MODULE DESCRIPTION - TU · MODULE DESCRIPTION Master Programme ... BIOMASS AND BIOGAS CO-GENERATION I ... Biomass integrated gasifier combined cycle

Fakultät 3

Maschinenbau, Elektrotechnik und Wirtschaftsingenieurwesen

MODULE DESCRIPTION

Master Programme

Power Engineering

12.08.2014

2

LIST OF CONTENTS

AUXILIARY POWER SUPPLY OF THE POWER PLANT ....................................................................... 3

BASICS IN GRID CALCULATION ....................................................................................................................... 4

BIOMASS AND BIOGAS CO-GENERATION I .............................................................................................. 5

BIOMASS AND BIOGAS CO-GENERATION II ............................................................................................ 6

CARBON CAPTURE AND STORAGE (CCS) ............................................................................................... 7

CONTROL ENGINEERING .................................................................................................................................... 8

EMC IN ELECTRICAL POWER INSTALLATIONS ..................................................................................... 9

ENERGY INFORMATION SYSTEMS .............................................................................................................. 10

FUNDAMENTALS IN POWER ELECTRONICS ......................................................................................... 11

FUNDAMENTALS IN THERMAL PROCESS ENGINEERING ............................................................ 12

FUTURE TECHNOLOGIES IN POWER PLANTS ..................................................................................... 14

HIGH VOLTAGE ENGINEERING AND INSULATING MATERIALS ................................................ 15

HIGH VOLTAGE MEASURING AND TESTING TECHNIQUE ............................................................ 16

INTERNATIONAL MANAGEMENT ................................................................................................................... 17

INTRODUCTION IN ELECTRICAL POWER ................................................................................................ 18

MEDIUM- AND LOW-VOLTAGE TECHNOLOGY ..................................................................................... 19

NATURAL GAS ........................................................................................................................................................... 20

PHOTOVOLTAICS: BASICS, STATE-OF-THE-ART, AND SOLAR CELL MATERIALS

RESEARCH .................................................................................................................................................................. 21

POWER AUTOMATION ......................................................................................................................................... 22

POWER ELECTRONIC APPLICATIONS IN DRIVE SYSTEMS ........................................................ 23

POWER ELECTRONIC APPLICATIONS IN HIGH VOLTAGE GRID .............................................. 24

POWER PLANT TECHNOLOGY 1 ................................................................................................................... 25

POWER PLANT TECHNOLOGY 2 ................................................................................................................... 26

POWER QUALITY AND INDUSTRIAL ECOLOGY FOR SMART MANUFACTURING .......... 27

POWER SYSTEM ECONOMICS I .................................................................................................................... 28

POWER SYSTEM ECONOMICS II ................................................................................................................... 30

POWER SYSTEM OPERATION ........................................................................................................................ 31

RENEWABLE ENERGY TECHNOLOGIES FOR ELECTRICAL POWER SUPPLY ................ 32

SELECTED CHAPTERS IN TECHNICAL COMBUSTION: ................................................................... 33

SIGNAL PROCESSING AND OPTIMIZATION METHODS IN DATA MINING ............................ 35

SOLAR ENERGY MATERIALS RESEARCH & SOLAR CELLS ........................................................ 37

SUSTAINABLE USE OF UNDERGROUND RESOURCES; GEOTH. EN. A. CO2 STOR .... 38

SWITCHING TECHNOLOGIES .......................................................................................................................... 39

THERMAL PROCESS ENGINEERING .......................................................................................................... 40

TECHNOLOGY AND OPERATION OF WIND TURBINES ................................................................... 41

TECHNICAL COMBUSTION ................................................................................................................................ 42

WIND ENERGY ECONOMICS, WIND RESOURCES ESTIMATION .............................................. 44

3

Auxiliary Power Supply of the Power Plant: Module 11199

Modultitel / Module title (deutsch) Elektrische Eigenbedarfsversorgung von Kraftwerken

Fakultät / Faculty 3

Verantwortliche/r / Responsible staff member: Dr. Klaus Pfeiffer

Kreditpunkte / Credits: 6

Lehrsprache / Language of teaching: English

Angebotsturnus / Frequency of offer: Each summer semester

Dauer / Duration: One semester

Empfohlen für Studienphase / Recommended placement in the study plan:

Master, 2nd year of studies

Lehrformen und deren Anteil am Gesamtumfang / Forms of teaching and proportion:

Vorlesung/Lecture: 2 SWS

Übung/Exercise: 2 SWS

Selbststudium/Self-organised

studies:

120 h Angabe immer in Stunden, nie

SWS

Lernziele / Learning outcome:

Students will get a deep overview about auxiliary networks in power plants.

Inhalt / Contents:

Requirements to the auxiliary system;

Basic layout, voltage levels and rating depending on power plant type and generator

capacity;

Redundancy concepts;

DC power supply and uninterruptible power supply concepts, emergency generators;

M.V.- and L.V.-switchgears in auxiliary networks including transformers, drives, adjustment

drives;

Selective protection in auxiliary networks;

Active and reactive power control of generators, frequency control, static and dynamic

stability, generator protection;

Transfer concepts

Unterrichtsmaterialien und Literaturhinweise / Teaching materials and literature:

Script

Zu erbringende Prüfungsleistungen / Assessment mode:

1 written examination of 90 min.

Empfohlene Voraussetzungen / Recommended prerequisites:

Basic understanding in electrical engineering

Medium- and Low-Voltage Technology

Zwingende Voraussetzungen / Mandatory prerequisites:

Bemerkungen / Remarks:

Veranstaltungen zum Modul / Module components:

4

Basics in Grid Calculation: Module 11198

Modultitel / Module title (deutsch) Grundlagen der Netzberechnung








Master, 1st year of studies





studies:

120 h Angabe immer in Stunden, nie

SWS


Students will get the basics in grid calculation as well as an overview about the methods of

calculation for short-circuit currents and power flow.

