Graduate study programme

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Applied Power Electronics DAEbc2-04

ECTS 5 | P 45 | A 0 | L 15 | K 0 | ISVU 149795 177084 177871 | Academic year: 2019./2020.

Course groups

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Course lecturers

HEDERIĆ ŽELJKO, Lecturer
PELIN DENIS, Lecturer
BRANDIS ANDREJ, Associate

Goals

Teach students about the topology of power electronic converters (PECs) for connecting renewable energy sources to a power grid and/or loads as well as for vehicle drives. Present the modulation technique of switching with PEC components in terms of optimising the harmonic content of the loads current and/or voltage as well as the voltage harmonic content of a power grid or power supply system in typical applications. Introduce students to hybrid electric vehicles (HEVs). Teach students about the modelling technology for the purpose of carrying out the analysis and synthesis of work, power flows, integration and design of HEV drives. Teach students about modelling and analysing the operation of energy storage systems in electric vehicles.

Conditions for enrollment

Requirements met for enrolling in the study programme

Course description

Distribution of renewable energy sources and their special features when connecting to a power grid and/or loads. Topology of power electronic converters (PECs) for connecting wind turbines, photovoltaic modules (strings) and fuel cells to power grids and/or vehicles and vehicle systems. Modulation techniques for converter conversion PEC components in order to optimise the harmonic power content and/or load voltage as well as the harmonic content of the power supply or a power supply system in the vehicle. Hybrid power generation systems. Hybrid electric vehicles, drive modelling techniques for carrying out the analysis and synthesis of work, power flows, integration and design of drives. HEV subdivision and subsystems. Analysis of the operating mode of the vehicle with respect to a driving mode of the vehicle. Power flows and system losses. Define basic energy storage management systems - batteries, super capacitors and hybrid systems.

Student requirements

Defined by the Student evaluation criteria of the Faculty of Electrical Engineering, Computer Science and Information Technology Osijek and paragraph 1.9

Monitoring of students

Defined by the Student evaluation criteria of the Faculty of Electrical Engineering, Computer Science and Information Technology Osijek and paragraph 1.9

Obligatory literature

1. 1 B. Skalicki Električni strojevi i pogoni Zagreb FESB 2004

2. 2 I. Flegar Elektronički energetski pretvarači Kigen, Zagreb, 2010.

3. 3 Ambrožič, V, Zajec, P. Električni servo pogoni Graphis Zagreb, 2019.


Pretraži literaturu na:

Recommended additional literature

1. 1 S. Sumathi, L. Ashok Kumar, P. Surekha Solar PV and Wind Energy Conversion Systems Springer, 2015.

2. 2 R. Teodorescu, M. Liserre, P. Rodriguez Grid converters for photovoltaic and wind power systems John Willey & Sons Ltd, 2011.

3. 3 A. Emadi Handbook of Automotive Power Electronics and motor drives Taylor & Francis Group, LLC, 2005.

4. 4 M. Alaküla Hybrid Drive Systems for Vehicles Lund University

5. 5 Tallner Batteries or supercapacitors as energy storage in HEVs1 Lund University

Course assessment

Conducting university questionnaires on teachers (student-teacher relationship, transparency of assessment criteria, motivation for teaching, teaching clarity, etc.). Conducting Faculty surveys on courses (upon passing the exam, student self-assessment of the adopted learning outcomes and student workload in relation to the number of ECTS credits allocated to activities and courses as a whole).

Overview of course assesment

Learning outcomes
Upon successful completion of the course, students will be able to:

1. classify topologies of power electronic converters when connecting renewable energy systems with a grid and/or loads and for vehicle drives

2. classify modulation control techniques of power electronic converters (PEC) with respect to harmonic content of load current and load voltage

3. analyse the ways of connecting typical renewable energy sources with loads and/or sources

4. create HEV model simulation models, and perform critical analysis of simulation results

5. analyse energy storage systems in electric vehicles



Aktivnosti studenta: Vidi tablicu aktivnosti