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Syllabus for

Academic year
ENM060 - Power electronic converters  
 
Syllabus adopted 2015-02-11 by Head of Programme (or corresponding)
Owner: MPEPO
7,5 Credits
Grading: TH - Five, Four, Three, Not passed
Education cycle: Second-cycle
Major subject: Electrical Engineering
Department: 47 - ENERGY AND ENVIRONMENT

The current course round has limited places. Please contact the student center if you are not able to add the course to your selection.
Teaching language: English
Open for exchange students
Block schedule: A
Maximum participants: 96

Course module   Credit distribution   Examination dates
Sp1 Sp2 Sp3 Sp4 Summer course No Sp
0107 Examination 7,5 c Grading: TH   7,5 c   11 Jan 2016 pm SB   05 Apr 2016 pm M,  23 Aug 2016 pm M

In programs

MPEPO ELECTRIC POWER ENGINEERING, MSC PROGR, Year 1 (compulsory)
MPEES EMBEDDED ELECTRONIC SYSTEM DESIGN, MSC PROGR, Year 2 (elective)
MPSYS SYSTEMS, CONTROL AND MECHATRONICS, MSC PROGR, Year 1 (elective)
TIELL ELECTRICAL ENGINEERING - Electrical Engineering, Year 3 (compulsory)
TIELL ELECTRICAL ENGINEERING - Common branch of study, Year 3 (compulsory elective)

Examiner:

Tekniklektor  Stefan Lundberg
Professor  Torbjörn Thiringer


Replaces

EEK175   Power electronics-1


Eligibility:


In order to be eligible for a second cycle course the applicant needs to fulfil the general and specific entry requirements of the programme that owns the course. (If the second cycle course is owned by a first cycle programme, second cycle entry requirements apply.)
Exemption from the eligibility requirement: Applicants enrolled in a programme at Chalmers where the course is included in the study programme are exempted from fulfilling these requirements.

Course specific prerequisites

-

Aim

The aim of the course is to make the students familiar with the operating principles of the most common power electronic converter topologies. Basic converter design, analysis of wave-shapes and efficiency calculations are among the items that the students will be able to perform after having participated in the course. The students will perform both simulations using Cadence PSpice as well as experimental work on real DC/DC-converters. The course lays the foundation for the continuation course 'Power Electronic Devices and Applications'. The items treated in the course are also useful for engineering work in many different areas, e.g. design of power supplies, electric drive systems or power system applications.

Learning outcomes (after completion of the course the student should be able to)

  • Determine Fourier components and total harmonic distortion (THD) for basic current and voltage wave-shapes.
  • Recognize the operating principle of the most common active components (e.g. diode, thyristor, IGBT, and MOSFET) as well as the most common passive components (e.g. capacitors, transformers and inductors).
  • Explain and exemplify how pulse width modulation (PWM) works. Describe the purpose as well as the means to control the desired quantity and recognize the need for a controller circuit within the power electronic converter. 
  • Analyze and perform analytical calculations of ideal DC/DC converters such as the buck, boost, buck-boost, flyback and the forward converter. The operating principle of each topology is differentiated and thoroughly evaluated in both continuous and discontinuous conduction mode by its current and voltage wave-shapes. In addition to this, other topologies (e.g. the push-pull, half-bridge and full-bridge converter) and circuit enhancements (e.g. converter interleaving and active clamp demagnetization) are exemplified.
  • Describe the basic operating principle of both single-phase and three-phase AC/DC inverters. Different modulation strategies (e.g. PWM and square wave operation) are implemented and the resulting current and voltage waveforms are evaluated and compared.
  • Explain the operation of multilevel converters (e.g. 3-level and 5-level NPC and MMC topologies) by current and voltage waveform analysis and apply the benefits and drawbacks to e.g. harmonics and losses. 
  • Perform calculations on single- and three-phase diode rectifiers operating with voltage-stiff and current-stiff DC-side. Apply the concept of line impedance within the converter circuit (current commutation) and evaluate the influence.
  • Perform calculations on single- and three-phase thyristor rectifiers operating with a current stiff DC-side. Apply the concept of line impedance within the converter circuit (current commutation) and evaluate the influence. Analyze more advanced topologies (e.g. 6-pulse and 12-pulse connections) of the thyristor rectifier and distinguish the benefits and drawbacks. 
  • Identify simple power electronic converter diagrams and schematics. Recognize the different parts in a physical circuit on which basic wave-shape and efficiency measurements is performed.
  • Determine the losses in both passive and active components. The resulting temperature in the active component is evaluated and an appropriate heat-sink is chosen. Have a basic understanding of how the lifetime of a component can be determined.
  • Utilize the software Cadence PSpice to simulate basic power electronic circuits. The purpose of the laborations is to understand the operating principle of the circuit, analyze waveforms, evaluate parameter variations and perform harmonic/Fourier analysis.

Content

Lectures and tutorials:
  • Review: electric and mathematic prerequisites, voltage and current relations for passive components, mean and RMS-value, Fourier analysis.
  • Active and passive components: diodes, thyristors, MOSFETs, GTOs, IGBTs, inductors, transformers and capacitors.
  • DC/DC converters without isolation: buck, boost, buck-boost and the H-bridge converter.
  • DC/DC-converters with isolation: flyback, forward, half-bridge, push-pull and the full-bridge converter.
  • DC/AC-generation: single-phase and three-phase AC-generation, square-wave and PWM-modulated inverters, multilevel inverters. 
  • Diode rectifiers: single- and three-phase diode rectifiers with continuous and discontinuous DC-side current.
  • Thyristor converters: single- and three-phase rectifiers with varying DC-link voltage.
  • Heat distribution and life-time: Loss calculations, thermal calculations, cooling requirements and component life-time. 

Laboratory experiments (compulsory):

  • Buck converter
  • Flyback converter

PSpice assignments (compulsory):
  • Seven PSpice exercises dealing with the converters analyzed in the course.

Organisation

The course consists of approximately:
  • 18 lectures (2 x 45min)
  • 13 tutorials (2 x 45min)
  • 2 practical laborations (4h)
  • 7 PSpice computer assignments (2h)

Literature

Mohan, Undeland, Robbins.
Power Electronics Converters, Applications and Design.
Wiley 2003, 3rd ed.

Examination

Written examination with grades Fail, 3, 4 or 5.
Approved laborations and PSpice assignments.


Page manager Published: Thu 04 Feb 2021.