Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Energy Trends: Resources and Use
Energietrends: Ressourcen und Nutzung
page 1
Module Coordinator
Balzer
Language
German
Lecturer
Balzer
Course Code
18133
Course Name
Energy Trends: Resources and Use
Energietrends: Ressourcen und Nutzung
Credits
8
Teaching Form
V+S
Frequency Offered
WS
Credits
8
Learning Outcomes, Acquired competence:
Independent preparation of technical themes; exercise in presentation, presentation of results
Auxiliary Studies:
none
Module Level
EES, WI-ET; MSc EPE, MSc ETiT
Exam Code
118671
Examiner Code
3460
Comments
Content / Syllabus
Themes from the field of electrical power systems
Teaching Materialis (1)
script
Electronic Teaching Material
www.eev.e-technik.tu-darmstadt.de
118671
Prerequisites
none
Type of Examination
written/oral
Duration
20 min
Semester
M3
Work Load
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Future Electrical Power Supply
Elektrische Energieversorgung der Zukunft
page 2
Module Coordinator
Balzer
Language
German
Lecturer
Balzer/Stenzel
Course Code
18714
Course Name
Future Power Systems Supply
Energieversorgung der Zukunft
Credits
6
Teaching Form
S
Frequency Offered
WS/SS
Credits
6
Learning Outcomes, Acquired competence:
Independent preparation of technical themes; exercise in presentation, presentation of results
Auxiliary Studies:
none
Module Level
EES, WI-ET; MSc EPE, MSc ETiT
Exam Code
118577
Examiner Code
3460/ 11894
Comments
Content / Syllabus
Themes from the field of electrical power systems
Teaching Materialis (1)
Electronic Teaching Material
118577
Prerequisites
Type of Examination
written/oral
Duration
20 min
Semester
M3
Work Load
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Advanced Power Electronics
Advanced Power Electronics
page 3
Module Coordinator
Mutschler
Language
Englisch
Lecturer
Mutschler
Course Code
18714
Course Name
Advanced Power Electronics
Advanced Power Electronics
Credits
5
Frequency Offered
SS
Teaching Form
2V+2Ü
Credits
5
Learning Outcomes, Acquired competence:
After an active participation in the lecture, especially by asking all questions on topics which you did not fully understand as well by solving all exercises prior to the
respective tutorial (i.e. not just shortly before the examination) you should be able to
1.) Identify the circuit diagrams for isolating DC/DC converters, especially for use in switched mode power supplies. Calculate the currents and voltages in these
circuits using defined simplifications.
2.) Explain the cross sectional layers and the basic modes of operation for power semiconductors (diode, thyristor, GTO. Mosfet and IGBT). Describe the steady state
and dynamic behavior of these devices.
3.) Describe the functions of gate dive-circuits for ITGBTs.
4.) Calculate the thermal behavior and design the cooling equipment for a voltage source inverter equipped with IGBT modules.
5.) Describe the stress reliving circuits to reduce switching losses in IGBTs.
6.) Calculate the current and voltage characteristics in quasi-resonant and resonant circuits used in power electronics.
Auxiliary Studies:
No
Module Level
MScETiT, MScEPE, EtiT, Wi/ETiT
Exam Code
118208
Comments
118208
Examiner Code
1353
Prerequisites
BScETiT or equivalent, especially Power Electronics and Basics of Semiconductors
Type of Examination
written
Duration
90 Minuten
Semester
M2
Work Load
151h
Vorles. 28h, Nacharbeit
Vorles. 25 h, Übung
Vorbereitung: 25h
Übung: 28h, Prüfungs
Vorber. 45h
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Content / Syllabus
Switch mode power supplies (insulating DC/DC-converters)
Realictic behaviour of power semiconductors:
Basics of semiconductor physics; Behaviour of diode,bipolar transistor, SCR, GTO, MOSDFET and IGBT,
Important circuits for switching real semiconductors with low losses
Forced commutation of SCRs, Loss reducing snubbers, quasi- resonant circuits, possibilitier for resonant switching.
Teaching Materialis (1)
Lecture notes, instructions for exercises are available both as hard copy or as download.
Mohan, Undeland, Robbins: Power Electronics: Converters, Applicationsand Design; John Wiley Verlag; New York; 1989
Electronic Teaching Material
http://www.srt.tu-darmstadt.de/pub/edu/vorles_e.html#PE2
page 3.2
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Computational Electromagnetics and Applications
Verfahren und Anwendungen der Feldsimulation
page 4
Module Coordinator
Weiland
Language
German
Lecturer
Weiland
Course Code
18101
Course Name
Computational Electromagnetics and Applications
Verfahren und Anwendungen der Feldsimulation
Credits
3
Teaching Form
V
Frequency Offered
SS
Credits
3
Learning Outcomes, Acquired competence:
Students will know numerical solution techniques to Maxwell´s equations. They will understand basic concepts of the Finite Integration Technique (FIT). Students
will learn about practical application of the method and using CAD tools to solve numerical field problems.
Auxiliary Studies:
none
Module Level
Exam Code
118056
Prerequisites
Recommended: Basic knowledge in electrotechnics and Maxwell´s equations, basics in linear
algebra,recommended: knowledge in "Technical Electrodynamics"
Examiner Code
5703
Type of Examination
oral
Duration
30 Minuten
Semester
M
Work Load
Comments
Content / Syllabus
Basics FIT, electrostatics, magnetostatics, magnetoquasistatics, high frequency simulations, convergence studies, discretisation, time- and frequency domain
simulations, Leapfrog algorithm, eigenvalue analysis.
Teaching Materialis (1)
Course notes, lecture slides.
Electronic Teaching Material
118056
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
page 5
Module Title
Control of Drives
Control of Drives
Module Coordinator
Mutschler
Language
English
Credits
5
Course Name
Control of Drives
Control of Drives
Lecturer
Mutschler
Course Code
18715
Frequency Offered
WS
Teaching Form
2 V+ 2 Ü
Credits
5
Learning Outcomes, Acquired competence:
After an active participation in the lectureas well as by solving all exercises prior to the respective tutorial students should be able to :
1.) develop the control-oriented block diagrams for the DC-machine operating in base speed range as well as in field weakening range.
2.) design the control loops for 1.) concerning the structure and the control parameters.
3.) understand the nature of space vectors and master their application in different rotating frames of reference.
4.) develop the dynamic equations of the permanent exited synchronous machine and the induction machine and to simplify these equations by help of
suitable rotating reference frames and represent these equations as non-linear control-oriented block diagram.
5.) design the control loops according to 4.) especially the field-oriented control concerning the structure of the control loops and the control parameters.
6.) understand the deduction of equations given in the literature for machine types, which are not discussed in this lecture, e.g. for the doubly fed
induction machine.
7.) derive the models and the observers for the rotor flux for the induction machine in different frames of reference and to apprise the benefits and drawbacks of the different solutions.
8.) design the control loops for the super-imposed speed controls even for mechanically oszillating loads.
