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Course Catalog 2013-2014
DEE-23106 Fundamentals of Electrical and Power Engineering, 5 cr |
Person responsible
Enrique Acha, Teuvo Suntio
Lessons
| Study type | P1 | P2 | P3 | P4 | Summer | Implementations | Lecture times and places |
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Requirements
To attend the course and to pass the one final exam
Learning Outcomes
Students having taken the course are expected to have gained a solid understandíng of the electric circuit theory, concepts and methods that are essential to understand the information given in the reminder of the MSc course. They should be able to: (i) calculate and analyse the steady-state and dynamic behaviour of simple electrical circuits; (ii) understand the three-phase nature of practical electrical power networks and the analytical tools that are available to power engineers to bring them down to manageable levels suitable for analysis; (iii) determine the impedance parameters of electrical power equipment
Content
| Content | Core content | Complementary knowledge | Specialist knowledge |
| 1. | Week 1: Introduction to course content, goals and working principles Review of basic concepts and laws in electrical circuit theory, e.g., the current and voltage relationship in the various electric circuit components Review of Kirchhoff's laws and their application to solve electrical circuit problems Review of Thevenin's and Norton's methods to solve electrical circuit problems Phasor notation Frequency and time domain analyses | ||
| 2. | Week 2: Introduction to Laplace transform and its application to solve the time-domain behaviour of Electrical circuits Introduction to the properties of first-and second-order systems | ||
| 3. | Week 3: Introduction to system dynamics including stability and frequency-domain behaviour of electrical systems Introduction to resonant circuits | ||
| 4. | Week 4: Electrical power (mean, active, reactiva,apparent, distortion and three-phase) The power triangle, power measurements and power factor The electrical power network (layout and description of the main components, voltage levels, per-unit notation) | ||
| 5. | Week 5: Nodal Analysis ( Ybus and partial inversion leading to to Zbus) Generalised theory of Thevenin and Norton equivalents | ||
| 6. | Week 6: Symmetrical components and related transformations (Fortescue, Clark, park) Application of Fortescue components to star and delta-connected circuits | ||
| 7. | Week 7: Parameter calculation of electrical equipment and their modelling: power transmission lines and cables; power transformers; three-phase synchronous machines; three-phase induction machines and other power systems loads |
Instructions for students on how to achieve the learning outcomes
Exam (100%)
Assessment scale:
Numerical evaluation scale (1-5) will be used on the course
Study material
| Type | Name | Author | ISBN | URL | Edition, availability, ... | Examination material | Language |
| Book | Analysis of Faulted Power Systems | P.M. Anderson | 0780311450 | IEEE Press power system series, revised and reprint 2005, $124.92; applicable chapters: 1,2,4,5,6,7,11 | Yes | English | |
| Book | Electric Circuits | J. W. Nilsson & S. Riedel | Seventh or newer edition; Applicable topics from chapters 2-4,7,8,9,14,15,16,17 | Yes | English | ||
| Lecture slides | Enrique Acha | Yes | English | ||||
| Lecture slides | Teuvo Suntio | Yes | English |
Prerequisite relations (Requires logging in to POP)
Correspondence of content
| Course | Corresponds course | Description |
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More precise information per implementation
| Implementation | Description | Methods of instruction | Implementation |
| The course provides the recap of basic circuit and power engineering theories needed to successfully study the courses in Smart Grid MSc Programme. |