Inhalt / Contents:

Symmetrical and asymmetrical three-phase system;

Transformation methods with focus on symmetrical components;

Neutral point treatment;

Symmetrical impedances and equivalent circuits;

Calculation of asymmetrical fault currents;

Nodal voltage method;

Mesh-current method;

Overview about software solutions in the field of grid calculation;

Diverse exercises for manual calculations for given grid layouts


Script, reference books about power supply (Herold)


1 written examination, 90 min


Module “Medium- and Low-Voltage Technology”




5

Biomass and Biogas Co-Generation I : Module 11218

Modultitel / Module title (deutsch) Biomasse und Biogas Kraft-Wärme-Kopplung (KWK) I

Fakultät / Faculty 3- Maschinenbau, Elektrotechnik und Wirtschaftsingenieurwesen/

Mechanical Engineering, Electrical Engineering and Industrial Engineering

Verantwortliche/r / Responsible staff member: Prof.. Dr.-Ing. Daniel Seibt



Angebotsturnus / Frequency of offer: jedes Wintersemester / each winter semester

Dauer / Duration: ein Semester / one semester


Master 1. Studienjahr / Masters 1st year course



Selbststudium/Self-organised studies: 120 h


The students will:

get a deep knowledge about the different biomass fuels and their thermophysical properties

understand the different thermochemical conversion techniques of biomass

acquire a deep understanding of the different biofuels and biogas production and their applications

understand the steam cycles used in biomass cogeneration plants

Inhalt / Contents:

Types and sources of biomass fuels; Photosynthesis and the carbon cycle; Organic biofuel

plants and crops; Physical and thermal properties of biomass fuels; Solid biomass, pelleting

and briquetting; Thermochemical conversion of biomass(Combustion, Gasification,

Pyrolsis); Biochemical conversion (Digestion, Fermentation); Biogas; Biogas anaerobic

digestion; Types of Biogas reactor or digester, design and construction features; Utilization

and application of biogas; Alternative liquid fuels; Bioethanol production and its application;

Biodiesel Production and its application; Thermodynamic cycles and engines for biomass

power generation; The organic Rankine cycle, The Stirling engine, Reciprocating engine;

Biomass small scale combined heat and power plants; Municipal Solid waste


Lecture slides will be available


Written examination, 120 min


Basic of Thermodynamics




Energy from Biomass I (Lecture)

6

Biomass and Biogas Co-Generation II : Module 11219

Modultitel / Module title (deutsch) Biomasse und Biogas Kraft-Wärme-Kopplung (KWK) II






Angebotsturnus / Frequency of offer: jedes Sommersemester / each summer

semester






Übung/Exercise 1 SWS



The students will:

get a deep understanding of solid biomass conversion and utilization using direct firing, co-firing and gasification.

able to perform combustion calculation for solid biomass

acquire understanding of the biomass based industrial scale power plants and small scale modular combined heat and power (CHP) systems

understand the different technologies for biomass firing and gasification

Inhalt / Contents:

Direct combustion of biomass; Combustion technologies of biomass for power generation;

Fixed bed and fluidized bed combustion technologies; Biomass power generation and co-

generation; Biomass co-firing; Biomass gasification; Gasification systems and technologies;

Biomass integrated gasifier combined cycle (BIGCC); Ash formation and handling;

Environmental issue of biomass power plants






Basic of Thermodynamics, Heat transfer, Fluid mechanics




Energy from Biomass II (Lecture and Exercise)

7

Carbon Capture and Storage (CCS): Module 11200

Modultitel / Module title (deutsch) CO2-Abscheidung und -Speicherung






Angebotsturnus / Frequency of offer: jedes Wintersemester / each winter semester








Students will acquire a deep understanding of the different technologies of carbon dioxide

capture and storage system.

Inhalt / Contents:

Properties of Carbon dioxide; Emission sources of CO2 and emission trends; Options for

mitigating CO2 emissions; Post-combustion capture; Pre-combustion capture; Oxy-fuel

combustion; Emerging technologies for CO2 capture (Chemical looping combustion,

Oxyfuel combustion with oxygen transport membrane) ; CO2 compression and transport;

CO2 storage; Economic and Social aspect of CO2 storage






Basic of thermodynamics, Energy conversion and utilization, Fuel combustion




Carbon Capture and Storage (Lecture)

8

Control Engineering : Modul 35-2-06

Langtitel/Long title: Control Engineering / Regelungstechnik

Fachgebiet/Scientific field: Elektrotechnik

Modulverantwortliche/r Responsible staff member:

Prof. Dr. Gerhard Lappus

Sprache/Language of teaching:

Englisch

Angebotsturnus/Frequency of offer:

jedes Sommersemester / each summer semester

Dauer/Duration: ein Semester / one semester

Lehrformen und deren Anteil am Gesamtumfang/Forms of teaching and proportion:

Übung / exercise 2 SWS

Selbststudium / self organised studies 120 Stunden gesamt

Vorlesung / lecture 2 SWS

Kreditpunkte/Credits: 6

Studiengänge/Courses of study:

Environmental Technologies/M.Sc. Process Engineering & Plant Design/M.Sc.

Lernziele/Learning outcome: Students are enabled to understand the basic feedback control principle and to apply it to simple problems. Students should acquire basic knowledge to model and analyse simple dynamic systems and to design simple control systems.

Inhalt/Contents: System properties: linear and time invariant systems, mathematical description of dynamic systems: linearization, linear differential equations with constant coefficients, models of first and second order, step response, LAPLACE transform and transfer function, analysis of signal flows and block diagrams, frequency response, stability.Feedback control: standard feedback control schemes, PID-controller, basic design procedures, Ziegler-Nichols-tuning of PID-controllers, control design using BODE plots, computer based design with MATLAB.

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: Scripts and worksheets for the lectures and exercises and the following books: G. F. Franklin, J. D. Powell, A. Emami-Naeini: Feedback Control of Dynamic Systems. Addison-Wesley Publishing Company. R. C. Dorf, R. H. Bishop: Modern Control Systems. Addison-Wesley Publishing Company.

Zu erbringende Leistungen/Assessment mode: Written examination (90 minutes): students have to solve problems of modelling and designing simple feedback control systems.

Voraussetzungen/Prerequisits: Mathematics and Physics

Bemerkungen/Remarks: Mandatory module no. BA-0302 in the ERM Bachelor programme module no. 3 “Engineering Sciences” (bisher 5,5 Credits)

9

EMC in Electrical Power Installations : Module 11191

Langtitel/Long title: EMC in Electrical Power Systems

Fachgebiet/Scientific field: Energietechnik


Prof. Dr. Harald Schwarz


Englisch


jedes Wintersemester / each winter semester



Seminar 2 SWS

Lecture 2 SWS




Power Engineering/M.Sc. Wirtschaftsingenieurwesen/Diplom

Lernziele/Learning outcome: Students will get a deeper understanding of possible interferences in power systems and will be able to design a EMC compatible layout in large scale power installations and systems

Inhalt/Contents: Electromagnetic environment (high frequency impulse fields, lightning impulse overvoltages, switching impulses, low and medium frequency interferences), EMC design criteria (protection against direct lightning stroke, potential grounding, screening, overvoltage protection,filters), EMC system planning (zone concept, interface definition) EMC measuring and testing technique

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: Script

Zu erbringende Leistungen/Assessment mode: Written examination 90 min or verbal examination 30 min

Voraussetzungen/Prerequisits:

Bemerkungen/Remarks: The seminar will include exercises, practical training and homeworks

10

Energy Information Systems: Modul 35-4-13

Langtitel/Long title: Energy Information Systems / Energie

Informationssysteme


Modulverantwortliche/r

Responsible staff member: Prof. Dr. Harald Schwarz

Sprache/Language of

teaching: Englisch

Angebotsturnus/Frequency

of offer: jedes Wintersemester / each winter semester

Dauer/Duration: zwei Semester / two semesters


Vorlesung / lecture 60 Stunden gesamt



Studiengänge/Courses of

study:

Electrical Power Engineering/M.Sc.