Auxiliary Studies:
Module Level
MScETiT, MScEPE, MScMechatronik, EtiT, Wi/ETiT
Exam Code
118209
Comments
118209
Examiner Code
1353
Prerequisites
BScETiT or equivalent, especially Control Theory and Electrical Machines / Drives
Type of Examination
written
Duration
120 Minuten
Semester
M1, M3
Work Load
176h
Vorles. 28h, Nacharbeit
Vorles. 30 h, Übung
Vorbereitung: 40h
Übung: 28h, Prüfungs
Vorber. 50h
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
page 5.2
Content / Syllabus
Control structures for drives; Design of controllers for drives; VSIs for drives; Space Vectors as basis of modelling AC-machines; Reference frames for description of
AC-machines; Control oriented block diagram for DC-drive; Structure and design of the controllers;
Control oriented block diagram for Permanent Magnet Synchronous Machine (PMSM);
Control oriented block diagram for Induction machine (IM)
Torque control for AC-machines using linear or switching controllers.
Field Oriented Control and Direct Torque Control für PMSM and IM.
Models and observers foer rotor flux of IM
Speed control, including oscillatory load.
Teaching Materialis (1)
Lecture notes, instructions for exercises are available both as hard copy or as download.
Schröder, Dierk: Elektrische Antriebe, Bd. 1-4, Springer-Lehrbuch, Berlin
Mohan, Ned: Electric Drives, Minneapolis 2001
Electronic Teaching Material
http://www.srt.tu-darmstadt.de/pub/edu/vorles_e.html#CoD
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Digital Control of mechatronic Systems I
Digitale Regelung mechatronischer Systeme I
page 6
Module Coordinator
Konigorski
Language
German
Lecturer
Konigorski
Course Code
18147
Course Name
Digital Control of mechatronic Systems I
Digitale Regelung mechatronischer Systeme I
Credits
4
Teaching Form
V+Ü
Frequency Offered
SS
Credits
4
Learning Outcomes, Acquired competence:
The Student gains knowledge in the field of digital signaltheory. He knows the basic differences between continuous and discrete control systems and is able to
develop discrete controllers.
Auxiliary Studies:
none
Module Level
3rd year
Exam Code
118436
Prerequisites
System Dynamics and Automatic Control Systems I, Additions to System Dynamics and Automatic
Control Systems I
Examiner Code
61663
Type of Examination
written
Duration
120 Minuten
Semester
M
Work Load
Comments
Content / Syllabus
theoretical aspects of discrete-time control systems:
discrete-time signals, holding element, z-transform, convolution sum, z-transfer function, poles and stability analysis
control systems for deterministic disturbances:
discretizing continuous PID-controllers, deadbeat and cancellation controllers, state-space controllers with observer, controllers for processes with large deadtime,
comparison of different controllers, optimal controllers
Teaching Materialis (1)
Skript Konigorski: "Digitale Regelungssysteme", Ackermann: "Abtastregelung", Aström, Wittenmark: "Computer-controlled Systems", Föllinger: "Lineare
Abtastsysteme", Isermann: "Digitale Regelungstechnik: Band 1: Grundlagen, deterministische Regelungen", Isermann: "Digitale Regelungstechnik. Band 2:
Stochastische Regelungen, Mehrgrößenregelungen, adaptive Regelungen, Anwendungen", Phillips, Nagle: "Digitla control systems analysis and design", Unbehauen:
"Regelungstechnik 2: Zustandsregelungen, digitale und nichtlineare Regelsysteme"
Electronic Teaching Material
118436
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Digital Measuring
Digitale Messtechnik
Course Name
Digital Measuring Techniques
Digitale Messtechnik
page 7
Module Coordinator
Pfeiffer
Language
German
Credits
4
Lecturer
Prof. Dr.-Ing. W. Pfeiffer
Course Code
18908
Teaching Form
V+Ü
Frequency Offered
WS
Credits
4
Learning Outcomes, Acquired competence:
Basics of digital measuring equipment and data processing/data transport. Those are needed for any electrical engineer.
Auxiliary Studies:
Participation in the lecture and collaboration in the excersises
Module Level
Diplom ETIT, MSc. ETIT: AET, AUT, DT, EET, NKT,
IMNT, MFT, MEC, MEL, TET; Diplom Wi-ET; MSc
IKT, MSc. IST, MSc. MEC, MSc.
Exam Code
118085
Examiner Code
1468
Prerequisites
Mathematics, Basics of Electrical Engineering
Type of Examination
oral
Duration
30 Minuten
Semester
M2
Work Load
150 h
Comments
Content / Syllabus
Basics of Fourier Transformation, Discrete-Fourier-Transformation, Fast-Fourier-Transformation, Analog-Digital-Converters, Digital-Analog-Converters, Errors of
A/D-Converters and Methods of Testing, Digital Storage Oscilloscope, Logic Analyser, Digital Spectrum Analyser, Fundamentals of Data Bus Systems, Parallel Data
Bus Systems, Serial Data Bus Systems.
Teaching Materialis (1)
Pfeiffer: Electrical Measurement Techniques; Springer-Publication, Pfeiffer: Digital Measuring Techniques; Springer-Publication
Electronic Teaching Material
www.tu-darmstadt.de/etit/fb/et/emt
118085
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Efficient Use of Energy
Rationelle Energieverwendung
page 8
Module Coordinator
Hartkopf
Language
German
Lecturer
Hartkopf
Course Code
18706
Course Name
Efficient Use of Energy
Rationelle Energieverwendung
Credits
4
Teaching Form
V+Ü
Frequency Offered
SS
Credits
4
Learning Outcomes, Acquired competence:
identification and unterstanding of thermodynamics, ecological consciousness, calculation and comparision of efficiency
Auxiliary Studies:
none
Module Level
Mxxx, EES 260, M-EPE1.1, AET 314, AUT 324,
Wi/ETiT-EES 321
Exam Code
118229
Examiner Code
17492
Prerequisites
mathematics, physics
Type of Examination
written
Duration
120 Minuten
Semester
M2, M4
Work Load
150
Comments
Content / Syllabus
Types of energy, exergy and anergy, efficiency and utilisation degree, storage of electrical energy, thermal process, fuel cell, stirling-motor, transport of energy,
hydrogen technology, combined heat and power
Teaching Materialis (1)
Course notes available for purchase in FG office
Electronic Teaching Material
http://www.re.e-technik.tu-darmstadt.de
118229
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Electric Traction Vehicles
Elektrische Triebfahrzeuge
page 9
Module Coordinator
Neudorfer
Language
German
Lecturer
Neudorfer
Course Code
18719
Course Name
Electric Traction Vehicles
Elektrische Triebfahrzeuge
Credits
3
Frequency Offered
WS
Teaching Form
V
Credits
3
Learning Outcomes, Acquired competence:
Understanding of basic concepts of electrical traction vehicles for street-cars and trains.
Auxiliary Studies:
Visit of companies
Module Level
MSc ETiT, MSc MEC, MSc EPE, MSc WI-ET
Exam Code
0
Examiner Code
20560
Prerequisites
Bachelor in Electrical Engineering or Mechatronics
Type of Examination
oral
Duration
0.5 h
Semester
M1 oder M2 oder M3
Work Load
50 h, davon 30 h Präsenz
Comments
Content / Syllabus
Content of the lecture "Elektrische Triebfahrzeuge": -ancient – development of electrical traction: -mechanics of traction -mechanical part of electrical traction
vehicles -electrical part of electrical traction vehicles -converter for electrical traction -motors for traction -monitoring systems -problems in designing electrical
drive systems -examples of traction vehicles
Teaching Materialis (1)
Textbook for the lecture; Bendel, H. u.a.: Die elektrische Lokomotive. Transpress, Berlin, 1994. Filipovic, Z: Elektrische Bahnen. Springer, Berlin, Heidelberg, 1995.
