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Lecturer(s)
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Čekalová Jaroslava, Ing. Ph.D.
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Soukup Petr, Ing. Ph.D.
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Course content
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1. Basic types, principles and properties of RES, their cooperation with the power grid 2. Water energy utilization for energy purposes, basic types and components of hydropower plants 3. Basic principles of the water motors, history, development and use of their individual types 4. Wind energy utilization for energy purposes, wind turbine types and principles, wind turbine design 5. Utilization of solar energy for energy purposes, photovoltaic systems, possibilities for increasing their efficiency 6. Low-temperature and high-temperature solar systems, utilization of biomass energy and geothermal energy for energy purposes 7. Possibilities and types of energy storage systems - their technology and integration to electric power grid 8. Flexibility and frequency and voltage stability of power grid, effect of decentralized resources on operation and management of power grid 9. Static characteristics of decentralized energy sources, flexibility and reliability of RES 10. Legislative conditions for the connection of decentralized sources and storage facilities in terms of the power grid regulation and management, the principle of operation regulation and management of photovoltaic and wind power systems involved in power grid regulation 11. Using virtual methods for control of the decentralized resources 12. Management of Smart Grids and Microgrids with RES - their island operation and parallel connection and cooperation with the power grid 13. Principle of regulation of several co-operating photovoltaic power systems and their co-operation with synchronous generators to regulate the part of power grid
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Learning activities and teaching methods
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Lecture supplemented with a discussion, Multimedia supported teaching, Practicum
- Contact hours
- 52 hours per semester
- Preparation for an examination (30-60)
- 40 hours per semester
- Preparation for laboratory testing; outcome analysis (1-8)
- 8 hours per semester
- Presentation preparation (report) (1-10)
- 10 hours per semester
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| prerequisite |
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| Knowledge |
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| to define basic electrical energy concepts and laws |
| to explain the basic physical principles of electrical energy production and basic thermodynamic quantities, events, laws and cycles |
| to describe concept of electrical power system, its parts and relation between them |
| explain the hierarchy of power system control and to characterize the operation of the transmission and distribution system in the Czech Republic |
| Skills |
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| to use high school and university math and physic on given topic |
| to apply the basics of MATLAB Simulink software |
| Competences |
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| N/A |
| N/A |
| N/A |
| learning outcomes |
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| Knowledge |
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| to describe basic types, principles and properties of RES and their cooperation with the power grid |
| to explain the physical principles of water, wind and photovoltaic power plants and solar systems |
| to define use of biomass energy and geothermal energy for energy purposes |
| to list the properties and types of storage devices and to evaluate the possibility of their use in the regulation of RES |
| to describe the impact of decentralized energy sources on electric system operations and management |
| to explain the frequency and voltage stability of power grid and the static characteristics of decentralized sources |
| to clarify the legislative conditions for the connection of decentralized sources and storage devices in terms of grid power regulation and management |
| to define the principle of regulation of decentralized resources, Smart Grids and microgrids using virtual methods |
| Skills |
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| to make the simplified designs of the hydro-energetic, eolian and solar energy equipments |
| to evaluate the regulation of RES in microgrids and Smart Grids based on simulations in the software |
| to design a model of RES regulation in small island microgrid |
| to justify the microgrid design and the results from the simulations and measurements of the microgrid operation |
| Competences |
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| N/A |
| teaching methods |
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| Knowledge |
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| Lecture with visual aids |
| Lecture supplemented with a discussion |
| Practicum |
| Task-based study method |
| Self-study of literature |
| One-to-One tutorial |
| Skills |
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| Lecture with visual aids |
| Interactive lecture |
| Practicum |
| Laboratory work |
| Task-based study method |
| Individual study |
| Skills demonstration |
| One-to-One tutorial |
| Competences |
|---|
| Lecture supplemented with a discussion |
| Practicum |
| Task-based study method |
| Individual study |
| assessment methods |
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| Knowledge |
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| Combined exam |
| Individual presentation at a seminar |
| Continuous assessment |
| Skills |
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| Skills demonstration during practicum |
| Individual presentation at a seminar |
| Competences |
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| Combined exam |
| Individual presentation at a seminar |
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Recommended literature
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Beranovský J., Murtinger K., Tomeš M. Fotovoltaika. 2009. ISBN 978-8-08733301-3.
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C. Nelson, Vaughn ; Starcher, Kenneth L. Introduction to Renewable Energy. CRC Press, 2015. ISBN 9781498701938.
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Cihelka, Jaromír. Solární tepelná technika. 1. vyd. Praha : Tomáš Malina, 1994. ISBN 80-900759-5-9.
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Ekanayake, J. B. Smart grid : technology and applications. Chichester : John Wiley & Sons, 2012. ISBN 978-0-470-97409-4.
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Hallenga, Uwe. Malá větrná elektrárna : návod ke stavbě. 1. vyd. Ostrava : HEL, 1998. ISBN 80-86167-00-3.
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Haselhuhn, Ralf. Fotovoltaika : budovy jako zdroj proudu. 1. české vyd. Ostrava : HEL, 2011. ISBN 978-80-86167-33-6.
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Henze, Andreas; Hillebrand, Werner. Elektrický proud ze slunce : fotovoltaika v praxi : technika, přehled trhu, návody ke stavbě. 1. vyd. Ostrava : HEL, 2000. ISBN 80-86167-12-7.
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Holata, Miroslav; Gabriel, Pavel. Malé vodní elektrárny : projektování a provoz. Vyd. 1. Praha : Academia, 2002. ISBN 80-200-0828-4.
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Ilić, Marija D.,; Chakrabortty, Aranya. Control and optimization methods for electric smart grids. New York : Springer, 2012. ISBN 978-1-4614-1604-3.
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Iniewski, Krzysztof. Smart grid infrastructure & networking. New York : McGraw-Hill, 2013. ISBN 978-0-07-178774-1.
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Krieg, Bernhard. Elektřina ze Slunce : Fotovoltaika v teorii a praxi. 1. čes. vyd. Ostrava : HEL, 1993.
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Kutscher, Charles F.; Milford, Jana B.; Kreith, Frank. Principles of Sustainable Energy Systems, Third Edition. CRC Press, 2018. ISBN 9781498788922.
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Libra, Martin; Poulek, Vladislav. Fotovoltaika : teorie i praxe využití solární energie. 1. vyd. Praha : ILSA, 2009. ISBN 978-80-904311-0-2.
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Mastný, Petr; Drápela, Jiří; Mišák, Stanislav; Macháček, Jan; Ptáček, Michal; Radil, Lukáš; Bartošík, Tomáš; Pavelka, Tomáš. Obnovitelné zdroje elektrické energie. Praha, 2011. ISBN 978-80-01-04937-2.
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Rychetník, Václav; Pavelka, Jiří; Janoušek, Josef. Větrné motory a elektrárny. 1. vyd. Praha : ČVUT, 1997. ISBN 80-01-01563-7.
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S. Chowdhury, S.P. Chowdhury and P. Crossley. Microgrids and Active Distribution Networks. The Institution of Engineering and Technology, London, United Kingdom, 2009. ISBN 978-1-84919-014-5.
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Sioshansi, Fereidoon P. Smart grid : integrating renewable, distributed & efficient energy. Amsterdam : Elsevier/Academic Press, 2012. ISBN 978-0-12-386452-9.
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