Checking date: 07/09/2022

Course: 2022/2023

Electrical power engineering fundamentals
(14020)
Study: Bachelor in Industrial Electronics and Automation Engineering (223)

Coordinating teacher: ROBLES MUÑOZ, GUILLERMO

Department assigned to the subject: Electrical Engineering Department

Type: Compulsory
ECTS Credits: 6.0 ECTS

Course:
Semester:

Requirements (Subjects that are assumed to be known)
All first-year subjects. Among them, Calculus I, Calculus II and Physics II are of utmost importance.
Objectives
By the end of this content area, students will be able to have: 1. A systematic understanding of the key aspects and concepts of electrical engineering; 2. Awareness of the wider multidisciplinary context of engineering. 3. The ability to apply their knowledge and understanding to identify, formulate and solve electrical engineering problems using established methods; 4. The ability to design and conduct appropriate experiments, interpret the data and draw conclusions; 5. Workshop and laboratory skills. 6. The ability to combine theory and practice to solve electrical engineering problems.
Skills and learning outcomes
Description of contents: programme
1. Introduction 1.1. General concepts 1.2. Kirchhoff's laws 2. Direct current circuits 2.1. Resistances and dependent and independent generators 2.2. Associations in series and parallel 2.3. Methods of meshes and nodes 2.4. Thévenin theorem 3. Altern current circuits 3.1. Inductances (coils) and capacitors 3.2. Waves and phasors 3.3. Impedance. 3.4. Circuits rseolutions in frequency domain 3.5. Power in AC circuits 4. Three-phase systems 4.1. General concepts 4.2. Line-to-neutral and line-to-line magnitudes 4.3. Single phase equivalent 4.4. Three phase power and reactive power compensation 5. First-order transient circuits 5.1 RC transient circuits 5.2 RL transient circuits
Learning activities and methodology
Basic theoretical concepts that students need learning to understand the subject will be explained in online master classes. Within the master class will be solved simple exercises that will help settling theory explained in each session. To make optimum use of the master class, it woulll be advisable to know which topics will be presented consulting on schedule. Likewise, the students should have worked on those topics before classes. Small classes in which the nearest student learning track will be done. These sessions will assess the skills acquired during the previous lectures and weekly work of students. Work, exercises and small daily examinations may be proposed. Along the course, three tests will be done on the days fixed in the schedule. There will be three practice sessions of laboratory in which the implementation of theoretical concepts will be worked. There are few specific times for tutorials and consultations of students. At the discretion of the teacher, tutoring outside that time period may be fixed if a student requests it.
Assessment System
• % end-of-term-examination 55
• % of continuous assessment (assigments, laboratory, practicals...) 45
Calendar of Continuous assessment
Basic Bibliography
• Bruce M. Carlsson. Teoría de Circuitos. Paraninfo. 2000
• Guillermo Robles . Problemas resueltos de fundamentos de ingeniería eléctrica. PARANINFO. 2015
• Jesús Fraile Mora. Electromagnetismo y Circuito Eléctricos. Mc. Graw Hill. 1995
• Julio Usaola, Mª Ángeles Moreno. Circuitos eléctricos: Problemas y ejercicios resueltos. Pearson Educación. 2002
Additional Bibliography
• Antonio Conejo Navarro. Circuitos eléctricos para la Ingeniería. McGraw-Hill. 2004
• Antonio Gómez Expósito. Teoría de Circuitos. Ejercicios de autoevaluación. Thomson. 2005
• J. Fernández Moreno. Teoría de Circuitos. Teoría y problemas resueltos. Paraninfo. 2011

The course syllabus may change due academic events or other reasons.