Bäzold, D. u.a.: Elektrische Lokomotion deutscher Eisenbahnen.Alba, Düsseldorf, 1993. Obermayer, H.J.: Internationaler Schnellverkehr.Franckh-Kosmos, Stuttgart,
1994. Volkhard, J.: Magnetisches Schweben. Springer, Berlin, Heidelberg, New York, 1988
Electronic Teaching Material
http://www.ew.e-technik.tu-darmstadt.de/
0
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Electro-thermal recycling processes
Elektrothermische Verfahren in Recyclingprozessen
page 10
Module Coordinator
Nacke
Language
German
Lecturer
Nacke
Course Code
18708
Course Name
Electro-thermal recycling processes
Elektrothermische Verfahren in Recyclingprozessen
Credits
3
Frequency Offered
WS oder SS
Teaching Form
V
Credits
3
Learning Outcomes, Acquired competence:
Understanding of basic design proceduces for electrothermal melting and its so significance for recycling.
Auxiliary Studies:
Module Level
MSc ETiT, MSc MEC, MSc EPE, MSc WI-ET
Exam Code
0
Examiner Code
14991
Prerequisites
Bachelor in Electrical Engineering or Mechatronics
Type of Examination
oral
Duration
0.5 h
Semester
M1 oder m2 oder M3
Work Load
50 h, davon 30 h Präsenz
Comments
Content / Syllabus
The technical and economical significance of electrical heating in industrial application is introduced. The advantages, attributes and fields of application of different
kinds of electrical heating processes will be shown with some selected examples. In the second part of the lecture basic relationships of the thermal- and electrical
physics are discussed, which are required for the understanding of all the different electrical heating processes. Modern calculation programs in practical use, which
are mainly based on the Finite-Difference-(FDM) and Finite-Element-Method (FEM), will be presented and their application will be shown. The main part of the
lecture treats with the technical application of the different electrical heating processes. The focus lies on inductive and capacitive heating technology.
Teaching Materialis (1)
Textbook; PowerPoint presentations; Fasholz, J., Orth, G.: Induktive Erwärmung, RWE Energie AG, Essen, 4. Aufl., 1991
Electronic Teaching Material
http://www.ew.e-technik.tu-darmstadt.de/
0
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Fuzzy Logic, Neural Networks and Evolutionary Algorithms
Fuzzy-Logik, Neuronale Netze und Evolutionäre Algorithmen
page 11
Module Coordinator
Adamy
Language
German
Lecturer
Adamy
Course Code
18213
Course Name
Fuzzy Logic, Neural Networks and Evolutionary Algorithms
Fuzzy-Logik, Neuronale Netze und Evolutionäre Algorithmen
Credits
4
Teaching Form
V+Ü
Frequency Offered
WS
Credits
4
Learning Outcomes, Acquired competence:
1) recall the elements and set-up of standardized fuzzy-logic, neural networks and evolutionary algorithms 2) discuss the pros and cons of certain set-ups of systems
from computational intelligence for solving a given problem 3) recognise situations in which tools taken from computational intelligence can be applied for problem
solving 4) create programs from algorithms taught in the lecture 5) extend the learnt standard procedures to solve new problems
Auxiliary Studies:
none
Module Level
MSc ETiT, ETIT, MEC, MSc ICE, MSc IKT, Bionik
Exam Code
118060
Examiner Code
18779
Prerequisites
Type of Examination
written
Duration
90 min.
Semester
M
Work Load
120
Comments
Content / Syllabus
The basics of Computationl Intelligence are taught in this course. Computational Intelligence is a subgroup of Artificial Intelligence and contains the topics of Fuzzy
Logic, Neural Networks and Evolutionary Algorithms. The lecture provides basic methods and especially their application in engineering.
Teaching Materialis (1)
Adamy - Fuzzy Logik, Neuronale Netze und Evolutionäre Algorithmen - Shaker Verlag - Available for purchase at the FG office
Electronic Teaching Material
www.rtr.tu-darmstadt.de/lehre/e-learning (optionales Material)
118060
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
High Voltage Measuring Techniques
Messverfahren der Hochspannungstechnik
page 12
Module Coordinator
Breilmann
Language
German
Lecturer
Breilmann
Course Code
0
Course Name
High Voltage Measuring Techniques
Messverfahren der Hochspannungstechnik
Credits
3
Teaching Form
V
Frequency Offered
WS
Credits
3
Learning Outcomes, Acquired competence:
Auxiliary Studies:
Module Level
MSc ETiT
Exam Code
118546
Prerequisites
Electrical Power Engienering
Examiner Code
NN
Type of Examination
oral
Duration
30 Minuten
Semester
M
Work Load
Comments
Content / Syllabus
Measurement of High DC Voltages, Measurement of High AC Voltages in High Voltage Transmission Systems, Measurement of High AC Voltages in the
Laboratory, Measurement of High Impulse Voltages, Impulse Voltages, Design of Dividers, Computation of the Step Response and of the Transfer Characteristic,
Analytical Calculation of the Response Time, Calculation of the Divider Output Voltage, Measurement of Step Response and Response Parameters, Calibration of an
Impulse Measuring System, Circuits for Low Voltage Signal Cable Matching, EMTP Model of a RC-Divider, Measurement and Calculation of the Uncertainty of the
Impulse Voltage Measuring System, DKD-Calibration, Accreditation of a Lab for type tests with voltages up to 3 MV.
Teaching Materialis (1)
Electronic Teaching Material
118546
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
High-Speed Measuring Techniques
Impulsmesstechnik
Course Name
High-Speed Measuring Techniques
Impulsmesstechnik
page 13
Module Coordinator
Pfeiffer
Language
German
Credits
3
Lecturer
Prof. Dr.-Ing. W. Pfeiffer
Course Code
18719
Teaching Form
V
Frequency Offered
SS
Credits
3
Learning Outcomes, Acquired competence:
Additional information about the measurement of high speed/high frequency phenomena. Such knowledge is useful for engineers in research and development.
Auxiliary Studies:
Participation in the lecture
Module Level
Diplom ETIT, MSc. ETIT: AET, AUT, DT, EET, NKT,
IMNT, MFT, MEC, MEL, TET; Diplom Wi-ET; MSc
IKT, MSc. IST, MSc. MEC, MSc.
Exam Code
118517
Examiner Code
1468
Prerequisites
Basics of Electrical Engineering
Type of Examination
oral
Duration
30 Minuten
Semester
M2
Work Load
120 h
Comments
Content / Syllabus
Concentrated and Distributed Voltage Dividers, High-Voltage Probes, Coaxial Shunts, Lossy Measuring Lines, Reflections and Termination of Lines, Transfer
Impedance, Impulse Amplifiers: Special Requirements, Computer-Aided Design and Optimisation, Wide-Band- and Sampling-Oscilloscopes, Calibration of
Measuring Systems, Measuring Techniques and Test Circuits for EMC-Measurements (Electro-Magnetic-Compatibility).
