Search result: Catalogue data in Autumn Semester 2019
Energy Science and Technology Master | ||||||
Master Studies (Programme Regulations 2018) | ||||||
Core Courses At least two core courses must be passed in each area. All students must participate in the course offered in the area "Interdisciplinary Energy Management" | ||||||
Electrical Power Engineering | ||||||
Number | Title | Type | ECTS | Hours | Lecturers | |
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227-0122-00L | Introduction to Electric Power Transmission: System & Technology | W | 6 credits | 4G | C. Franck, G. Hug | |
Abstract | Introduction to theory and technology of electric power transmission systems. | |||||
Learning objective | At the end of this course, the student will be able to: describe the structure of electric power systems, name the most important components and describe what they are needed for, apply models for transformers and lines, explain the technology of overhead power lines, calculate stationary power flows, current and voltage transients and other basic parameters in simple power systems. | |||||
Content | Structure of electric power systems, transformer and power line models, analysis of and power flow calculation in basic systems, symmetrical and unsymmetrical three-phase systems, transient current and voltage processes, technology and principle of electric power systems. | |||||
Lecture notes | Lecture script in English, exercises and sample solutions. | |||||
227-1635-00L | Electric Circuits Students without a background in Electrical Engineering must take "Electric Circuits" before taking "Introduction to Electric Power Transmission: System & Technology" | W | 4 credits | 3G | M. Zima, D. Shchetinin | |
Abstract | Introduction to analysis methods and network theorems to describe operation of electric circuits. Theoretical foundations are essential for the analysis of the electric power transmission and distribution grids as well as many modern technological devices – consumer electronics, control systems, computers and communications. | |||||
Learning objective | At the end of this course, the student will be able to: understand variables in electric circuits, evaluate possible approaches and analyse simple electric circuits with RLC elements, apply circuit theorems to simple meshed circuits, analyze AC circuits in a steady state and understand the connection of the explained principles to the modelling of the 3-phase electric power systems. | |||||
Content | Course will introduce electric circuits variables, circuit elements (resistive, inductive, capacitive), resistive circuits and theorems (Kirchhoffs’ laws, Norton and Thevenin equivalents), nodal and mesh analysis, superposition principle; it will continue by discussing the complete response circuits (RLC), sinusoidal analysis – ac steady state (complex power, reactive, active power) and conclude with the introduction to 3-phase analysis; Mathematical foundations of the circuit analysis, such as matrix operations and complex numbers will be briefly reviewed. This course is targeting students who have no prior background in electrical engineering. | |||||
Lecture notes | lecture and exercises slides will be distributed after each lecture via moodle platform; additional materials to be accessed online (wileyplus) | |||||
Literature | Richard C. Dorf, James A. Svoboda Introduction to Electric Circuits, 9th Edition Online materials: https://www.wileyplus.com/ Lecture slides and exercises slides | |||||
Prerequisites / Notice | This course is intended for students outside of D-ITET. No prior course in electrical engineering is required |
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