It is recommended that the student has specific knowledge about circuits theory, electrical machines, electrical installations, control, electronics and power electronics.
At the Order CIN/311/2009, 9th of February, the requirements for the verification of the official University degrees that set up the practice of the Industrial Engineer are stablished. It that Order, the minimum amount of credits are stablished equal to 30 European credits for the Industrial Technologies module and 15 for the Installations, facilities and complementary buildings. Among them, it is stablished to have proper knowledge about specific and technologic issues related to electrical engineering and energy engineering, infrastructures, etc. Electric Energy Systems subject is completely covering the competences included in that Order, such as knowledge and ability for the analysis and design of generation systems, transmission and distribution of electric energy, knowledge and abilities that allow the understanding, analysis, operation and management of different energy sources and partially covering others such as knowledge and abilities to design electrical installations and fluids, lighting, air conditioning systems, energy efficiency acoustics, communication networks, home automation, smart buildings and security installations.
Electric Energy Systems subject is providing the basic knowledge about the operation and control of the electric power systems as well as the basic concepts to design an electrical installation
Course competences | |
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Code | Description |
A01 | To have appropriate knowledge of the scientific and technological aspects of mathematical, analytical and numerical methods in engineering, electrical engineering, energy engineering, chemical engineering, mechanical engineering, continuous medium mechanics industrial electronics, automation, manufacturing, materials, quantitative management methods, industrial computing, town planning, infrastructures, etc. |
A02 | To plan, calculate and design products, processes, facilities and plants. |
A04 | To conduct research, development and innovation in products, processes and methods. |
B01 | Knowledge and capacity for the analysis and design of systems for generating, transporting and generating electricity. |
B06 | Knowledge and capacity to understand, analyse, exploit and manage different energy sources. |
CB06 | Knowledge and skills to organise and manage enterprises. |
CB07 | Strategy and planning knowledge and skills applied to different organisational structures. |
CB09 | Knowledge of financial and costs accounting. |
CB10 | Knowledge of information systems for management, industrial organisation, production, logistics and quality management systems. |
D04 | Knowledge and abilities to plan and design electrical and fluid installations, lighting, heating and ventilation, energy saving and efficiency, acoustics, communications, domotics, Smart buildings and security installations. |
Course learning outcomes | |
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Description | |
Acquire basic knowledge for designing an electrical installation: sizing, transformer centres, protection, conductors, etc. | |
Acquire basic knowledge for understanding and analysing the problem of tension and frequency control. | |
Acquire basic knowledge for modelling and determining optimal charge flows. | |
Understand the importance of studying the safety of electrical energy systems. | |
Understand the importance of state estimation in the operational safety of a system. | |
Additional outcomes | |
Not established. |
The following Lab Practice are expected to be conducted:
- Practice 1: Load flow I
- Practice 2: Load flow II
- Practice 3: shortcircuits and protections
Training Activity | Methodology | Related Competences (only degrees before RD 822/2021) | ECTS | Hours | As | Com | Description | |
Class Attendance (theory) [ON-SITE] | Lectures | A01 A02 A04 B01 B06 CB06 D04 | 1.08 | 27 | Y | N | ||
Class Attendance (practical) [ON-SITE] | Practical or hands-on activities | A01 A02 A04 B01 B06 CB06 D04 | 0.96 | 24 | Y | N | ||
Writing of reports or projects [OFF-SITE] | Practical or hands-on activities | A01 A02 A04 B06 CB06 CB07 CB09 CB10 D04 | 1.8 | 45 | Y | N | ||
Project or Topic Presentations [ON-SITE] | Assessment tests | A01 A02 A04 B01 B06 CB06 CB07 CB09 CB10 D04 | 0.24 | 6 | Y | N | ||
Progress test [ON-SITE] | Assessment tests | A01 A02 A04 B01 B06 CB06 CB07 CB09 CB10 D04 | 0.12 | 3 | Y | Y | ||
Study and Exam Preparation [OFF-SITE] | Self-study | A01 A02 A04 B01 B06 CB06 CB07 CB09 CB10 D04 | 1.8 | 45 | Y | N | ||
Total: | 6 | 150 | ||||||
Total credits of in-class work: 2.4 | Total class time hours: 60 | |||||||
Total credits of out of class work: 3.6 | Total hours of out of class work: 90 |
As: Assessable training activity Com: Training activity of compulsory overcoming (It will be essential to overcome both continuous and non-continuous assessment).
