MSE Master of Science in Engineering

The Swiss engineering master's degree

Jedes Modul umfasst 3 ECTS. Sie wählen insgesamt 10 Module/30 ECTS in den folgenden Modulkategorien:

12-15 ECTS in Technisch-wissenschaftlichen Modulen (TSM)
TSM-Module vermitteln Ihnen profilspezifische Fachkompetenz und ergänzen die dezentralen Vertiefungsmodule.
9-12 ECTS in Erweiterten theoretischen Grundlagen (FTP)
FTP-Module behandeln theoretische Grundlagen wie die höhere Mathematik, Physik, Informationstheorie, Chemie usw. Sie erweitern Ihre abstrakte, wissenschaftliche Tiefe und tragen dazu bei, den für die Innovation wichtigen Bogen zwischen Abstraktion und Anwendung spannen zu können.
6-9 ECTS in Kontextmodulen (CM)
CM-Module vermitteln Ihnen Zusatzkompetenzen aus Bereichen wie Technologiemanagement, Betriebswirtschaft, Kommunikation, Projektmanagement, Patentrecht, Vertragsrecht usw.

In der Modulbeschreibung (siehe: Herunterladen der vollständigen Modulbeschreibung) finden Sie die kompletten Sprachangaben je Modul, unterteilt in die folgenden Kategorien:

Unterricht
Dokumentation
Prüfung

Power Grids: Systems and Devices (TSM_PowGrid)

In this

module, students will increase their knowledge in selected areas of power grids

in electricity distribution and transmission:

High voltage engineering and relevant design rules

Breakdown theory

High voltage testing equipment

Design, construction and parameters of components in power grids

Learn the origin of networks failures, consequences, preventing and recovery measures

Operation principles and challenges of power grids

Special actual challenges and trends in transmission and distribution systems

Eintrittskompetenzen

Basics of electrical laws, circuitries, three-phase

systems, components in power grids, energy conversion, electric

charge, electric field theory.

Lernziele

Students

know the main challenges of today's modern grids
know the main elements of an electrical grid and the differences of transmission components
possess a fundamental knowledge of the principles of designing high voltage equipment.
Know the basic design and technical solutions of the most important high voltage equipment in a power grid
have become acquainted with the static/dynamic modelling and simulation of high voltage components.
know the design criteria of power grids and can perform basic grid calculations
know the behavior of meshed grids in normal operation
understand the basics of power system stability
can describe the advantages of smart-grid applications
learn the basic principles of the management and regulation of electrical grids

Modulkategorie

Course

Designation

Week

Introduction: Evolution of the power grid

History of power grids / technological milestones, DC and AC Systems, components and devices, market and regulations

Fundamentals and devices in high voltage engineering

Tasks of HVE, Overvoltages origin and control, insulation Coordination (w2)
Properties of insulating materials (w2)
Electric fields and field stress control, (w3)
Break down in gases (homogeneous field – Paschen; inhomogeneous field – Streamer/Leader (w4)
Beakdown in liquids and in solids (w5)

2,3,4,5

HV-testing

Generation of testing high voltages (DC, AC and impulse)
Partial Discharge measurement

6,7

Interconnected Grids

Design of T&D Grids

Static load flow analysis, fault analysis
Frequency & active power exchange under control of the TSO
Combined voltage and reactive power control in the T&D Grid
Excursion Swissgrid Control Center, Aarau / W. Sattinger

8,9,10,11

Special Chapters on T&D (Transmission and Distribution)

Grid Dynamics and Stability
Optimized Grid use by “Smart Grid” Applications
Energy storage

12,13,14

Lehr- und Lernmethoden

ex cathedra teaching
exercises
presentation and discussion of case studies

Bibliografie

A. Küchler; «High Voltage Engineering», Springer Vieweg (2018)

Information on additional literature will occasionally be given during the module.

Vollständige Modulbeschreibung herunterladen

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