Elektrotechnik/B.Sc.

Elektrotechnik/M.Sc.

Power Engineering - PO 2008

Wirtschaftsingenieurwesen/Diplom

Wirtschaftsingenieurwesen/M.Sc. - PO 2008

Lernziele/Learning outcome:

Students will get a knowledge in the structure- und process optimized information

systems in the energy sector

Inhalt/Contents:

Structures and processes in the energy supply, information requirements, basic data

and data exchange, data models, company wide integration, communication,

automation, office integration, standard architecture, CIM-data model etc., functional

moduls, architecture und workflow

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature:

Basics of information processing, relevant standards, “Information Technology for

Energy Managers” by Barney Capehart/Uni Florida, The Fairmont Press Inc. 2004

Zu erbringende Leistungen/Assessment mode:

Two written examination, 90 min or two verbal examination, 30 min

Voraussetzungen/Prerequisites:

Bemerkungen/Remarks:

Lecturer Dipl.-Ing. Johann Pohany

The lecture will be organized as a one week block seminar in each of the semesters.

The script will be handed out in advance and it will be expected that the students will

prepare the block seminar by self organized studies

11

Fundamentals in Power Electronics : Modul 35-4-38

Grundlagen der Leistungselektronik



Prof. Seyed-Mohsen Hosseini


Englisch










Lernziele/Learning outcome: Students learn to understand the functional principle of power electronics, their specific components, control structures and the characteristic behaviour. They are able to find suitable concepts and define components and auxiliaries for power converters.

Inhalt/Contents:

definition of power electronics

components and their static and transient behaviour

circuit topologies as grid commutated converter

self commutated converter

dc-dc-converter

resonant and quasi-resonant converter

single and three phase applications

characteristic values of components and topologies

cooling

passive components and filters

firing

driver and protection devices

pulse-width-modulation

simulation tools

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: will be given in lecture

Zu erbringende Leistungen/Assessment mode: written examination, 90min

Voraussetzungen/Prerequisits: Fundamental lecture: Electrical Engineering


12

Fundamentals in Thermal Process Engineering : Modul 44-4-30

Langtitel/Long title: Grundlagen der Thermischen Verfahrenstechnik

Fachgebiet/Scientific field: Verfahrenstechnik


Responsible staff member: Prof. Fabian Mauß

Sprache/Language of

teaching: Englisch


of offer: winter semester 1 or 3








study:

Environmental Technologies/M.Sc.

Process Engineering & Plant Design/M.Sc.


In the module the fundamentals of engineering thermodynamics will be introduced

and applied to problems of energy conversion. This also includes equilibrium

thermodynamics of ideal mixtures. Furthermore the fundamentals of heat and mass

transfer will be teached. Both beeing important in many technical processes within

energy conversion and chemical engineering. Upon successful completion of this

course, students will have gained working knowledge of basic properties of

thermodynamic systems, processes and cycles. Simple heat transfer problems can

be solved using either similarity correlations or analytical solutions. The analogy

between heat and mass transfer will be understood. The knowledge in

thermodynamics and heat and mass transfer will be applied to distillation and

rectification processes.

Inhalt/Contents:

- properties of thermodynamic systems

- first and second law of thermodynamics

- ideal gas law and changes in state of ideal gases

- mixtures of ideal gases, humid air

- phase equilibrium vapour-liquid of ideal mixtures

- conservation of mass, species and energy

- fundamentals of heat transfer (conduction, convective heat transfer, radiation)

- fundamentals of mass transfer (diffusion, convective mass transfer)

- distillation and rectification


Teaching materials:

13

- lecture handouts, formulary, exercise materials

Literature:

- Sonntag, Richard Edwin; Borgnakke, Claus: Fundamentals of thermodynamics.

Wiley, New York 2003.

- Moran, Michael J.; Shapiro, Howard N.: Fundamentals of engineering

thermodynamics. Wiley, Chichester 2006.

- Incropera, Frank P., De Witt, David P.: Fundamentals of heat and mass transfer.

Wiley, New York 2002.

- Baehr, Hans Dieter; Stephan, Karl: Heat and mass transfer. Springer, Berlin 2006.

- Coulson, John M.: Coulson & Richardson's chemical engineering volume 2.

Butterworth-Heinemann, Oxford 2002.

- Felder, Richard M.; Rousseau, Ronald: Elementary principles of chemical

processes. Wiley, New York 2000.

- Seader, J. D.; Henley, E.J.: Separation Process Principles. Wiley-VCH, Chichester

2006.


- 2 attestations during the semester (each with 15 % of final grade)

- written final examination (70 % of final grade)


knowledge in mathematics, physics


This module is offered in WS 14/15, 16/17, 18/19

14

Future Technologies in Power Plants: Module 11220

Modultitel / Module title (deutsch) Zukunftstechnologien in Kraftweken



Verantwortliche/r / Responsible staff member: Prof. Przemyslaw Janik



Angebotsturnus / Frequency of offer: jedes Sommersemester / each summer

semester



Master 2. Studienjahr / Masters 2nd year course


Seminar/Seminar: 4 SWS



Students will acquire knowledge about emerging technologies in power generation. They

will be able to identify the need and trend of future power plant technologies in relation to

the environmental issues and economic aspect.

Inhalt / Contents:

Supercritical and Ultra-supercritical steam power plants; Boiler and Steam turbine Materials

for high pressure and temperature applications; Integrated Gasification Combined Cycle

(IGCC); Indirect fired combined cycle; Magnetohydrodynamics (MHD); Emerging Coal

Combustion technologies (pressurized fluidized bed combustion, oxy fuel combustion and

chemical looping combustion); Advanced gas turbine and gas-steam combined cycles;

Solar-steam turbine hybrid power plants; solar-gas turbine hybrid power plants ; Energy

storage (Battery, Compressed air)



Homework: Written report on a given topic (< 30 pages)

Presentation and discussion of the topic in class (45 minutes)

The final mark is based on the report (75%) and the presentation (25%).