Teaching Materialis (1)
Pfeiffer: Electrical Measurement Techniques; Springer-Publication
Electronic Teaching Material
www.tu-darmstadt.de/etit/fb/et/emt
118517
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Large generators and high power drives
Großgeneratoren und Hochleistungsantriebe
page 14
Module Coordinator
Binder
Language
German/English
Credits
4
Frequency Offered
WS oder SS
Lecturer
Binder
Course Code
18804
Teaching Form
V+Ü
Credits
4
Course Name
Large generators and high power drives
Großgeneratoren und Hochleistungsantriebe
Learning Outcomes, Acquired competence:
Expert knowledge in design of generators, large drives, their cooling systems and operational performance is acquired.
Auxiliary Studies:
Tutorial with design examples / Visit of companies
Module Level
MSc ETiT, MSc EPE, MSc MEC, MSc WI-ET
Exam Code
118540
Examiner Code
18184
Prerequisites
Physics, Electrical Machines and Drives, Electrical Power Engineering
Type of Examination
oral
Duration
0,5 h
Semester
M1 oder M2 oder M3
Work Load
100 h; davon 30 h
Präsenz
Comments
Content / Syllabus
Design of large electric generators: Special cooling methods with air, hydrogen and water, loss evaluation, especially eddy current losses, and measures to reduce the
additional losses. Design of big hydrogenerators up to 800 MVA and turbo generators up to 1600 MVA with desing examples. Application of power electronics in
large variable speed drives with synchronous motors: Synchronous converter and cyclo-converter. Numerous photographs to illustrate applications, excursion with
students to special firms or plants.
Teaching Materialis (1)
Detailed textbook with calculated examples; Vas, P.: Parameter estimation, condition monitoring, and diagnosis of electrical machines, Clarendon Press, 1993
Fitzgerald, A.; Kingsley, C.; Kusko, A.: Electric machinery,McGraw-Hill, 2003
Leonhard, W.: Control of electrical drives, Springer, 1996
Electronic Teaching Material
http://www.ew.e-technik.tu-darmstadt.de/
118540
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Measurement and Testing Methods of Electromagnetic Compatibility
Mess- und Prüfverfahren der EMV
Course Name
Measurement and Testing Methods of Electromagnetic Compatibility
Mess- und Prüfverfahren der Elektromagnetischen Verträglichkeit
page 15
Module Coordinator
Pfeiffer
Language
German
Credits
3
Lecturer
Prof. Dr.-Ing. W. Pfeiffer
Course Code
18603
Teaching Form
V
Frequency Offered
WS
Credits
3
Learning Outcomes, Acquired competence:
Measuring and test methods for the determination of the Electromagnetic Compatibility (EMC). Basic knowledge for engineers in the development and testing area.
Auxiliary Studies:
Participation in the lecture
Module Level
Diplom ETIT, MSc. ETIT: AET, AUT, DT, EET, NKT,
IMNT, MFT, MEC, MEL, TET; Diplom Wi-ET; MSc
IKT, MSc. IST, MSc. MEC, MSc.
Exam Code
118559
Examiner Code
1468
Prerequisites
Basics of Electrical Engineering
Type of Examination
oral
Duration
30 Minuten
Semester
M1
Work Load
120 h
Comments
Content / Syllabus
Immunity: Noise Immunity against Electrostatic Discharge (ESD), Immunity against radiated Radio Frequency (RF) electromagnetic Fields, Immunity against
Electrical fast transients (burst), Immunity against surges, Immunity against conducted Radio Frequency (RF), disturbances Immunity against Magnetic Fields,
Immunity against Voltage Fluctuations; Emission: Reaction to the public power supply system: Harmonic current Emissions, Voltage Fluctuations and Flicker;
Conducted Radio Frequency (RF) disturbances, Power Lines; Communication Lines; Radiated Radio Frequency disturbances: Measurements in open Fields,
Measurements in shielded rooms.
Teaching Materialis (1)
Electronic Teaching Material
www.tu-darmstadt.de/etit/fb/et/emt
118559
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Motor Developement for Electric Drive Systems
Motorenentwicklung in der Antriebstechnik
Module Coordinator
Binder
Course Name
Motor Developement for Electric Drive Systems
Motorenentwicklung in der Antriebstechnik
page 16
Language
German/English
Credits
4
Frequency Offered
WS oder SS
Course Code
18703
Teaching Form
V2+Ü1
Credits
4
Lecturer
Binder
Learning Outcomes, Acquired competence:
The students get acquainted with latest electric motor developement details and learn its benefits for application.
Auxiliary Studies:
Tutorial with practical examples/Visit of companies
Module Level
MSc EPE, MSc ETiT, MSc MEC, MSc WI-ET
Exam Code
118508
Examiner Code
18184
Prerequisites
Physics, Electrical Machines and Drives, Electrical Power Engineering
Type of Examination
oral with short
presentation/oral+written
(optional)
Duration
Schriftlich 1.5 h,
mündlich 0,5 h
Semester
M1 oder M2 oder M3
Work Load
100 h, davon 30 h
Präsenz
Comments
Content / Syllabus
Development of modern drives systems such as inverter-fed induction machines, permanent magnet synchronous and dc machines, "brushless" dc, synchronous and
switched reluctance drives as well as transversal flux machines and modular synchronous motors are discussed in detail. Interaction between inverter and motor such
as additional voltage spikes and bearing currents are explained. New bearing concepts for high speed, prototype measurements and sensing techniques are highlighted.
Teaching Materialis (1)
Detailed text book and collection of exercices; Complete set of PowerPoint presentations
Hendershot, J.R.; Miller, T.J.E.: Design of brushless permanent-magnet motors, Clarendon Press, Oxford, 1994
Falk, K.: Der Drehstrommotor - ein Lexikon für die Praxis, VDE-Verlag, Offenbach, 1997
Miller, T.J.E.: Switched Reluctance Motors and their control, Clarendon Press, Oxford, 1993
Electronic Teaching Material
http://www.ew.e-technik.tu-darmstadt.de/
118508
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
New technologies of electric energy converters and acuators
page 17
Module Coordinator
Binder
Language
German or
English
Lecturer
Binder
Course Code
18730
Credits
4
Frequency Offered
WS oder SS
Neue Technologien elektrischer Energiewandler und Aktoren
Course Name
New technologies of electric energy converters and acuators
Neue Technologien elektrischer Energiewandler und Aktoren
Teaching Form
V+Ü
Credits
4
Learning Outcomes, Acquired competence:
Basic knowledge in application of superconductivity in energy systems is understood as well as magnetic levitation, magnetohydrodynamics and fusion technology.
