Subject description - B1M14ESP

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B1M14ESP Electric Machinery and Apparatus Extent of teaching:2+2l
Guarantors:  Roles:PZ,P Language of
teaching:
CS
Teachers:Mindl P., Voženílek P. Completion:Z,ZK
Responsible Department:13114 Credits:5 Semester:Z

Anotation:

The course is focused on contact and solid-state switching devices in LV networks. Basic topologies AC switches and stress of their components, systems with modern semiconductor devices and their protection circuits, testing electrical devices. The course also deals with the general theory of electrical machines. Magnetic field. Fundamentals of commutation. The transformer efficiency, voltage drop. Transients - switch to the network, a short circuit. Mathematical model of synchronous and asynchronous machines. A rotating magnetic field. Induction machine, starting and speed control. Influence of harmonic magnetic field. Single-phase induction motor. Work synchronous machine on a network. Torque, stability, overload capacity.

Course outlines:

1. Low voltage contacts switching apparatus properties and application ability.
2. Components of semiconductor switching devices.
3. Single- phase semiconductor switches with thyristors and GTO thyristors, control circuits.
4. Semiconductor switches with bipolar, MOS and IGBT transistors and its control circuits.
5. Three- phase semiconductor switches topology, components voltage and current dimensioning
6. Softstarters, semiconductor switches protecting circuits.
7. Electrical apparatus testing.
8. Principles of electromechanical energy conversion. Theorie of general electric machine, mathematical model
9. Magnetic field. Fundamentals of DC machine commutation. Armature reaction
10. Winding of AC rotating machines, rotating magnetic field
11. Starting and speed control of induction machine. Single-phase induction motor
12. Mathematical model of the synchronous and induction machine, d,q,0-transformation
13. Operation of the synchronous machine to the network, torque, stability, overload capacity
14. Transient phenomena of synchronous generator, cut-off

Exercises outline:

Lab- exercises can be united to two session blocks.
1. Organization of lab exercises, work safety in the lab, laboratory rules, first tasks preparation.
2. Relay breaking properties in LV DC circuit.
3. Fuses current limiting characteristics measurement.
4. Residual current circuit breaker breaking characteristics measurement.
5. Dynamic making and breaking characteristics of IGBT switch measurement.
6. Switching characteristics of single-phase zero crossing switch measurement.
7. A single-phase thyristor and triacs switch control circuit application.
8. Magnetic field in the air gap of DC machine. No-load characteristic
9. Three-transformer winding connection, vector angle
10. Determination of an induction motor parameters by the measurement
11. Induction motor loading, circle diagram
12. No load- and short circle measuring of a synchronous machine
13. Determination of a synchronous machine model parameters by the measurement
14. Assesment

Literature:

[1] CHIASSON, John Nelson. Modeling and high performance control of electric machines. Hoboken: Wiley, 2005. ISBN 0-471-68449-X.
[2] LEONHARD, Werner. Control of electrical drives. 3rd ed. Berlin: Springer, 2001. xviii, 460 s. ISBN 3-540-41820-2.

Requirements:

Active participation on laboratory measurement, document administration in due form, measure result processing, submit of test reports

Subject is included into these academic programs:

Program Branch Role Recommended semester
MPEEM1_2018 Electrical Drives PZ 2
MPEEM3_2018 Technological Systems PZ 2
MPEEM2_2018 Electrical Power Engineering PZ 2
MPEEM1_2016 Technological Systems P 1
MPEEM3_2016 Electrical Power Engineering P 1
MPEEM2_2016 Electrical Machines, Apparatus and Drives P 1


Page updated 24.6.2019 17:52:59, semester: Z,L/2020-1, L/2018-9, Z,L/2019-20, Send comments about the content to the Administrators of the Academic Programs Proposal and Realization: I. Halaška (K336), J. Novák (K336)