Basic of Thermodynamics, Energy resources and conversion, Heat transfer, Fluid

mechanics


Power plant Technology I


The contents of the course are not limited to the topics listed above. Based on the

developments of new technologies, additional topics can be added whenever deemed

necessary.


Future Technologies in Power Plants (seminar)

15

High Voltage Engineering and Insulating Materials : Modul 35-4-34

Langtitel/Long title: High Voltage Engineering and Insulating Materials





Englisch





Seminar 2 SWS






Lernziele/Learning outcome: The students will get a detailled knowledge in high voltage engineering and insulating materials including the relevant electric field calculations and breakdown mechanisms.

Inhalt/Contents: Electric field strength, surface charges, dielectricas discharges and breakdowns in gases, liquid and solid insulators. Processing and material prameters of technical insulating materials.

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: skript, hand out for lab experiments

Zu erbringende Leistungen/Assessment mode: written test, 90 min or oral test, 30 min


Bemerkungen/Remarks: The lecture and seminar will be offered by an external lecturer- Dr.-Ing. Löhning

16

High Voltage Measuring and Testing Technique : Modul 35-4-10

Langtitel/Long title: High Voltage Measuring and Testing Technique





Englisch





Seminar 2 SWS





Electrical Power Engineering/M.Sc. Elektrotechnik/M.Sc.

Wirtschaftsingenieurwesen/Diplom

Lernziele/Learning outcome: Students will get a detailed knowledge in measuring and testing circuits and equipment with special respect to high voltage applications and will practise their knowledge in several high voltage lab experiments.

Inhalt/Contents: AC, DC and impulse generators with Marx-generator or transformers, oscillating impulse generation, EMP- and cable generators, high current sources, resistive or capacitve dividers, response time, band width, earth capacitance, measuring cables, digital and analog oszilloscopes, rogowski-coils, hall-sensors, shunts, optical voltage and current sensors, dielectric measurements, partial discharge detection

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: Skript

Zu erbringende Leistungen/Assessment mode: Written test, 90 min or Oral test, 30 min


Bemerkungen/Remarks: The seminar will be organized as a mixture of exercises, practical training and home work. The lecture will be offered by Dr.-Ing. habil. Dr. h.c. Wolfgang Hauschild.

17

International Management : Modul 35-4-43

Langtitel/Long title: International Management



Prof. Dr. Harald Fien


Englisch









Lernziele/Learning outcome: Students will get a principle understanding about management processes with special respect to international economical relations.

Inhalt/Contents: • Basics of management • Management tools • Strategic planning • Projectmanagement • International economic problems • Organisation of international companies • Personnel development • Global marketing • Supply chain management • International management of technologies & innovations • Controlling of multinational corporations • Intercultural relations

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: Literature references will be provided before lecture starts.

Zu erbringende Leistungen/Assessment mode: Written examination, 90 min or verbal examination, 45 min


Bemerkungen/Remarks: The lecture will be organized as a one week block seminar in each of the semesters

18

Introduction in Electrical Power: Modul 11196

Langtitel/Long title: Introduction in Electrical Power Systems





Englisch






Übung/ exercise 2SWS




Electrical Power Engineering/M.Sc.

Lernziele/Learning outcome: Students will get a basic understanding in electrical power engineering with special reflection on the situation during normal or fault operation

Inhalt/Contents: Basics in single phase and three phase systems, conventional power plants, generators, transformers, operation under normal and fault conditions, overvoltages

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: script


Voraussetzungen/Prerequisits: Basic understanding in electrical engineering

Bemerkungen/Remarks: The lecture will give a short introduction to students with bachelor degrees in electrical engineering (or others), who had no subjects in electrical power engineering in their undergraduate programmes

19

Medium- and Low-Voltage Technology: Module

Modultitel / Module title (deutsch) Betriebsmittel der Mittel- und Niederspannungtechnik





Angebotsturnus / Frequency of offer: Each winter semester








studies:

120 h


The focus of this lecture is on design, parameters and rating of equipment in M.V.- and

L.V.-level.

Inhalt / Contents:

Transformers;

Switchgears;

Substations;

Cables and overhead lines;

Switching devices;

Basics in symmetrical fault calculation;

Calculation of relevant stress parameters to the equipment;

Project work (including s.c.-calculation, cable selection and rating of switchgears)


Script


1 written examinations, 90 min


Module „Introduction in Electrical Power“




20

Natural Gas : Modul 35-5-07

Langtitel/Long title: Natural Gas (resources, usage, technology) / Erdgas



Prof. Dr. Gerhard Lappus


Englisch





Seminar 4 SWS




Lernziele/Learning outcome: Akquisition of basic knowledge about natural gas as world-wide important source of primary energy and related technologies; self-organised collection and evaluation of data covering a special topic; presentation and discussion.

Inhalt/Contents: Natural gas worldwide; natural gas reserves and production; gas transport and transmission pipelines; regional gas distribution pipeline networks; technology (pipeline, undergrund storage, compressor station, regulator station), supervision and control of high pressure gas pipeline networks.

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: Partial script material; seminar presentations and discussions

Zu erbringende Leistungen/Assessment mode: - Homework: Written report on a given topic (25 pages) - Presentation and discussion of the topic in class (30 minutes) The final mark is based on the report (75%) and the presentation (25%).



21

Photovoltaics: Basics, State-of-the-Art, and Solar Cell Materials Research:

Module 11222

Modultitel / Module title (deutsch) Phtovoltaik (PV): Grundlagen, Stand der Technik und PV-

Materialforschung


Verantwortliche/r / Responsible staff member: Dr.-Ing. Marcus Bär


Lehrsprache / Language of teaching: Englisch

Angebotsturnus / Frequency of offer: On spezial announcement








studies:

120 h


Students will get an introduction into photovoltaics; including the basics of the fundamental

principles of operation and fabrication of solar cells. Furthermore, current PV technology

trends and materials research towards new concepts will be discussed.

Inhalt / Contents:

(1) Solar insolation: Energy source for PV (2) Crash course in semiconductor physics: (a)

absorption, (b) electrons and holes in semiconductors, (c) generation, transport and

recombination of charge carriers, (d) p-n junction under illumination. (3) Photovoltaic

technologies (Si-wafer based vs. Thin-film PV). (4) Solar cell materials research.


Copies of viewgraphs will be made available. Suggested literature: [1] A.L. Fahrenbruch, R.

H. Bube, “Fundamentals of Solar Cells”, Academic Press, New York – London, 1983, [2]

H.J. Möller “Semiconductors for Solar Cells”, Artech House, Boston – London, 1993, [3]

S.M. Sze, Chapter 14 in “Physics of Semiconductor Devices”, John Wiley & Sons, New

York, 1981.


written examination, 90 min


Fundamental knowledge in physics and engineering

(after introductory study period / nach dem Grundstudium)



Compulsory module for area ‘Applied Physics’ in the study programme Physics M.Sc.