Auxiliary Studies:
Tutorial/Visit of companies
Module Level
MSc EPE, MSc ETiT, MSc MEC, MSc WI-ET
Exam Code
118509
Comments
118509
Examiner Code
18184
Prerequisites
Physics, Electrical Machines and Drives, Electrical Power Engineering
Type of Examination
oral
Duration
0,5 h
Semester
M1 oder M2 oder M3
Work Load
100h, davon 30 h
Präsenz
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
page 17.2
Content / Syllabus
Goal: The application of new technologies, i.e. super conduction, magnetic levitation techniques and magneto-hydrodynamic converter principles, are introduced to
the students. The physical operation mode in principle, implemented prototypes and the current state of the development are described in detail. Content: Application
of the superconductors for electrical energy converters:
- rotating electrical machines (motors and generators),
- solenoid coils for the fusion research,
- locomotive- and railway transformers,
- magnetic bearings.
Active magnetic bearings (“magnetic levitation”)
- basics of the magnetic levitation technique,
- magnetic bearings for high speed drives in kW to MW range,
- application for high-speed trains with linear drives.
Magneto-hydrodynamic energy conversion:
- physical principle,
- state of the art and perspectives.
Fusion research:
- magnetic field arrangements for contactless plasma inclusion,
- state of the current research.
Teaching Materialis (1)
Detailed textbook; Komarek, P.: Hochstromanwendungen der Supraleitung, Teubner, Stuttgart, 1995
Buckel, W.: Supraleitung, VHS-Wiley, Weinheim, 1994
Schweitzer, G.; Traxler, A.; Bleuler, H.: Magnetlager, Springer, Berlin, 1993
Schmidt, E.: Unkonventionelle Energiewandler, Elitera, 1975
Electronic Teaching Material
http://www.ew.e-technik.tu-darmstadt.de/
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Overvoltage Protection and Insulation Coordination
Überspannungsschutz und Isolationskoordination
page 18
Module Coordinator
Hinrichsen
Language
German/English
Credits
3
Frequency Offered
WS
Lecturer
Hinrichsen
Course Code
18814
Teaching Form
V
Credits
3
Course Name
Overvoltage Protection and Insulation Coordination
Überspannungsschutz und Isolationskoordination
Learning Outcomes, Acquired competence:
Auxiliary Studies:
none
Module Level
Exam Code
118756
Prerequisites
Examiner Code
20653
Type of Examination
oral
Duration
Semester
M
Work Load
Comments
Content / Syllabus
Voltage Stresses in Service, Characteristics of Overvoltage Protective Devices, Co-ordination of Withstand Voltages, Required Withstand Voltage, Standard
Withstand Voltage an Testing Procedures
Teaching Materialis (1)
Electronic Teaching Material
118756
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Planning and application of electrical drives (Drives for electric
vehicles)
Praxisorientierte Projektierung elektrischer Antriebe (Antriebstechnik
für Elektroautos)
page 19
Module Coordinator
Neudorfer
Language
German
Lecturer
Neudorfer
Course Code
18175
Course Name
Planning and application of electrical drives (Drives for electric vehicles)
Praxisorientierte Projektierung elektrischer Antriebe (Antriebstechnik für
Elektroautos)
Credits
4
Teaching Form
P
Frequency Offered
SS
Credits
4
Learning Outcomes, Acquired competence:
Knowledge on design proceduces for electric modulation systems for electric and hybrid cars
Auxiliary Studies:
Project work/ MATLAB/Simulink Training of presentation techniques/Seminary final report
Module Level
MSc ETiT, MSc MEC, MSc EPE, MSc WI-ET
Exam Code
0
Examiner Code
20560
Prerequisites
Bachelor in Electrical Engineering or Mechatronics, "Electrical Drives and Machines" and "Power
electronics" recommended
Type of Examination
seminary work / oral
Duration
Seminarvortrag 0.5 h /
Prüfung 0.5 h
Semester
M2 oder M3
Work Load
125 h, davon 45 h
Präsenz
Comments
Content / Syllabus
Mono- and hybrid drive concepts, motor technology, DC and AC machines, drive systems, car dynamic, energy storage; Seminary work: simulation of car with
electric drive train, measurement with a DaimlerChrysler E-Go-Cart, presentation of seminary work
Teaching Materialis (1)
Textbook; Binder, A.: Electric machines and drives I, Darmstadt Univ. of Technology Mitschke, M.: Dynamik der Kraftfahrzeuge, Springer Verlag Berlin
Electronic Teaching Material
http://www.ew.e-technik.tu-darmstadt.de/
0
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
page 20
Module Title
Power Cable Systems
Energiekabelanlagen
Module Coordinator
Blechschmidt
Language
German
Credits
3
Course Name
Power Cable Systems
Energiekabelanlagen
Lecturer
Blechschmidt
Course Code
0
Teaching Form
V
Frequency Offered
WS
Credits
3
Learning Outcomes, Acquired competence:
Auxiliary Studies:
Module Level
MSc ETiT
Exam Code
118536
Prerequisites
Electrical Power Engineering
Examiner Code
NN
Type of Examination
oral
Duration
30 Minuten
Semester
M
Work Load
Comments
The course includes one excursion. The participants will take part for a half day in the cabling course run by HSE Technik, GmbH & Co. KG. In the cabling course
during the winter break fitters attend, to be trained in all types of cables in operation. Cab
Content / Syllabus
The course provides theorie as well as inside-know-how on technical and commercial issues of a power network operator. Relevant topics comprise, e.g. the
permeability of cables to humidity, testing of new cables, diagnosis, of cables already in operation or the latest results in research such as, superconductivity.
Additionally the course reflects the most recent effects, of European power market liberalisation on network operation. The course contains: General, Cable structures
and design, Standards and (German) VDE regulations, Types of cables, Cable laying, Fittings and installation, Testing of cable networks
Teaching Materialis (1)
Beck Texte im dtv Verlag: Patentrecht und Musterrecht
Electronic Teaching Material
118536
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Power Laboratory I (EPE)
Module Coordinator
Binder
page 21
Language
English/German
facultative
Credits
4
Frequency Offered
WS
Course Code
18972
Teaching Form
P
Credits
4
Energietechnisches Praktikum I (EPE)
Course Name
Power Laboratory I (EPE)
Energietechnisches Praktikum I (EPE)
Lecturer
Binder, Balzer, Hartkopf,
Hinrichsen, Mutschler,
Stenzel
Learning Outcomes, Acquired competence:
Practical knowledge is gained in measuring and operating electrical devices and apparatus of electrical power engineering in small groups of students.