Evaluation System | Continuous assessment | Non-continuous evaluation * | Description |
Progress Tests | 35.00% | 40.00% | Evaluation of the Practice topics |
Practicum and practical activities reports assessment | 5.00% | 0.00% | Evaluation of the reports made by the student related to the Practice Lab |
Final test | 60.00% | 60.00% | A minimum mark of 4 out of 10 is required |
Total: | 100.00% | 100.00% |
Not related to the syllabus/contents | |
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Hours | hours |
Project or Topic Presentations [PRESENCIAL][Assessment tests] | 6 |
Progress test [PRESENCIAL][Assessment tests] | 3 |
Study and Exam Preparation [AUTÓNOMA][Self-study] | 45 |
Unit 1 (de 7): Introduction to Electric Energy Sistems | |
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Activities | Hours |
Class Attendance (theory) [PRESENCIAL][Lectures] | 3 |
Writing of reports or projects [AUTÓNOMA][Practical or hands-on activities] | 4 |
Unit 2 (de 7): Load flow, optimal load flow | |
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Activities | Hours |
Class Attendance (theory) [PRESENCIAL][Lectures] | 4 |
Class Attendance (practical) [PRESENCIAL][Practical or hands-on activities] | 4 |
Writing of reports or projects [AUTÓNOMA][Practical or hands-on activities] | 4 |
Unit 3 (de 7): Fequency and voltage control | |
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Activities | Hours |
Class Attendance (theory) [PRESENCIAL][Lectures] | 4 |
Class Attendance (practical) [PRESENCIAL][Practical or hands-on activities] | 6 |
Writing of reports or projects [AUTÓNOMA][Practical or hands-on activities] | 11 |
Unit 4 (de 7): Operation of the generation system | |
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Activities | Hours |
Class Attendance (theory) [PRESENCIAL][Lectures] | 4 |
Writing of reports or projects [AUTÓNOMA][Practical or hands-on activities] | 6 |
Unit 5 (de 7): Shortcircuit analysis and protection systems | |
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Activities | Hours |
Class Attendance (theory) [PRESENCIAL][Lectures] | 4 |
Class Attendance (practical) [PRESENCIAL][Practical or hands-on activities] | 6 |
Writing of reports or projects [AUTÓNOMA][Practical or hands-on activities] | 6 |
Unit 6 (de 7): Power system state estimation | |
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Activities | Hours |
Class Attendance (theory) [PRESENCIAL][Lectures] | 4 |
Class Attendance (practical) [PRESENCIAL][Practical or hands-on activities] | 8 |
Writing of reports or projects [AUTÓNOMA][Practical or hands-on activities] | 10 |
Unit 7 (de 7): Electrical installations | |
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Activities | Hours |
Class Attendance (theory) [PRESENCIAL][Lectures] | 4 |
Writing of reports or projects [AUTÓNOMA][Practical or hands-on activities] | 4 |
Global activity | |
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Activities | hours |
Author(s) | Title | Book/Journal | Citv | Publishing house | ISBN | Year | Description | Link | Catálogo biblioteca |
---|---|---|---|---|---|---|---|---|---|
A. Molina-García and A.D. Hansen and E. Muljadi and V. Gevorgian and J. Fortmann and E. Gómez-Lázaro | Large Scale Grid Integration of Renewable Energy Sources | The Institution of Engineering and Technology | 978-1-78561-162-9 | 2017 | http://dx.doi.org/10.1049/PBPO0980 | ||||