22

Power Automation : Modul 35-4-09

Langtitel/Long title: Power Automation



Honorarpro Siegfried Lemmer


Englisch






Vorlesung/Seminar 4 SWS



Electrical Power Engineering/M.Sc. Elektrotechnik/B.Sc.

Elektrotechnik/Diplom Elektrotechnik/M.Sc.

Lernziele/Learning outcome: Students will get understanding of power network protection systems and will be able to design own basic layouts

Inhalt/Contents: protection concepts, device engineering, settings, communication, requirements, algorithms, hard ware concepts, new technologies

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: Script

Zu erbringende Leistungen/Assessment mode: Two written examination, a 90 min or two verbal examination, a 30 min


Bemerkungen/Remarks: The lecture will be organized as a one week block seminar in each of the semesters. The script will be handed out in advance and it will be expected that the students will prepare the block seminar by self organized studies

23

Power Electronic Applications in Drive Systems : Modul 35-4-37

Langtitel/Long title: Power Electronic Applications in Drive

Systems/Leistungselektronik in Antriebssystemen





Englisch










Lernziele/Learning outcome: Students learn the specific items of power electronics in drive applications. They know the typical topologies, power circuit and control structures and can rate and design a drive converter.

Inhalt/Contents: Current and voltage source inverter systems, cycloconverter; converter and control design for dc drives, reversing operation dc drives, three-phase asynchronous and synchronous drives, multiphase switched reluctance drives, drives with recuperation; pulse-width-modulation for drive converter; dimensioning of converter systems



Voraussetzungen/Prerequisits: Basics in Power Electronics, Electrical Machines, Control Engineering


24

Power Electronic Applications in High Voltage Grid : Modul 35-4-36

Langtitel/Long title: Power Electronic Applications in High Voltage

Grid/Leistungselektronik in Hochspannungsanlagen





Englisch










Lernziele/Learning outcome: Students get a deeper view into the specific items of power electronics devices in grid use. They know typical components, applications and control strategies for designing and use of devices in higher voltage and power levels.

Inhalt/Contents: High voltage and high current power electronics components; cooling principles; serial and parallel connection of components; multiphase and multilevel converter topologies; control structures for grid connection and parallel operation; applications like HVDC and frequency converters;



Voraussetzungen/Prerequisits: Basics in Power Electronics, Control Engineering


25

Power Plant Technology 1 : Modul 35-4-49

Langtitel/Long title: Power Plant Technology 1/Kraftwerkstechnik 1



Prof. Dr.-Ing. Daniel Seibt


Englisch











Lernziele/Learning outcome: Students will get a knowledge about power engineering processes. They will compare and validate different types of power plants. The students learn in the practice the design and optimising of cycles.

Inhalt/Contents: Types of power plants, basic components of conventional power plants; steam cycles (Clausius-Rankine saturated steam cycle and superheated steam cycle); gas turbine cycle (Brayton cycle); methods to improve efficiency; thermodynamic calculations of cycles; design of power led power plants and combined heat and power plants (CHP); gas turbine power plants, steam turbine power plants; classification and characteristics of fuels; boiler; firing systems; combustion calculation

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: It is possible to download the script from the internet.


Voraussetzungen/Prerequisits: Basics in Thermodynamic


26

Power Plant Technology 2 : Modul 35-4-50

Langtitel/Long title: Power Plant Technology 2/Kraftwerkstechnik 2



Prof. Dr.-Ing. Daniel Seibt


Englisch











Lernziele/Learning outcome: Students will get a knowledge about build, design and operation of components in power plants. They will get the competency to dimensioning components according to the engineering rules.

Inhalt/Contents: construction of heat exchangers in power plants; turbines and pumps in power plants; electrical engineering equipment for power generation, transmission and auxiliary power requirement, control technology; safety and protection systems; hydroelectric and nuclear power plants, fuel cells, hydrogen economy

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: It is possible to download the script from the internet.


Voraussetzungen/Prerequisits: power plant technology 1


27

Power Quality and Industrial Ecology for Smart Manufacturing: Module 11197


Verantwortliche/r / Responsible staff member: Dr. Leonowicz




Dauer / Duration: one semester






studies:

120 h


Students will get detailed knowledge about power quality issues and notions of industrial

ecology, with practical examples and exercises.

Inhalt / Contents:

Standards of power quality. Harmonic analysis, Fourier series, DFT, DFT algorithms,

Wavelets, Automation of Disturbance Recognition, Sources of harmonic distortion in power

systems, Transformers, Rotating Machines, Arcing Devices, Rectifiers, Power Converters,

Inverter-Fed Drives, AC Regulators, Compensators, Effects of Harmonic Distortion:

Resonances, Harmonic Losses, Power Plant effects, Power of Distorted Waveforms, Fault

Conditions, Measurements, Data Acquisition, Equipment, Tests. Mitigation of Harmonics:

Active and Passive Filters, Tuned Filters, STATCOM, Hybrid Systems, Harmonic Flows:

Direct Harmonic Analysis, Models, Harmonic Impedances of the system.

General presentation of industrial ecology. The role of biodiversification in human activity.

Industry as living system within living systems. Capability of imitation of the nature.

Fundamental laws of industrial ecology. Dynamics of ecosystems, its limitations in industry.

Ecological systems and natural systems. Methods and tools of industrial ecology. Industrial

metabolism. Modeling of input/output dynamics. Waste prevention, examples. Product-life,

service economy. Future concepts. Industrial ecosystems and Eco-Industrial Parks.

Examples from power industry, transportation, manufacturing, telecommunication.


R. C. Dugan, M. F. McGranaghan, and H. W. Beaty. Electrical Power Systems Quality,

McGraw-Hill, New York, 1996; T.E. Graedel, B.R. Allenby: Industrial Ecology and

Sustainable Engineering, Pearson, 2010, Web-based teaching material.


two written examinations, 90 min




The lecture will be offered as a block seminar


28

Power System Economics I : Modul 35-3-03

Langtitel/Long title: Techno-economic characterisation of power systems (Power System Economics I) / Elektrizitätswirtschaft I



Prof. Dr. Felix Müsgens


Englisch










Electrical Power Engineering/M.Sc. Elektrotechnik/B.Sc.

Elektrotechnik/Diplom Elektrotechnik/M.Sc.

Environmental and Resource Management/M.Sc. Wirtschaftsingenieurwesen/Diplom

Lernziele/Learning outcome: After attending the module “Power System Economics 1” the students have a deeper understanding of energy-economic basics. The students can compare different components of an energy supply system with the help of techno-economic characteristics. Due to the variety of interdependencies between power system economics and business administration/economics the students also have knowledge of different approaches used in business administration and economics.