Auxiliary Studies:
Mandatory attendance at the briefing and labs, lab reports and written exam
Module Level
MSC EPE
Exam Code
518674
Prerequisites
Bachelor of Science in Electrical Engineering, Power Engineering or similar
Examiner Code
18184/3460/017492/20653/1353
Type of Examination
written
Duration
Protokolle im
Eigenstudium,
Schriftliche Prüfung 3 h
Semester
M1
Work Load
76 h, davon Präsenz 26
h
Comments
Content / Syllabus
Safety instructions for lab; Topic of experiments:
Electrical machines and drives: DC-Machine
Power electronics: Induction machine AC Drive with voltage source inverter
Electrical energy supply: Shock hazard protection
High voltage technology: Generating and measuring of high voltages
Renewable Energies: Fuel cell
Electrical power systems: Digital power system protection
Teaching Materialis (1)
Binder, A. et al.: Textbook with detailed description of experiments; Hindmarsh, J.: Electrical Machines and their Application, Pergamon Press, 1991
Nasar, S.A.: Electric Power systems. Schaum's Outlines
Mohan, N. et al: Power Electronics, Converters, Applications and Design, John Wiley & Sons, 1995
Kind, D., Kärner, H.: High-Voltage Insualtion Technology, Friedr. Vieweg & Sohn, Braunschweig/Wiesbaden, 1985, ISBN 3-528-08599-1
Text book Power Lab 1
518674
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Electronic Teaching Material
http://www.ew.e-technik.tu-darmstadt.de/
page 21.2
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Power Laboratory II (EPE)
Module Coordinator
Binder
page 22
Language
English/German
facultative
Credits
4
Frequency Offered
SS
Course Code
18974
Teaching Form
P
Credits
4
Energietechnisches Praktikum II (EPE)
Course Name
Power Laboratory II (EPE)
Energietechnisches Praktikum II (EPE)
Lecturer
Binder, Balzer,
Hinrichsen, Mutschler,
Stenzel
Learning Outcomes, Acquired competence:
Practical knowledge is gained in measuring and operating electrical devices and apparatus of electrical power engineering in small groups of students.
Auxiliary Studies:
Mandatory attendance at the briefing and labs, lab reports and written exam
Module Level
MSc EPE
Exam Code
518565
Prerequisites
Master program: Power Lab 1 (EPE)
Examiner Code
18184, 3460, 17492,
20653, 1353, 11894
Type of Examination
written
Duration
Protokolle im
Eigenstudium,
Schriftliche Prüfung 3 h
Semester
M2
Work Load
76 h, davon Präsenz 34 h
Comments
Content / Syllabus
Practical course on power engineering - Distribution and Application. About 50% of the units are devoted to power distribution and high voltage engineering;
About 50% are dealing with application in drive systems, concerning "field-oriented
control" of variable speed drives, encoder sytems, linear permanent magnet
and switched reluctance machines.
Teaching Materialis (1)
Text book Power Lab 2
Electronic Teaching Material
http://www.ew.e-technik.tu-darmstadt.de/
518565
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
page 23
Module Title
Power plants
Energieerzeugung
Module Coordinator
Balzer
Language
German
Credits
4
Course Name
Power Generation
Energieerzeugung
Lecturer
Balzer
Course Code
18710
Teaching Form
V+E
Frequency Offered
SS
Credits
4
Learning Outcomes, Acquired competence:
The goal of the course is to show the relationship between power generation and transmission/distribution.
Auxiliary Studies:
none
Module Level
EES, WI-ET, MSc EPE
Exam Code
118444
Prerequisites
No formal prerequisites.
Examiner Code
3460
Type of Examination
oral
Duration
20 min
Semester
M3
Comments
Content / Syllabus
Overview; basics of thermal operation; steam plants; gas turbines; hydro power; renewable energies; auxiliary substation; system requirements
Teaching Materialis (1)
script
Electronic Teaching Material
www.eev.e-technik.tu-darmstadt.de
118444
Work Load
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Power supply for electric Railways
Energieversorgung elektrischer Bahnen
page 24
Module Coordinator
Zimmert
Language
German
Lecturer
Zimmert
Course Code
18226
Course Name
Power supply for electric Railways
Energieversorgung elektrischer Bahnen
Credits
3
Frequency Offered
WS
Teaching Form
V
Credits
3
Learning Outcomes, Acquired competence:
Understanding of electrical supply systems for railway systems and their applications worldwide.
Auxiliary Studies:
Module Level
MSc ETiT, MSc MEC, MSc EPE, MSc WI-ET
Exam Code
0
Examiner Code
18552
Prerequisites
Bachelor in Electrical Engineering or Mechatronics
Type of Examination
oral
Duration
0.5 h
Semester
M1 oder M2 oder M3
Work Load
50 h, davon 30 h Präsenz
Comments
Content / Syllabus
The Basics and Specialities of Electric Power Supply Systems for Electric Railways are introduced and discussed. An Overview on Concepts of Power Supply for
Heavy- and Light Rail Systems is given. The main Topics of the Lectures are: 1. Comparison of different Power Supply Systems 2. Design of Power Supply
Systems 3. AC - Systems for Heavy Rail 4. DC - Systems for Light- and Heavy Rail 5. Problems of Earthing and earth Return Currents
6. Design of Overhead
Systems considering also High Speed Trains
Teaching Materialis (1)
Detailed textbook; Guckow, A.; Kiessling, F.;Puschmann, R.: Fahrleitungen el. Bahnen, Teubner, Stuttgart, 1997
Schaefer,H.: Elektrotechnische Anlagen für Bahnstrom, Eisenbahn-Fachverlag, Heidelberg, 1981
Electronic Teaching Material
http://www.ew.e-technik.tu-darmstadt.de/
0
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Power system control
Netz- und Stationsleittechnik
page 25
Module Coordinator
Stenzel
Course Name
Power system control
Netz- und Stationsleittechnik
Lecturer
Stenzel
Language
German/English
Credits
4
Frequency Offered
WS
Course Code
18514
Teaching Form
V+Ü
Credits
4
Learning Outcomes, Acquired competence:
The students acquire knowledge over the construction and the facilities of secondary technology in electrical networks and switchgears. They win understanding how
the operation of electrical power systems goes on. They are able to explain the interaction to the different utilities in the European interconnected system.
Auxiliary Studies:
none
Module Level
AET, EES, WI/ETiT/EES, EPE-MSc
Exam Code
118230
Examiner Code
11894
Prerequisites
Power systems I + II
Type of Examination
oral
Duration
30 min
Semester
B
Work Load
Comments
Content / Syllabus
Communication systems: Fibre optics, line carrier systmes, ripple control, SCADA; Substation automation: Automation systems, interlocking devices, IEC 61850;
Control centre: Equipment, load frequency control, scheduling and accounting in transmission systems, cross-border trade; Prerequisites for running a system and
impacts: Grid Code, distributed generation, renewable energies
Teaching Materialis (1)
http://www.eev.e-technik.tu-darmstadt.de/Lehre/Inhalt.php?ID=8&table=Vorlesungen&spr=EN
Electronic Teaching Material
118230
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Power Systems II
Energieversorgung II
page 26
Module Coordinator
Balzer
Language
German
Lecturer
Balzer
Course Code
18801
Course Name
Power Systems II
Energieversorgung II
Credits
4
Teaching Form
V+Ü
Frequency Offered
SS
Credits
4
Learning Outcomes, Acquired competence:
The course/exercise covers the knowledge about operation and design of power systems.
Auxiliary Studies:
none
Module Level
EES, WI-ET, MSc EPE
Exam Code
118226
Prerequisites
Power Systems I
Examiner Code
3460
Type of Examination
oral
Duration
20 min
Semester
M1
Work Load
Comments
prerequisite for the course system protection
Content / Syllabus
behavior of generators; short-circuit calculation;neutral point treatment of m.v. and h.v. systems; insulation co-ordination; system planning, reliability calcuation
Teaching Materialis (1)
script
Electronic Teaching Material
www.eev.e-technik.tu-darmstadt.de
118226
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Practical Training with Drives
Antriebstechnisches Praktikum
page 27
Module Coordinator
Binder
Language
German
Lecturer
Binder, Mutschler
Course Code
18711
Course Name
Practical Training with Drives
Antriebstechnisches Praktikum
Credits
4
Frequency Offered
WS oder SS
Teaching Form
P
Credits
4
Learning Outcomes, Acquired competence:
The students get the ability of measurement for electrical motors, generators and transformers.
