Aims |
Contribution of the course to the program objectives
Axis 1 (1.1, 1.2, 1.3), Axis 3 (3.3), Axis 5 (5.4)
Specific learning outcomes of the course
At the end of the course, students will be able to:
- Link the fundamental concepts (Faraday's law, energy and magnetic co-energy, ...) to the general equations of an electromechanical converter;
- Build the steady state model (equations and equivalent circuit) of a rotating field machine, an asynchronous machine (three or single-phase), a synchronous machine and a DC machine;
- Build the steady state model (equations and equivalent circuit) of the transformer (single or three phase);
- Experimentally determine the parameters of these models
- Use these models to predict operating conditions of these devices depending on the supply and the load.
In addition, the student will be able to:
- Determine and interpret the characteristic quantities of an electromechanical converter or transformer;
- Identify the main electromechanical converters structures;
- Establish the conditions guaranteeing the energy conversion in an electromechanical converter;
- Explain the principle of the universal motor;
- Explain the ways to increase the starting torque, to reduce the starting current or to vary the speed of an electromechanical converter;
- Explain how to connect and control an alternator on the grid.
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Content |
- Introduction, reminder of the basics of electrical circuits (1h)
- The single-phase transformers (4h): structure, fundamental laws, models of the ideal transformer, of the perfect transformer and of the real transformer, on load operation, experimental parameter identification
- Three-phase transformers (1 hour): structure, connection modes, single-phase equivalent circuit
- The general theory of electromechanical converters (2 hours): classification, structure, basic assumptions, electrical and mechanical equations, magnetic energy and co-energy, electromagnetic torque
- Rotating field machines (4h): general design features, equations, supply, equivalent circuit, saturation, synchronous and asynchronous operating modes, main structures of rotating field machines
- The three-phase asynchronous machine (5h): specific design features, equations, equivalent circuit, phasor diagram (the circle diagram), torque-speed characteristic, operating point, saturation, iron losses, power and efficiency, practical problems (current-starting torque vs efficiency, speed control), specific applications (phase shifter and induction regulator, electrical axis - Selsyn, synchronoscope, Leblanc damper)
- The single-phase induction motor (1 hour): structure, principle and equations
- The synchronous machine (4h): specific design features, equations, equivalent circuits, phasor diagram, operating point (stability), active and reactive power control, connection and control of an alternator on the grid
- The DC machine (2h): specific design features, structure, equations, operating and excitation modes, starting, universal motor
- Introduction, reminder of the basics of electrical circuits (1h)
- The single-phase transformers (4h): structure, fundamental laws, models of the ideal transformer, of the perfect transformer and of the real transformer, on load operation, experimental parameter identification
- Three-phase transformers (1 hour): structure, connection modes, single-phase equivalent circuit
- The general theory of electromechanical converters (2 hours): classification, structure, basic assumptions, electrical and mechanical equations, magnetic energy and co-energy, electromagnetic torque
- Rotating field machines (4h): general design features, equations, supply, equivalent circuit, saturation, synchronous and asynchronous operating modes, main structures of rotating field machines
- The three-phase asynchronous machine (5h): specific design features, equations, equivalent circuit, phasor diagram (the circle diagram), torque-speed characteristic, operating point, saturation, iron losses, power and efficiency, practical problems (current-starting torque vs efficiency, speed control), specific applications (phase shifter and induction regulator, electrical axis - Selsyn, synchronoscope, Leblanc damper)
- The single-phase induction motor (1 hour): structure, principle and equations
- The synchronous machine (4h): specific design features, equations, equivalent circuits, phasor diagram, operating point (stability), active and reactive power control, connection and control of an alternator on the grid
- The DC machine (2h): specific design features, structure, equations, operating and excitation modes, starting, universal motor
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