Inhalt/Contents: I. Electricity demand a. Electricity demand in Germany / Europe / the World b. Load structure c. Energy efficiency on the demand side II. Electricity transport and distribution a. Electricity networks in Germany b. Investments and network charges c. Congestion management III. Electricity production a. Actual investment needs b. Investment planning in electricity production c. Techno-economic characterisation of options for electricity production d. Further development of options for electricity production IV. Power systems in Europe a. Existing power plants in Europe

29

b. Framework conditions for renewable energies in Europe c. Energy-economic framework conditions in Germany d. Power companies in Germany V. Emissions from electricity production

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: Skript/ lecture notes: http://www.tu-cottbus.de/energiewirtschaft Literatur/ literature:Stoft, Steven: “Power System Economics”, Wiley-Interscience (ISBN 0-471-15040-1) Shively, B.; Ferrare, J.: „Understanding Today’s Electricity Business“, Enerdynamics (ISBN 0-9741744-1-6) Hensing, I.; Pfaffenberger, W.; Ströbele, W.: “Energiewirtschaft“, Vahlen Verlag (ISBN 3-486-24315-2)

Zu erbringende Leistungen/Assessment mode: Written examination, 150 min



30

Power System Economics II : Modul 35-4-01

Langtitel/Long title: Fundamentals of liberalised power markets (Power

System Economics II) / Elektrizitätswirtschaft II



Prof. Dr. Felix Müsgens


Englisch










Electrical Power Engineering/M.Sc. Wirtschaftsingenieurwesen/Diplom

Lernziele/Learning outcome: After attending the module “Power System Economics II” the students have a deeper understanding of the new economic reality of liberalised energy markets. Furthermore, the students know the different submarkets of the power market and how they work.

Inhalt/Contents: The European liberalisation process, The German power market and the submarkets, Market power, pricing and investments, New requirements of the liberalised market, Energy companies in 20 years

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: Script, reference books

Zu erbringende Leistungen/Assessment mode: Schriftliche Prüfung / Written examination, 150 min



31

Power System Operation: Module

Modultitel / Module title (deutsch) Systemführung von Elektroenergienetzen


Verantwortliche/r / Responsible staff member: Prof. Dr.-Ing. Harald Schwarz



Angebotsturnus / Frequency of offer: each winter semester



2nd year of Master studies





studies:

120 h


The focus of this lecture is on theoretical and practical introduction into power system

operation. For laboratory exercises the facilities of the Research and Training Centre for

grid operators at BTU Cottbus will be used.

Inhalt / Contents:

Theoretical part:

control systems;

operation control of power systems;

system management planning;

security of supply;

balancing group management;

stability of the system;

power-frequency control

Practical part (individual training and team training):

detailed introduction into the training system;

introduction in handling the control system;

training of several scenarios under almost authentic conditions (faults in the grid, overload

of grid elements, breakdown of load or generation units, high RE in-feed combined with

various load cases);

training of communication processes between system operators;


Script


1 written examination, 90 min; presentation


Introduction in Electrical Power Systems



Will not be offered in WS 2013/14, WS 14/15


32

Renewable Energy Technologies for Electrical Power Supply: Module 11195

Modultitel / Module title (deutsch) Elektroenergieerzeugung auf Basis erneuerbarer

Energien













studies:

120 h


Students will get an introduction into different technologies of utilization of renewable

energies for generation of electrical energy.

Inhalt / Contents:

RE-technologies: Hydro power, Wind power, Photovoltaic, Solar-thermal power plants,

Geothermal power plants, Tidal power plants;

Overview about the resources and accessible potentials;

Physical basics;

Availability, efficiencies and ranges of power output of existing and prospective plants;

Problems of grid integration of fluctuating RE-units.

Storage of electrical energy: Pumped-hydro plants, CAES-plants;


Script


1 written examinations, 90 min


Basic understanding in electrical engineering




33

Selected Chapters in Technical Combustion: Module 11292

Modultitel / Module title (deutsch) Ausgewählte Kapitel der Technischen Verbrennung


Verantwortliche/r / Responsible staff member: Prof. Dr.-Ing. Mauß, Fabian











studies:

120 h


The aim of the module is to describe in an applicate context the chemistry and

physics of combustion processes. The module will analyzed advance laser

diagnostic, combustion modeling, laminar and turbulent flame, combustion

application in mechanism generation an reduction techniques, engine simulation

and optimization.

Inhalt / Contents:

- Thermodynamics and Chemical kinetics of Combustion Processes

- Reaction kinetics of homogeneous gas phase reactions

- Balance equations for laminar and turbulent flows

- Ignition and extinction processes in homogeneous systems

- Laminar and turbulent premixed and diffusion flames

- Pollutant formation


Teaching materials: - Power point presentations Papers from the literature of actual research Literature: - Peters, Norbert: Turbulent Combustion. Cambridge Univ. Press, Cambridge 2000. - Warnatz, Jürgen: Verbrennung - Physikalisch-chemische Grundlagen, Modellierung und Simulation, Experimente, Schadstoffentstehung. Springer-Verlag, Berlin 2001. - Warnatz, Jürgen; Maas, Ulrich; Dibble, Robert: Combustion – Physical and chemical fundamentals, modeling and simulation, experiments, pollutant formation. Springer-Verlag, Berlin 2006. - Görner, Klaus: Technische Verbrennungssysteme - Grundlagen, Modellbildung, Simulation. Springer-Verlag, Berlin 1991. - Journal of Combustion and Flame

34

- Proceedings of the combustion institute - Journal of physics and chemistry


80% Oral examination 20% Contribution to the seminar

80% of the assistance is required to pass the course


- Module 44407 Technical Combustion

- Strongly recommended: Fundamental knowledge in mathematics and physics,

thermodynamics, and heat and mass transfer.


None



440350 LE Selected chapter in technical combustion

440351 SE Selected chapter in technical combustion

35

Signal Processing and Optimization Methods in Data Mining: Module 11194

Modultitel / Module title (deutsch) Signalverarbeitung und Optimierungsmethoden für Data

Mining


Verantwortliche/r / Responsible staff member: Dr. Janik










studies:

120 h


Students will get detailed knowledge about signal processing issues and notions of

optimization methods, with practical examples and exercises.

Inhalt / Contents:

The first part of the course introduces foundations of signal processing methods in electrical

power engineering. Introducing lectures provide ideas of discrete representations of

continuous signal with basic functions and signal orthogonal projection. Next stage of the

course concerns continuous representations of deterministic signals. Introduced definitions

allow passing into nonparametric time-frequency representations. Then, follow the time-

scale representations with wavelets. Backgrounds of statistical signal processing are

introduced with outlined parameter estimation, optimal filtering, linear modeling and

estimation. Finally, various methods of parametric spectrum estimation are outlined.