Auxiliary Studies:
Mandatory attendance at the briefing and labs, lab reports and written exam
Module Level
MSc ETiT, MSc MEC
Exam Code
518589
Prerequisites
Bachelor of Science in Electrical Engineering, Power Engineering or similar
Examiner Code
18184/1353
Type of Examination
written
Duration
Protokolle im
Eigenstudium,
Schriftliche Prüfung 2 h
Semester
M1 oder M2 oder M3
Work Load
100h, davon 44h Präsenz
Comments
Content / Syllabus
The purpose of this laboratory is gaining extented knowledge about realization and behaviour of drive systems. An introduction in measurement problems concerning
drives is given. The contents of the laboratory is setting drives to work and investigating
drive systems under laboratory conditions. Special attention is paid to inverter-fed AC drives.
Teaching Materialis (1)
Textbook with lab instructions; Nürnberg, W.: Die Prüfung elektrischer Maschinen, Springer, 2000; Leonhard, W.: Control of electric drives, Springer, 2000
Electronic Teaching Material
http://www.ew.e-technik.tu-darmstadt.de/
518589
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Project Seminar Electromagnetic CAD
Projektseminar Elektromagnetisches CAD
page 28
Module Coordinator
Weiland
Course Name
Project Seminar Electromagnetic CAD
Projektseminar Elektromagnetisches CAD
Lecturer
Weiland
Language
German/English
Credits
6
Frequency Offered
WS/SS
Course Code
18110
Teaching Form
S
Credits
6
Learning Outcomes, Acquired competence:
Students will gain experience in the domain of electromagnetic field computations. They will learn how to present scientific results in terms of talks and written
elaborations (paper).
Auxiliary Studies:
Intermediate talk, final presentation.
Module Level
Exam Code
118277
Prerequisites
Desirable:"Computational Electromagnetics and Applications".
Examiner Code
5703
Type of Examination
oral
Duration
30 Minuten
Comments
Content / Syllabus
Work on a small project in numerical field calculation using own software and commercial tools.
Teaching Materialis (1)
Course notes "Computational Electromagnetics and Applications", further material is provided.
Electronic Teaching Material
118277
Semester
M
Work Load
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Quality Management Systems according to ISO-9000 and DIN-ISOIEC-17025 in Test Labs
Qualitätsmanagementsysteme nach ISO-9000, bzw. DIN-ISO-IEC17025 in Prüflaboratorien
Course Name
Quality Management Systems according to ISO-9000 and DIN-ISO-IEC17025 in Test Labs
Qualitätsmanagementsysteme nach ISO-9000, bzw. DIN-ISO-IEC-17025 in
Prüflaboratorien
page 29
Module Coordinator
Pfeiffer
Language
German
Credits
4
Lecturer
Prof. Dr.-Ing. W. Pfeiffer
Course Code
18754
Teaching Form
S
Frequency Offered
SS
Credits
4
Learning Outcomes, Acquired competence:
Basics of quality assurance and its application in test laboratories. Today some knowledge in quality assurance is required for any engineer.
Auxiliary Studies:
Participation in the seminar
Module Level
Diplom ETIT, MSc. ETIT: AET, AUT, DT, EET, NKT,
IMNT, MFT, MEC, MEL, TET; Diplom Wi-ET; MSc
IKT, MSc. IST, MSc. MEC, MSc.
Exam Code
118561
Examiner Code
1468
Prerequisites
Basics of Electrical Engineering
Type of Examination
oral
Duration
30 Minuten
Semester
M2
Work Load
120 h
Comments
Content / Syllabus
The course deals with the influence of quality managment systems on the operation of testlabs in the field of electrical engineering. Special emphasis is given on the
achievement of high quality proof results and the necessary calibration of the test equipment. This also includes methods for the estimation of the measurement
uncertainty. As applicable areas the course will deal with testlabs for electromagnetic compatibility, safety of electrical equipment and high voltage equipment.
Teaching Materialis (1)
Electronic Teaching Material
www.tu-darmstadt.de/etit/fb/et/emt
118561
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Renewable Energies
Regenerative Energien
page 30
Module Coordinator
Hartkopf
Language
English
Lecturer
Hartkopf
Course Code
18720
Course Name
Renewable Energies
Regenerative Energien
Credits
4
Frequency Offered
WS
Teaching Form
V+Ü
Credits
4
Learning Outcomes, Acquired competence:
survey on functionality and application area for renewable energy converters, analysis of potential of renewable energy sources, ecological consciousness
Auxiliary Studies:
none
Module Level
B1xx (AUT, EES, AET), B2xx (all others) M2xx (all),
EES 250, M-EPE110, AET 230, AET314, Wi/ET(EES)
310, Wi/ET(EVT) 421, AUT 324
Exam Code
118030
Examiner Code
17492
Prerequisites
mathematics, physics
Type of Examination
written/oral
Duration
90+15 Minuten
Semester
B5, M1, M3
Work Load
150
Comments
Advice: Place at the end of bachelor, knowledge of physics necessary
Content / Syllabus
Physical and technical fundamentals of renewable energy technologies: wind turbines, photovoltaics, solar thermal systems, geothermal, hydro electricity. Future
potential for use of renewable energy under technical and economical aspects
Teaching Materialis (1)
Course notes available for purchase in FG office
Electronic Teaching Material
http://www.re.e-technik.tu-darmstadt.de
118030
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Software Lab Computational Electromagnetics and Applications
Softwarepraktikum zu Verfahren und Anwendungen der
Feldsimulation
page 31
Module Coordinator
Weiland
Language
German
Lecturer
Weiland
Course Code
18156
Course Name
Software Lab Computational Electromagnetics and Applications
Softwarepraktikum zu Verfahren und Anwendungen der Feldsimulation
Credits
6
Teaching Form
P
Frequency Offered
SS
Credits
6
Learning Outcomes, Acquired competence:
Students will understand basic concepts of numerical solution techniques to field problems related to different physical domains. They will exhibit the ability to write
small simulation programs in Matlab.
Auxiliary Studies:
Written elaborations to the prior lab must be submitted before next next lab.
Module Level
Exam Code
118276
Prerequisites
Desirable: "Computational Electromagnetics and Applications" (also in parallel).
Examiner Code
5703
Type of Examination
oral
Duration
30 Minuten
Semester
M
Work Load
Comments
Content / Syllabus
Various topics are: 1. Introduction, 2. Basics of FIT I, 3. Basics of FIT II, 4. Static problems (electrical/magnetical) (scalar potential), 5. Magnetostatic problems,
frequency domain, 5. Time domain integration techniques: Leapfrog I, 7. Time domain integration techniques: Leapfrog II, 8. Other physical problems: heat
conduction, 9. Other discretization methods: Finite Element Method.
Teaching Materialis (1)
Course notes will be provided.
