Christian Franck: Katalogdaten im Herbstsemester 2020

Auszeichnung: Die Goldene Eule
NameHerr Prof. Dr. Christian Franck
LehrgebietHochspannungstechnik
Adresse
Inst. f. El. Energieübertragung
ETH Zürich, ETL H 28
Physikstrasse 3
8092 Zürich
SWITZERLAND
Telefon+41 44 632 47 62
E-Mailfranck@eeh.ee.ethz.ch
URLhttp://hvl.ee.ethz.ch
DepartementInformationstechnologie und Elektrotechnik
BeziehungOrdentlicher Professor

NummerTitelECTSUmfangDozierende
227-0001-00LNetzwerke und Schaltungen I Belegung eingeschränkt - Details anzeigen 4 KP2V + 2UC. Franck
KurzbeschreibungDieser Kurs führt die Studierenden in die Grundlagen der Elektrotechnik und der elektrischen Netze ein und vermittelt die grundlegenden physikalischen Phänomene sowie die benötigten mathematischen Berechnungsmethoden.
LernzielDie Grössen Spannung und Strom sowie die Eigenschaften der Grundelemente elektrischer Schaltungen (Kondensator, Widerstand, Induktivität) vor dem Hintergrund elektrischer und magnetischer Felder verstehen. Schaltungselemente in ihrer technischen Ausführung mathematisch beschreiben, analysieren und letztlich auslegen können. Die Strom- und Spannungsverteilungen von Netzwerken mit Gleichspannungs- oder -stromquellen berechnen können. Die Induktionswirkung zeitlich veränderlicher magn. Felder verstehen und für zugeordnete technische Anwendungen mathematisch formulieren können.
InhaltElektrostatisches Feld; Stationäres elektrisches Strömungsfeld; Einfache elektrische Netzwerke; Stromleitungsmechanismen; Stationäres Magnetfeld; Zeitlich veränderliches elektromagnetisches Feld.
Um den Analyse- und Syntheseschritt der Ingenieurpraxis abzubilden, behandeln die Rechenübungen die mathematische Beschreibung praktischer technischer Systeme, sowie deren Funktionsanalyse und Dimensionierungsfragen.
SkriptManfred Albach, Elekrotechnik ISBN 978-3-86894-398-6 (2020)
ergänzt durch Vorlesungsfolien
LiteraturManfred Albach, Elekrotechnik
978-3-86894-398-6 (2020)
227-0085-08LProjekte & Seminare: Bluetooth Low Energy Programming for IoT Sensing System Belegung eingeschränkt - Details anzeigen
Nur für Elektrotechnik und Informationstechnologie BSc.

Die Lerneinheit kann nur einmal belegt werden. Eine wiederholte Belegung in einem späteren Semester ist nicht anrechenbar.
4 KP4PC. Franck
KurzbeschreibungDer Bereich Praktika, Projekte, Seminare umfasst Lehrveranstaltungen in unterschiedlichen Formaten zum Erwerb von praktischen Kenntnissen und Fertigkeiten. Ausserdem soll selbstständiges Experimentieren und Gestalten gefördert, exploratives Lernen ermöglicht und die Methodik von Projektarbeiten vermittelt werden.
LernzielBluethoot Low Energy System on Chip – Firmware Programming and sensors Interfacing using an Arm Cortex-M (Nordic nrf52838) Microcontroller

The NRF52832 Bltuethoo Low Energy System on Chip produced by Nordic Semiconductor is one of the pioneering low-power chip to integrate Bluetooth Low Energy (BLE 5.0) and microcontroller functionality into a single die. With the introduction of the BLE 5.0 standard, Bluetooth has achieved high data bandwidth with low power consumption. This makes the technology an ideal match for many applications i.e. IoT sensor application or audio streaming, by address
two of the greatest bottlenecks of these devices. This course offers the chance for participants to do hands-on programming of microcontrollers. In particular, the focus will be laid on interfacing with sensors, acquisition of data, on-board event-driven data processing and BLE transmissions. The programming will be performed in C.

Today’s microcontrollers offer a low power, efficient and cost-effective
solution of tackling a nearly infinite number of task specific applications. Ranging from IoT devices, wearable system, sensor (mesh) device, all the way to be being integrated as submodule for the most complex of system such as cars, planes and rockets. Microcontrollers derive their advantages from the efficient use of resources and as such require very efficient and resource-saving
programming. It is therefore mandatory to understand the microcontroller’s hardware components such as processor cores, ADC, clocks, serial communication, wireless communication, timers, interrupts, etc. The P&S includes 5 weeks project where the student will setup a IoT sensor node to monitor electric power transmission and distribution system.