Examples of application in electrical engineering are presented throughout the course.

Main chapters: 1) The backgrounds of deterministic signal representations, 2) Basic

functions and signals orthogonal projections, 3) Continuous representations of deterministic

signals, 4) Nonparametric time-frequency representations, 5) Generalized equation of

nonparametric time-frequency representations, 6) Time-scale signal representations, 7)

Backgrounds of Statistical Signal Processing 8) Linear modeling and estimation of model

parameters from data 9) Parametric spectrum estimation, 10) Applications in power

systems.

In the Optimization part the Students will learn foundations of optimization methods and

their numerical application in engineering. The students will be skilled to optimize various

types of practical industrial problems. The following issues are highlighted

1) Optimization problem formulation. Classification of problems. The standard form of an

optimization problem. Objective function and optimization variables. Examples.

2) Mathematical preliminaries. Vectors and Matrices. Elements of differential calculus.

Convex sets and functions. 3) Unconstrained problems. Optimality conditions for

unconstrained problems. 4) Unconstrained minimization techniques. The steepest descent

method. Conjugate gradient. The Newton methods. 5) One-dimensional search methods.

Golden section search. 6) Nonlinear constrained optimisation. Kuhn-Tucker conditions.

36

Lagrangian function. Lagrangian duality. 7) Penalty methods. Linear programming. The

simplex method. Integer optimization. 8) Genetic algorithms. Neural networks. Interior-point

methods. 9) Numerical matrix operations. Numerical solutions to rule-based optimization

problems. The practical examples and exercises include:

1. Optimization problem formulation, mathematical models of problems.

2. Analytical minimization techniques.

3. Numerical methods: the steepest descent, conjugate gradient, the Newton methods.

4. Linear programming.

5. The application of Matlab Optimization Toolbox.


S. Haykin, B. Van Veen – Signals and Systems, John Wiley & Sons, Inc., 1999, C.W.

Therrien – Discrete Random Signals and Statistical Signal Processing, Englewood Cliffs,

Prentice Hall, 1992, web based lecture script

K.P. Chong, S.H. Żak: An Introduction to Optimization, 2nd edition, New York, John Wiley,

2001, J.F. Bonnans: Numerical optimization: theoretical and practical aspects, Springer-

Verlag, 2003, M. Asghar Bhatti: Practical Optimization Methods, Berlin, Springer-Verlag

2000


two written examinations, 90 min


Courses on Algebra and Analysis



The lecture will be offered as a block seminar


37

Solar Energy Materials Research & Solar Cells Module:11400

Materialforschung für die Solarenergie & Solarzellen

Department: Faculty 1 - Mathematics, Natural Sciences and Computer Science

Responsible Staff Member: Prof. Dr.-Ing. Bär, Marcus

Language of Teaching: English

Duration: 1 semester

Frequency of Offer: On special announcement

Credits: 6

Learning Outcome:

Compared to module 11222 "Photovoltaics: Basics, State of the Art and Solar Cell Materials Research", students will get a more detailed introduction into photovoltaics including current photovoltaics technology trends and materials research approaches towards new concepts. In hands-on lab tutorials they will learn how to characterize the optical properties of solar energy materials and the electrical performance of solar cell devices.

Contents:

Thin-film photovoltaics

Optical properties of solar energy materials

I(V) characteristics of solar cell devices

Quantum efficiency of solar cell devices

"Third generation" photovoltaics

Photovoltaics manufacturing technologies

Advanced characterization methods for photovoltaics materials research

Recommended Prerequisites:

Fundamental knowledge in physics and engineering

Good knowledge of the content of module 11222 : Photovoltaics: Basics, State of the Art and Solar Cell Materials Research

Mandatory Prerequisites: None

Forms of Teaching and Proportion:

Lecture / 2 Hours per Week per Semester

Practical training / 2 Hours per Week per Semester

Self organised studies / 120 Hours

Teaching Materials and Literature:

A. L. Fahrenbruch, R .H. Bube, "Fundamentals of Solar Cells", Academic Press, New York - London 1983 H. J. Müller, "Semiconductors of Solar Cells", Artech House, Boston - London 1993 S. M. Sze, Chapter 14 in "Physics of Semiconductor Devices", John Wiley & Sons, New York 1981 M. Bär, L. Weinhardt, and C. Heske, Advanced Characterization Techniques for Thin Film Solar Cells, edited by D. Abou-Ras, T. Kirchartz, and U. Rau (Wiley VCH Verlag GmbH & Co KGaA, ISBN: 978-3-527-41003-3), Chap. 15.

Assessment Mode: Oral examination (with grade)

Remarks: This module will be taught as a block course in the semester break at the Helmholtz-Zentrum Berlin f¸r Materialien und Energie GmbH in Berlin. Number of participants is limited to 10 students.

38

Sustainable Use of Underground Resources; Geoth. En. a. CO2 Stor : Modul 35-4-42

Langtitel/Long title: Technologies for geothermal heat recovery and CO2

storage from underground reservoirs





Englisch










Lernziele/Learning outcome: Students will get a deeper understanding the exploration thermal energy reservoirs or depth section area to sequestrate CO2 and the necessary technology for these proceses

Inhalt/Contents: The lecture encounters basic knowledge for the geo-energetic utilization of underground reservoirs. The lecture helps to understand the basic geology needed for the exploration of geothermal energy reservoirs or of the depth sections to sequestrate CO2 and shows up the practice to make access to these reservoirs by drilling and the engineering of the reservoir by enhancing methods. The lecture describes the technology to make use of the Earth’s heat for direct use, power, and/or chill and gives boundary conditions for its economic and environmental utilization. Main chapters: 1) Exploration with Reservoir Definition and Exploration Methods, 2) Development with Drilling into the interesting Reservoirs, 3) Reservoir Engineering incl. Enhancing Methods and Reservoirs in Operation, 4) Process Engineering with Direct Use and Conversion of Earth’s Heat into Chill or Power, Economics and Environmental Impact and specific aspects of Carbon capture.

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: web based lecture script


Voraussetzungen/Prerequisits: Basics in physics and natural sciences

Bemerkungen/Remarks: Will not be offered in WS 14/15, WS 15/16

39

Switching Technologies

Langtitel/Long title: Switching Technologies for industrial and grid

applications



Prof. Dr.-Ing Christian Heinrich


Englisch


WS








Power Engineering

Lernziele/Learning outcome: Students know the operating principles of various switching technologies used for power engineering. This covers switching in vacuum, switching in gases and power electronics including the switching devices and its characteristics. Students will also get an overview of application in industrial plants and power grids.