Electronic Teaching Material
118276
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Standardization, Testing and Approvals in the Elctrotechnical Area
Normen-, Prüf- und Zulassungswesen in der ETiT
page 32
Module Coordinator
Mutschler
Language
German
Lecturer
Dreger
Course Code
0
Course Name
Standardization, Testing and Approvals in the Elctrotechnical Area
Normen-, Prüf- und Zulassungswesen in der ETiT
Credits
3
Teaching Form
V
Frequency Offered
SS
Credits
3
Learning Outcomes, Acquired competence:
Auxiliary Studies:
Module Level
BSc ETiT, MSc ETiT
Exam Code
518405
Prerequisites
Examiner Code
5683
Type of Examination
oral
Duration
30 Minuten
Semester
M
Work Load
Comments
The lecture is supplemented by a half-day excursion to the VDE Testing and Certification Institute of the VDE Association of Electrotechnology, Electronics,
Information Technology located at 63069 Offenbach, Merianstr. 28. Tel. +49 (0)69 83 06-0, Fax +49
Content / Syllabus
In the European Union (EU), the fundamental requirements for electrical equipment, such as safety and electromagnetical compatibility (EMC) including
functionality, are stipulated in EC Directives and by national implementation in laws and decrees. These requirements take shape in harmonized standards. The
manufacturer or his authorized agent resident in the EU or, as the case may be, the user of the equipment has to show compliance with the requirements by means of own tests or - tests carried out by an independent neutral testing laboratory. During the lecture, these critera are considered with respect to the following topics: Appliance and product safety law (GPSG) - Energy promotion law (EnWG) - Law on electromagnetical compatibility of equipment (EMVG) - Telecommunications
law (TKG) - X-ray decree (RöV) - Explosion-protection decree - Calibration decree - Standardization by the German Electrotechnical Commission of DIN and VDE
(DKE) - Standardization: - in Europe by CENELEC (= European Committee of Electrotechnical Standardization) - worldwide by IEC (= International
Electrotechnical Commission).
Teaching Materialis (1)
Warner, A.: Jahrbuch zum VDE-Vorschriftenwerk, Berlin: VDE-VERLAG, since 1986 annually until to-day; see there especially the chapters "Documentation" and
"Original versions of new legal acts"; Barz: EG-Niederspannungs-Richtlinie, Berlin: VDE-VERLAG, 1997. (EC Low voltage Directive)
Electronic Teaching Material
518405
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
System Dynamics and Automatic Control II
Systemdynamik und Regelungstechnik II
page 33
Module Coordinator
Adamy
Language
German
Lecturer
Adamy
Course Code
18114
Course Name
System Dynamics and Automatic Control II
Systemdynamik und Regelungstechnik II
Credits
6
Teaching Form
V+Ü
Frequency Offered
SS
Credits
6
Learning Outcomes, Acquired competence:
1) construct and evaluate the root locus of given systems, 2) describe the concept and importance of the state space for linear systems, 3) define controllability and
observability for linear systems and be able to test given systems with respect to these properties, 4) state controller design methods using the state space and be able to
apply them to given systems, 5) apply the method of linearization to non-linear systems
Auxiliary Studies:
none
Module Level
MSc ETiT, ETIT, MSc ICE, MSc IKT
Exam Code
118451
Examiner Code
18779
Prerequisites
System Dynamics and Control Engineering I
Type of Examination
written
Duration
180 min.
Semester
B6
Work Load
180
Comments
Content / Syllabus
Main topics treated are: 1. Root locus method (Construction and application), 2. State space representation of linear systems (Representation, Time Solution,
controllability, observability, obserber-based controller design)
Teaching Materialis (1)
Systemdynamik und Regelungstechnik II - Shaker Verlag - Available for purchase at the FG office
Electronic Teaching Material
www.rtr.tu-darmstadt.de/lehre/e-learning (optionales Material)
118451
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
System Protection
Netzschutz
page 34
Module Coordinator
Balzer
Language
German
Lecturer
Balzer
Course Code
18713
Course Name
Power System Protection
Netzschutz
Credits
4
Teaching Form
V+Ü
Frequency Offered
WS
Credits
4
Learning Outcomes, Acquired competence:
The course covers the knowledge about design of protection system.
Auxiliary Studies:
none
Module Level
EES, WI-ET, MSc EPE
Exam Code
118547
Prerequisites
Power Systems I and II
Examiner Code
3460
Type of Examination
oral
Duration
20 min
Comments
Content / Syllabus
Basics, failure detection criteria; instrument transformers; application, digital protection; overvoltage protection
Teaching Materialis (1)
script
Electronic Teaching Material
www.eev.e-technik.tu-darmstadt.de
118547
Semester
M3
Work Load
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Transients in power systems
page 35
Module Coordinator
Stenzel
Language
German /
English
Credits
8
Lecturer
Stenzel
Course Code
18141
Frequency Offered
WS/SS
Transiente Vorgänge in Energieversorgungsnetzen
Course Name
Transients in power systems
Transiente Vorgänge in Energieversorgungsnetzen
Teaching Form
V+S
Credits
8
Learning Outcomes, Acquired competence:
The students acquire the ability to calculate transient events in networks, to judge the consequences and to interpret the results for planning with the help of a large
program system.
Auxiliary Studies:
none
Module Level
AET, EES, WI/ETiT/EES, EPE-MSc
Exam Code
118518
Examiner Code
11894
Prerequisites
Power systems I + II
Type of Examination
oral / presentation
Duration
30 min
Semester
M
Work Load
Comments
Prerequisite for studies and master theses/Diplomarbeiten
Content / Syllabus
After an introduction lecture into the field of transients in power systems and the program package the students are given individual little projects. The subjects can
deal with: Impact of surges in powr systems (Traveling wave phenomena), switching overvoltages, use of overvoltage diverters, impact of short-circuit currents,
dynamic and transient stability.
Teaching Materialis (1)
script in the Web
Electronic Teaching Material
118518
Module Information Master of Science Electrical Power Engineering (Rel. 1.1; 15.01.2008)
Module Title
Wind Turbines
Windkraftanlagen
page 36
Module Coordinator
Hartkopf
Language
German
Lecturer
Hartkopf
Course Code
18711
Course Name
Wind Turbines
Windkraftanlagen
Credits
4
Teaching Form
V+Ü
Frequency Offered
SS
Credits
4
Learning Outcomes, Acquired competence:
survey on functionality and application area for wind power plants, analysis of potential of renewable energy sources, ecological consciousness
Auxiliary Studies:
none
Module Level
Mxxx, B-EPE140, EES 320, M-EPE210, Wi/ET(EES) 322
Exam Code
118037
Examiner Code
17492
Prerequisites
"Renewable Energies" recommended
Type of Examination
oral
Duration
15 Minuten
Semester
M2, M4
Work Load
150
Comments
Extension of "Renewable Energies", integration in Bachelor not recommended.
Content / Syllabus
Potentials of wind energy, wind generation, physics of wind conversion, wind production and energy, construction of wind turbines, generator systems for wind
turbines, control of wind turbines, grid connection of wind turbines, upscaling of wind turbines
Teaching Materialis (1)
Course notes available for purchase in FG office
Electronic Teaching Material
http://www.re.e-technik.tu-darmstadt.de
118037