A. Orths, H. Abildgaard, F. van Hulle, J. Kiviluoma, B. Lange, M. O¿Malley, D. Flynn, A. Keane, J. Dillon, E. M. Carlini, J. O. Tande, A. Estanqueiro, E. Gómez-Lázaro, L. Söder, M. Milligan, J. C. Smith, y C. Clark. | WIND INTEGRATION STUDIES | Finland | 2013 | http://www.ieawind.org/task_25.html | |||||
Andrzej M. Trzynadlowski (Editor), Eduard Muljadi, Emilio Gomez-Lazaro, Antonio Ginart | Power Electronic Converters and Systems: Frontiers and Applications | The Institution of Engineering and Technology | 978-1849198264 | 2015 | https://iet.presswarehouse.com/books/BookDetail.aspx?productID=405109 | ||||
Antonio Gomez-Expósito, Claudio Cañizares, Antonio J. Conejo | Electric Energy Systems - Analysis and Operation | EEUU | CRC | 9780849373657 | 2009 | ||||
Antonio Gómez Expósito y otros | Análisis y operación de sistemas de energía eléctrica | Mc Graw Hill Interamericana S.L | 978-8448135928 | 2002 | |||||
E. Muljadi and E. Gómez-Lázaro and A. Ginart | Power Electronic Converters and Systems: Frontiers and Applications | The Institution of Engineering and Technology | 978-1-84919-826-4 | 2015 | http://dx.doi.org/10.1049/PBPO074E | ||||
E. Muljadi and E. Gómez-Lázaro and A. Ginart | Power Electronic Converters and Systems: Frontiers and Applications | The Institution of Engineering and Technology | 978-1-84919-826-4 | 2015 | http://dx.doi.org/10.1049/PBPO074E | ||||
Emilio Gómez Lázaro | Material desarrollado para la asignatura | ||||||||
H. Holttinen, J. Kiviluoma, A. Robitaille, N. A. Cutululis, A. Orths, F. Van Hulle, I. Pineda, B. Lange, M. O¿Malley, J. Dillon, E. M. Carlini, C. Vergine, J. Kondoh, Y. Yasuda, M. Gibescu, J. Olav Tande, A. Estanqueiro, E. Gómez-Lázaro, L. Söder, J. C. Smith, M. Milligan, y D. Lew. | Design and operation of power systems with large amounts of wind power | Helsinki, Finland | Julkaisija-Utgivare | 978-951-38-7308-0 | 2013 | http://www.ieawind.org/task_25.html | |||
J. Duncan Glover, Mulukutla S. Sarma, Thomas Overbye | Power System Analysis and Design | Cengage Learning | 9781111425791 | 2011 | |||||
J. M. Adell, J. Canales, M. Gálvez, A. Frossard, J. L. Garda, E. Gómez-Lázaro, N. Goodall, E. Méndez, J. L. Plá, A. Pototschnig, J. C. Ruiz, A. Salem, R. Schaeffer, y J. Verde | Energía: Desarrollos tecnológicos en la protección medioambiental | Thomson Reuters | 978-84-470-3806-0 | 2011 | |||||
J. Roger Folch, M. Riera Guasp, C. Roldán Porta | Tecnología Eléctrica | Síntesis | 8477387672 | 2000 | |||||
Jaquelin Cochran, Mackay Miller, Michael Milligan, Erik Ela, Douglas Arent, Aaron Bloom, Matthew Futch, Juha Kiviluoma, Hannele Holtinnen, Antje Orths, Emilio Gómez-Lázaro, Sergio Martín-Martínez, Steven Kukoda, Glycon Garcia, Kim Møller Mikkelsen, Zhao Yongqiang, y Kaare Sandholt. | Market Evolution: Wholesale Electricity Market Design for 21st Century Power Systems | 21stCenturyPower.org | NREL/TP-6A20-57477 | 2013 | http://www.nrel.gov/docs/fy14osti/57477.pdf | ||||
John J. Grainger, William D. Stevenson | Análisis de sistemas de potencia | MacGraw-Hill | 9789701009086 | 1999 | |||||
S. Martin-Martínez, A. Vigueras-Rodríguez, E. Gómez-Lázaro, A. Molina-García, E. Muljadi, y M. Milligan | Advances in wind power | Rijeka, Croatia | Intech | 978-953-51-0863-4 | 2012 | http://www.intechopen.com/books/advances-in-wind-power |