Inhalt/Contents:

Definitions and classification of switching devices Requirements for switching elements Vacuum switching chamber and its characteristics Power electronic elements and its static and dynamic behaviour other switching technologies Application of vacuum switching tubes in circuit breakers Circuit breaker application in power grids converter designs Converter and its applications

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: Script, list of recommanded literature will be provided during the lecture

Zu erbringende Leistungen/Assessment mode: written exam at the end of semester, duration 90 min

Voraussetzungen/Prerequisits: Bachelor in Elektrotechnik


40

Thermal Process Engineering and Equilibrium Thermodynamics : Modul 44-1-08

Langtitel/Long title: Thermal Process Engineering and Equilibrium

Thermodynamics

Fachgebiet/Scientific field: Process Engineering


Prof. Dr.- Fabian Mauß


Englisch





Vorlesung/Praktikum 1 SWS

Vorlesung/Übung 4 SWS



Environmental Technologies/M.Sc. Process Engineering & Plant Design/M.Sc.

Lernziele/Learning outcome: The module provides knowledge about thermal apparatuses with phase transformation. The student will learn how to calculate thermal equilibriums in complex systems and to evaluate thermal apparatuses.

Inhalt/Contents: Single and multiphase flow, distillation, rectification, absorption, extraction, adsorption, drying

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: Teaching materials: formulary, lecture handouts, laboratory informations Literature: Coulson, John M. : Coulson & Richardson’s chemical engineering Volume 2, Butterworth - Heinemann; Oxford 2002

Zu erbringende Leistungen/Assessment mode: laboratory documentation (exame prerequisite), written exam

Voraussetzungen/Prerequisits: knowledge in mathematics, physics and thermodynamics

Bemerkungen/Remarks: This module will be offered in WS 13/14, 15/16, 17/18

41

Technology and Operation of Wind Turbines : Modul 35-4-59

Langtitel/Long title: Technik und Betrieb von Windkraftanlagen



Prof. Dr. Przemyslaw Janik


Englisch



Dauer/Duration: one Semester / one semesters







Lernziele/Learning outcome: Students will get a deeper knowledge of the different types and components of Wind turbine generators (WTG) and how to operate large wind farms and single turbines according to maintenance and trouble shooting. How to affect reliability and availability of WTG in a positive matter.

Inhalt/Contents: Introduction in development and planning of wind farms, Description of WTG components and their function (frequency converter, gear box, rotor blades, tower etc.), Influences of components to reliability and availability of WTG, Maintenance strategy, Operation strategy and system (data mining and storage, evidence of technical parameters and data to operation).

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: Script and Presentation (Power Point)


Voraussetzungen/Prerequisits: Basics in Power Engineering


42

Technical Combustion: Modul 44-4-07

Langtitel/Long title: Technische Verbrennung /

Technical combustion

Fachgebiet/Scientific field: Verfahrenstechnik


Responsible staff member: Prof. Fabian Mauß

Sprache/Language of

teaching: Deutsch / English


of offer: jedes Wintersemester / each winter semester







study:

Nachwachsende Rohstoffe und Erneuerbare

Energien/M.Sc. - PO 2008

Verfahrenstechnik - Prozess- und Anlagentechnik/M.Sc.

- PO 2009

Wirtschaftsingenieurwesen/M.Sc. - PO 2008


Ziel des Moduls ist es Verbrennungsvorgänge aus physikalischer und chemischer

Sicht zu beschreiben. Der Schwerpunkt der Lehrveranstaltung liegt deshalb zum

Einen auf der Betrachtung von Verbrennungsvorgängen unter thermodynamischen

Gesichtspunkten. Zum Anderen werden die Reaktionskinetik homogener

Gasreaktionen, Kettenreaktionsmechanismen, sowie Zünd- und Löschvorgänge in

homogenen Systemen behandelt. Des Weiteren werden den Studenten Kenntnisse

über laminare/turbulente Vormischflammen laminare/turbulente Diffusionsflammen,

sowie deren technische Anwendungen vermittelt.

Inhalt/Contents:

- Thermodynamik und Chemie von Verbrennungsprozessen

- Reaktionskinetik homogener Gasreaktionen

- Bilanzgleichungen für laminare und turbulente Strömungen

- Zünd- und Löschvorgänge in homogenen Systemen

- laminare/turbulente Vormisch- und Diffusionsflammen

- Schadstoffbildung


Unterrichtsmaterialien:

- Vorlesungsfolien

Literatur:

43

- Peters, Norbert: Turbulent Combustion. Cambridge Univ. Press, Cambridge 2000.

- Warnatz, Jürgen: Verbrennung - Physikalisch-chemische Grundlagen, Modellierung

und Simulation, Experimente, Schadstoffentstehung. Springer-Verlag, Berlin 2001.

- Warnatz, Jürgen; Maas, Ulrich; Dibble, Robert: Combustion - Physical and

chemical fundamentals, modeling and simulation, experiments, pollutant formation.

Springer-Verlag, Berlin 2006.

- Görner, Klaus: Technische Verbrennungssysteme - Grundlagen, Modellbildung,

Simulation. Springer-Verlag, Berlin 1991.


mündliche Abschlussprüfung


mathematische (Analysis, lineare Algebra) und physikalische Grundkenntnisse,

Grundlagen der Thermodynamik und des Wärme- und Stofftransports


Modul wird auch in Englisch angeboten!

44

Wind Energy Economics, Wind Resources Estimation : Modul 35-4-26

Langtitel/Long title: Wirtschaftlichkeit und Resourcenabschätzung von

Windenergie



Prof. Dr. Przemyslaw Janik


Englisch



Dauer/Duration: one Semester / one semesters







Lernziele/Learning outcome: Students will get an understanding of the wind energy market and the key variables influencing the economics of a wind farm. They will learn and practice, what is necessary to evaluate the wind resource, prepare a viable business case, build a financial model and select a suitable funding mix.

Inhalt/Contents: The business case for wind energy: market and economics; An introduction to the developing, structuring and financing of wind projects; Estimating cash flows and preparing spreadsheets; Wind farm valuation using different evaluation methods; Risk analysis

Unterrichtsmaterialien und Literaturhinweise/Teaching materials and literature: Students will be provided with a reader as well as the slides and material presented in class. Lessons will to a large extent be case-based and application-oriented. There is no book or text which covers the entire content taught in this module. The reader will contain a collection of the papers used in the course.


Voraussetzungen/Prerequisits: None explicitly required. However, students with a prior knowledge of basic financial compounding and discounting methods will have an advantage.


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