Module description

Transcription

Module description

Campus Gengenbach
Klosterstraße 14, 77723
Campus Offenburg
Badstraße 24, 77652
Energy Economics
Teaching methods
Learning target
Lecture
The students know and apply the common terminology in the energy sector. They know and
understand the structure of an energy sector by example of Germany and are able to access
systematically the structures of other energy markets. The students know how to access data in the
energy sector; they are acquainted to statistical methods allowing critical analysis of data.
The students got the background to judge the impact of actual developments in industry, politics,
legacy etc. on the energy sector.
The students know how to gain information and data required for techno-economic analyses of
energy projects. They are able to perform cost calculation and investment appraisal studies.
By applying Computer-Algebra-Tools they are able to perform extensive sensitivity analyses.
Duration
Hours per week
Overview
1 Semester
4.0
ECTS
Responsible
person
Max. participants
Recommended
semester
Frequency
Lectures
Classes:
Individual/
Group work:
Workload:
4.0
Prof. Dr. Anke Weidlich
60 h
60 h
120 h
25
ECM 1
Annually (ws)
Energiewirtschaft
Type
Lecture/seminar
Nr.
M+V3037
Hours
4.0
per week
Lecture
1. Terminology in the energy sector.
contents
2. Primary energy resources (conventional and renewable) and energy
conversion chains
3. Environment protection (impact of exploitation, transport and conversion
on environment, environment protection and international law).
4. Structure of the energy sector (government agencies, organisations,
industry, etc. involved and their role; Regulations in the energy sector by
example of Germany and Europe; Liberalisation in the energy market;
regulation of grid-bound energy sector)
5. Cost calculation; Learning Curves; Investment appraisal Methods
6. Energy demand and energy systems (sectors; daily, weekly and
seasonal load profiles; electricity market and heat market; district heating;
cogeneration)
7. Electrical supply (example Germany, Europe; power plant fleet; virtual
power plants; base load, middle load, peak load; decentralised energy
supply; grid topology; grid operation; quality and reliability of grid
operation)
Literature
MÜLLER, L.: Handbuch der Elektrizitätswirtschaft - Technische,
wirtschaftliche und rechtliche Grundlagen. 2. Auflage, Berlin : Springer,
2001.
KONSTANTIN, P.: Praxisbuch Energiewirtschaft - Energieumwandlung, transport und -beschaffung im liberalisierten Markt. 2. Auflage, Berlin :
Springer, 2009.
Operations Research in Energy Economics
http://www.hs-offenburg.de/en/nc/international/study-in-offenburg/international-masters-programs/international-businessconsulting-ibc/module-description/lsfguide/21225/1945/3/?sort=1&cHash=7a79f26eecedc769c62b81e1cbed0ef1
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Operations Research in Energy Economics
Teaching methods
Learning target
Lecture
Qualitative and quantitative methods of management science/Operational Research are gaining
ever higher importance in the energy sector e.g. optimization problems play a prominent role in
energy economics, considering for example development of power plant fleets, development of
grids and the usage of power plants. Students learn about the background of forecasting methods
and optimization as mathematical tool for analysing power systems. They are able to formulate
mathematical models and to apply optimization methods, e.g. linear programming.
Within module ECM-02 the students also apply the knowledge and competencies gained in
economics and business strategy gained so far. Within required elective courses the students
deepen and expand their capabilities when implementing a revised business strategy and
experience the impact on an enterprise as a whole or when analysing and further developing
energy management solutions in industry.
Duration
Hours per week
Overview
1 Semester
4.0
ECTS
Responsible
person
Max. participants
Recommended
semester
Frequency
Lectures
Classes:
Individual/
Group work:
Workload:
4.0
Prof. Dr. Anke Weidlich
60 h
60 h
120 h
25
ECM 3
Annually (ws)
Operations Research in der Energiewirtschaft
Type
Lecture
Nr.
M+V3038
Hours
4.0
per week
Lecture
1. System analysis in Energy Economics (data acquisition and data
contents
refinement, data representation, regression techniques)
2. Optimization problems in Energy Economics (types of problems; e.g.
development of power plant fleet; resource planning)
3. Approaches to develop models for optimization problems in energy
sector
4. Application of selected computational optimization techniques
Literature
KONSTANTIN, P.: Praxisbuch Energiewirtschaft - Energieumwandlung, transport und -beschaffung im liberalisierten Markt. 2. Auflage, Berlin :
Springer, 2009.
RUDOLPH, M., WAGNER, U.: Energieanwendungstechnik. Wege und
Techniken zur effizienteren Energienutzung. Berlin : Springer, 2008.
SUHL, L., MELLOULI, T.: Optimierungssysteme : Modelle, Verfahren,
Software, Anwendungen. 2. Auflage, Berlin : Springer, 2009.
Hydro and Wind Power Plants
Teaching methods
