Implications for Future Research
  • 5.4Practical Applications of Study Results
  • 5.5Contribution to the Field of Electric Motors

Project Abstract

<p> Interior Permanent Magnet (IPM) motor is widely used for many industrial applications and has relatively high torque ripple generated by reluctance torque. Since the configuration of the stator has great influence on reluctance torque, different stator configuration is necessary to improve the torque performance of IPM motor. Natural variable modeling and performance comparison of Interior Permanent Magnet Motor with Concentrated winding (CW), Short pitched and Full pitched distributed winding (DW) is presented in this project report. Three phase Interior Permanent Magnet Motor with identical rotor dimensions, air gap length, series turn number, stator outer radius, and axial length was studied with different stator winding configuration. Basic parameters and machine performance, such as inductances, copper losses, power density, efficiency at high and low speed, torque ripple, rotor speed with load torque, phase currents, electromagnetic torque, controllability and demagnetization tolerance are compared. As a means of supplementing analysis of the IPM motor, winding function theory (WFT) is used to analyze the motor. Winding function theory has enjoyed success with induction, synchronous, and erven switched reluctance machines in the past. It is shown that this method is capable of analyzing IPM motor with different stator configuration and the simulations were carried out by using Embedded MATLAB function. It was observed that, the concentrated winding IPM motor has a lower copper loss of 0.3 kw and 3.7 kw at low and high speed respectively and 133 Nm high peak torque developed, pull out power of 58 kw, torque ripple of 96 Nm, average torque of 142 Nm, demagnetization tolerance of 60%, amplitude of the fundamental winding is 26.45 and efficiency of 89. the short pitched distributed winding IPM motor has a lower copper loss of 0.35 kw and 3.6 kw at low and high speed respectively and 116 Nm high peak torque developed, pull out power of 57 kw, torque ripple of 71 Nm, average torque of 185 Nm, demagnetization tolerance of 78%, amplitude of the fundamental winding is 27.53 and efficiency of 87. As for full pitched distributed winding IPM motor has a lower copper loss of 0.35 kw and 3.6 kw at low and high speed respectively and 116 Nm high peak torque developed, pull out power of 56 kw, torque ripple of 71 Nm, average torque of 185 Nm, demagnetization tolerance of 78%, amplitude of the fundamental winding is 29.3 and efficiency of 88. <br></p>

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