The course will be taught in English.
227-0117-AALHigh Voltage Engineering
Belegung ist NUR erlaubt für MSc Studierende, die diese Lerneinheit als Auflagenfach verfügt haben.

Alle andere Studierenden (u.a. auch Mobilitätsstudierende, Doktorierende) können diese Lerneinheit NICHT belegen.
6 KP8RC. Franck
KurzbeschreibungUnderstanding of the fundamental phenomena and principles connected with the occurrence of extensive electric field strengths. This knowledge is applied to the dimensioning of high-voltage equipment. Methods of computer-modeling in use today are presented and applied within a workshop in the framework of the exercises.
LernzielThe students know the fundamental phenomena and principles connected with the occurrence of extensive electric field strengths. They comprehend the different mechanisms leading to the failure of insulation systems and are able to apply failure criteria on the dimensioning of high voltage components. They have the ability to identify of weak spots in insulation systems and to name possibilities for improvement. Further they know the different insulation systems and their dimensioning in practice.
Inhalt- discussion of the field equations relevant for high voltage engineering.
- analytical and numerical solutions/solving of this equations, as well as the derivation of the important equivalent circuits for the description of the fields and losses in insulations
- introduction to kinetic theory of gases
- mechanisms of the breakdown in gaseous, liquid and solid insulations, as well as insulation systems
- methods for the mathematical determination of the electric withstand of gaseous, liquid and solid insulations
- application of the expertise on high voltage components
- excursions to manufacturers of high voltage components
- excercise to learn on computer-modeling in high voltage engineering
SkriptHandouts
LiteraturA. Küchler, Hochspannungstechnik, Springer Berlin, 4. Auflage, 2017 (ISBN: 978-3-662-54699-4)
227-0117-00LHigh Voltage Engineering6 KP4GC. Franck, U. Straumann
KurzbeschreibungHigh electric fields are used in numerous technological and industrial applications such as electric power transmission and distribution, X-ray devices, DNA sequencers, flue gas cleaning, power electronics, lasers, particle accelerators, copying machines, .... High Voltage Engineering is the art of gaining technological control of high electrical field strengths and high voltages.
LernzielThe students know the fundamental phenomena and principles associated with the occurrence of high electric field strengths. They understand the different mechanisms leading to the failure of insulation systems and are able to apply failure criteria on the dimensioning of high voltage components. They have the ability to identify of weak spots in insulation systems and to propose options for improvement. Further, they know the different insulation systems and their dimensioning in practice.
Inhalt- discussion of the field equations relevant for high voltage engineering.
- analytical and numerical solutions/solving of this equations, as well as the derivation of the important equivalent circuits for the description of the fields and losses in insulations
- introduction to kinetic gas theory
- mechanisms of the breakdown in gaseous, liquid and solid insulations, as well as insulation systems
- methods for the mathematical determination of the electric withstand of gaseous, liquid and solid insulations
- application of the expertise on high voltage components
- excursions to manufacturers of high voltage components
SkriptHandouts
LiteraturA. Küchler, High Voltage Engineering: Fundamentals – Technology – Applications, Springer Berlin, 2018 (ISBN 978-3-642-11992-7)
227-0122-00LIntroduction to Electric Power Transmission: System & Technology
Students that complete the course from HS 2020 onwards obtain 4 credits.
4 KP2V + 2UC. Franck, G. Hug
KurzbeschreibungIntroduction to theory and technology of electric power transmission systems.
LernzielAt 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 overhead power lines, explain the technology of transformers and lines, calculate stationary power flows and other basic parameters in simple power systems.
InhaltStructure of electric power systems, transformer and power line models, analysis of and power flow calculation in basic systems, technology and principle of electric power systems.
SkriptLecture script in English, exercises and sample solutions.
227-1631-10LCase Studies: Energy Systems and Technology: Part 1 Belegung eingeschränkt - Details anzeigen
Only for Energy Science and Technology MSc.
2 KP4GC. Franck, C. Schaffner
KurzbeschreibungThis course will allow the students to get an interdisciplinary overview of the “Energy” topic. It will explore the challenges to build a sustainable energy system for the future. This will be done through the means of case studies that the students have to work on. These case studies will be provided by industry partners.
LernzielThe students will understand the different aspects involved in designing solutions for a sustainable future energy system. They will have experience in collaborating in interdisciplinary teams. They will have an understanding on how industry is approaching new solutions.
SkriptDescriptions of case studies.