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Analysis of Electrical Machines Lecture1: Sept. 17, 2009 Term Project

Analysis of Electrical Machines Lecture1: Sept. 17, 2009 Term Project. Term Projects. You are required to produce a term project You will be working with two of your class members Projects will culminate with a presentation and submission of a final report

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Analysis of Electrical Machines Lecture1: Sept. 17, 2009 Term Project

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  1. Analysis of Electrical Machines Lecture1: Sept. 17, 2009 Term Project

  2. Term Projects • You are required to produce a term project • You will be working with two of your class members • Projects will culminate with a presentation and submission of a final report • A set of suggested projects is included. You may select one of the suggested projects, or you may devise your own comparable project

  3. Projects • Chose three projects from the list in order of priority -> Form a group of three -> Send this information to senc@uwindsor.ca after 6 PM today • All groups must submit a well-organized proposal of two to three pages in length by October 1st to senc@uwindsor.ca • The proposal should clearly describe the methodology, including the topic to be covered, any investigation, development, and the expected results • Proposals will be reviewed and must be approved by the instructor

  4. List of Projects • 1 - Vibration in permanent magnet synchronous motor • Calculation of electromagnetic force • Fluctuations in electromagnetic force causes vibration and noise • Electromagnetic forces in axial and radial direction • Discuss methods to minimize vibration and noise in PMSM • 2 - Control of permanent magnet synchronous motor • Types of control • Calculation of torque and flux using PMSM mathematical model • Control implementation methods • Comparative study of the simulation results • 3 - Power capability and flux-weakening performance of permanent magnet synchronous motor • Study of electromagnetic torque, output power capability and flux weakening • Effect of flux weakening on PMSM performance • Influence of losses on the output power capability • Discuss flux weakening control methods in PMSM • 4 - Analysis of design aspects of permanent magnet synchronous motor • Overview of motor design aspects with respect to applications • Technologies for high torque density • Technologies for high efficiency • Motor performance

  5. List of Projects • 5 - Application of induction motor in hybrid/electric vehicles • Motor requisites • Design and control specifications • Methods for achieving energy efficient operation • Comparative study of induction motor with other motor technologies used in hybrid and electric vehicles • 6 - Control of induction motor • Types of control • Calculation of torque and flux using IM mathematical model • Control implementation methods • Comparative study of the simulation results • 7 - Causes and reduction techniques of electromagnetic noise in induction motors • Causes of noise in induction motors • Theoretical foundations for various causes of electromagnetic noise generation and calculation of noise • Reduction of electromagnetic noise through stator–rotor mechanical design, stator winding design, etc. • Practical reduction techniques for new or existing motors. • 8 - Analysis of design aspects of induction motor • Overview of motor design aspects with respect to applications • Technologies for high torque density • Technologies for high efficiency • Motor performance

  6. List of Projects • 9 - Torque ripple minimization of switched reluctance motor • Effect of torque ripple on SRM performance • Calculation of electromagnetic torque and torque ripple • Discuss control methods to minimize torque ripple in SRM • Discuss design modifications to minimize torque ripple in SRM • 10 - Control of switched-reluctance motor • Types of control • Calculation of torque and flux using SRM mathematical model • Control implementation methods • Comparative study of the simulation results • 11 - Equivalent circuit model of switched-reluctance motor • SRM construction and characteristics • Mathematical model development using electromagnetic and mechanical equations • Equivalent circuit development • Efficiency and performance analysis employing the mathematical model of SRM • 12 - Analysis of design aspects of switched-reluctance motor • Overview of motor design aspects with respect to applications • Technologies for high torque density • Technologies for high efficiency • Motor performance

  7. Final Presentation Guidelines • Plan to give a 20 minute over-head presentation, with an additional 5 mins for questions and discussion • Presentations should be self-contained, and should be clear and precise • Briefly introduce the topic including • any background information • model developed for analysis • describe the investigation or simulation that was conducted • describe/analyze the results of the investigation • individual contribution

  8. Suggested Presentation Guidelines • Title: Name the project and group members • Outline: Summarize the full presentation. • Introduction: Introduce the purpose and goals of the project. Provide any background material necessary to understand the presentation. • Model development for analysis. • Simulation/Investigation conducted. • Results: Present the results of the investigation. • Conclusion • Individual contribution • Questions and discussion.

  9. Report Guidelines • Each project will result in a detailed 20-30 page written technical report • In addition to this, computer programs or any other related information can be added in appendix sections of the report • The project report should be well organized and self-contained • Also, it should be written with the readers in mind. Any class member should be able to understand your report, and benefit from the results you obtain • Therefore, you should include adequate references and/or background materials and you should use tables, diagrams, graphs, figures, and portions of printouts to enhance readers' comprehension of your project

  10. Suggested Report Guidelines • Abstract. Gives succinct (to the point) information on the purpose, methods, results and conclusions reported • Introduction. Include background material and discuss the scope and limitations of your project • Main Body. Here model should be developed using the basic system equations for analysis. Be sure to fully describe any figures, tables or diagrams you include • Simulation results. This section should include simulation procedure, flowcharts, simulation conditions, system parameters, and finally the simulation results • Conclusions. • Recommendations, especially for future work and unsolved problems • References (must always be included) with almost no internet citation • Appendices, including supporting material as needed

  11. General Guidelines • IEEE PES format (single column) • Submit a copy of your report and presentation slides to senc@uwindsor.ca for grading. Some projects may be kept by the instructor for the OCGS and CEAB inspection • Grading of written reports and presentations will be based upon substantive content, appropriate organization and use of allotted presentation time, and effectiveness of the presentation and report • Take the time to properly cite material written by someone else -- include references

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