Course Websites
ECE 431 - Electric Machinery
Last offered Spring 2024
Official Description
Related Faculty
Subject Area
- Power and Energy Systems
Course Director
Description
Goals
Present theory and laboratory experimentation of basic rotating machines and transformers.
Topics
- Power measurement, three-phase power
- Power factor control
- Single-phase transformer tests and theory
- Saturation and harmonic effects in three-phase transformers
- Induction motor testing and theory
- Induction motor performance
- dc machine testing and theory
- dc machine performance
- Synchronous machine testing and theory
- Synchronous machine performance
- Digital simulation of machine dynamics
- Energy control projects
Detailed Description and Outline
Present theory and laboratory experimentation of basic rotating machines and transformers.
Topics:
- Power measurement, three-phase power
- Power factor control
- Single-phase transformer tests and theory
- Saturation and harmonic effects in three-phase transformers
- Induction motor testing and theory
- Induction motor performance
- dc machine testing and theory
- dc machine performance
- Synchronous machine testing and theory
- Synchronous machine performance
- Digital simulation of machine dynamics
- Energy control projects
Computer Usage
Multiple experiments and homework in simulation of electric machines.
Reports
Weekly lab reports are required.
Lab Projects
See above topics. Class also includes a special project related to machines and power systems. Project includes a trip to industry and oral presentation to class.
Topical Prerequisites
- Electromechanics
- dc and ac circuits
Texts
A. E. Fitzgerald, C. Kingsley, and S. D. Umans, Electric Machinery, 6th ed., New York: McGraw-Hill, 2003
ABET Category
Engineering Science: 2 credits
Engineering Design: 2 credits
Course Goals
This course is a senior or beginning-graduate level elective for electrical and computer engineering majors. The goals are to impart an understanding of electromechanics from theoretical and experimental bases. The successful student will be able to explain how a given electromechanical devices works, and justify the explanation mathematically. Further, the student should be able to conceive a device that is capable of meeting performance criteria, though detailed design is not part of the course. The student should also be able to understand and articulate a broad range of application areas, including emerging areas.
Instructional Objectives
A. After the first three weeks, the students should be able to:
- Describe the impact of electric machines on modern society, including the breadth of their application and the extent of use. (3,4)
- Inspect an electromechanical system (magnetic or electrostatic) and determine a mathematical model of the electrical system that can be used to calculate current, voltage, flux, or charge, as appropriate to the system. (1)
- Plan and perform laboratory measurements on 3-phase power circuits and transformers. (6)
- Explain, understand, and follow the safety precautions for performing experiments in an electric machinery lab. (4,7)
B. After the first five weeks, the student should be able to:
- Derive the force functions for a given electromechanical device and apply the function to a complete mechanical system. (1)
- Have a demonstrated understanding of devices that work on principle of changing inductance or capacitance (reluctance devices). (1)
- Make measurements and predictions of the performance of stepper motors. (1,6)
C. After the first eight weeks, the student should be able to
- Explain suitable application contexts for stepper motors, reluctance machines, and induction machines (1)
- Develop electrical models for electromechanical devices that work on the principle of induction (charge or current induction). (1)
- Use the steady-state versions of the electrical models to predict performance of induction machines. (1)
- Make measurements on induction motors to determine steady-state model parameters. (6)
- Use measured induction motor parameters to predict performance and verify the prediction in the lab. (1,6)
D. After the first eleven weeks, the student should be able to
- Develop electrical models for machines that have both reluctance and induction properties, and may include permanent magnets (synchronous machines). (1)
- Build a dynamic computer simulation of a synchronous machine. (1,6,7)
- Make laboratory measurements on synchronous machines to determine steady-state characteristics involving voltage, power, current, power factor, and torque. (6)
E. After the first thirteen weeks, the student should be able to
- Lay out simple control loops for torque, speed, and position control based on constant volts per hertz operation. (1)
- Program an electric drive, through a high-level interface, in a lab setting to track a given torque or speed command. (6)
- Build a dynamic computer simulation of typical electric machines, including models of mechanical loads and interactions within a complete system. (1,7)
F. After the full 15 weeks, the student should be able to
Title | Section | CRN | Type | Hours | Times | Days | Location | Instructor |
---|---|---|---|---|---|---|---|---|
Electric Machinery | ABA | 33876 | LAB | 0 | 0930 - 1220 | R | 4024 Electrical & Computer Eng Bldg | Michael Stoens Parag Bajaj |
Electric Machinery | ABB | 33878 | LAB | 0 | 1200 - 1450 | W | 4024 Electrical & Computer Eng Bldg | Brian Andrew Wolhaupter Michael Stoens |
Electric Machinery | ABC | 33879 | LAB | 0 | 1400 - 1650 | R | 4024 Electrical & Computer Eng Bldg | Brian Andrew Wolhaupter Parag Bajaj |
Electric Machinery | ABD | 51021 | LAB | 0 | 1500 - 1750 | W | 4024 Electrical & Computer Eng Bldg | Brian Andrew Wolhaupter |
Electric Machinery | AL1 | 33880 | LEC | 4 | 0900 - 0950 | M W F | 3081 Electrical & Computer Eng Bldg | Kiruba Sivasubramaniam Haran |