Learning target
Lecture
The students understand the technology of wind power and hydro power plants. They are able to
perform a first design for a specific plant. The students know the environmental impact of hydro
and wind power and can judge the impact of environmental protection on permit procedures. They
are capable to perform a feasibility study for a wind power plant or hydro power plant covering
aspects of technical potential, basic design of the plant, environmental impact, permit procedure
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and economics.
Measurement techniques and their field of application are known. The signal recording,
processing and display are known from own experience during the lab work. The students are
able to define the measuring equipment when investigating the behaviour of apparatus and
machines in energy conversion plants. The students are familiar with the components of a
measuring chain.
Duration
Hours per week
Overview
ECTS
Responsible
person
Max. participants
Recommended
semester
Frequency
Lectures
1 Semester
5.0
Classes:
Individual/
Group work:
Workload:
5.0
Prof. Dr. Peter Treffinger
75 h
75 h
150 h
25
ECM 1
Annually (ws)
Wasser- und Windkraftanlagen
Type
Lecture
Nr.
M+V3039
Hours
5.0
per week
Lecture
1. Wind power
contents
1.1 Introduction (History of wind power, structure of wind power plants,
technical potential of wind power); 1.2 Physical background of wind energy
conversion, aerodynamics, power curves ;1.3 Rotor design (static and
dynamic loads, material and construction); 1.4 Components of wind
energy conversion chain (mechanics of rotor, gear boxes, electrical
generator, bearings);1.5 Construction of wind power plants; 1.6 Integration
of wind power plants in energy systems; 1.7 Economics of wind power and
permit procedures
2. Hydro power
2.1 Introduction (History of hydro power, structure of hydro power plants,
technical potential of hydro power); 2.2 Physical background water
turbines and turbine types; 2.3 Construction of hydro power plants and
impact on the environment (hydrology, ecosystem, landscape); 2.4
Components of hydro power energy conversion chain and integration in
energy systems; 2.5 Economics of hydro power and permit procedures
Literature
GIESECKE, J.: MOSONYI, E.: Wasserkraftanlagen - Planung, Bau und
Betrieb. 4. Auflage, Berlin : Springer, 2005.
STIEBLER, M.: Wind Energy Systems for Electric Power Generation. Berlin :
Springer, 2008.
HAU, E.: Windkraftanlagen. 4. Auflage, Berlin : Springer, 2008.
Thermal Power Plants
Teaching methods
Learning target
Lecture
The students know in-depth fluid dynamics and mechanics of thermal turbo-machinery. They know
about different types of steam generators and understand their requirements with respect to fluid
mechanics and heat exchange in two-phase-flow. The students are aware of instabilities, which
can occur when operating steam generators. The students are able to formulate a specification
sheet for the main components of thermal power plants. Optimization strategies for the operating
conditions of power plants can be judged and examined in a qualified way.
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Duration
1 Semester
Hours per week
Overview
8.0
ECTS
Responsible
person
Max. participants
Recommended
semester
Frequency
Lectures
Classes:
Individual/
Group work:
Workload:
7.0
Prof. Dr. Bernd Jatzlau
Campus Offenburg
120 h
90 h
210 h
25
ECM 1
Annually (ws)
Thermische Kraftanlagen
Type
Lecture
Nr.
M+V3040
Hours
8.0
per week
Lecture
1. Flow and heat Transfer in Gas-Liquid-Mixtures
contents
1.1 Definitions
1.2. Conservation laws and balances
1.3. Flow characteristics
1.4. Steam quality and heterogeneous flow (flow with slip)
1.5. Pressure drop
1.6. Critical stream out
1.7. Boiling (Nucleation and bubble generation, Generation of mixture)
1.8. Measuring techniques
1.9.Similarity laws
2. Advanced Fluid Mechanics in Turbo Machinery
2.1 Critical Review of Design Approaches
2.2 Flow through Channels and Nozzles
2.3 Linear and Rotating Cascades (Blade Rows)
2.4 Losses in Turbo Machinery
2.5 Radial Equilibrium of Flow
3. Auxiliaries
3.1 Condensate System (Condensors, Cooling Towers, Auxiliaries)
3.2 Feedwater Heater
3.3 Raw Water Treatment (Ion_Exchange Water Conditioners,
Evaporators)
3.4 Lubricants and Lubricating Devices
3.5 Environmental Control Systems
Literature
VDI-GVC (Hrsg.): VDI-Wärmeatlas - Berechnungsblätter für den
Wärmeübergang. 10. Auflage, Berlin : Springer, 2006.
Energy Systems
Teaching methods
Learning target
Lecture
The students govern the thermodynamic background of power cycles. They are able to develop
sets of equations describing large-scale energy systems and govern the mathematical methods for
solving it by means of computer algebra programs. They are proficient in the main characteristics
of components of energy systems, e.g. heat exchanger and apply methods to design heat
exchangers. The students know the technology of piping networks and are able to select specific
requirements suitable to the envisaged application. The students know about the range of fluid
machinery in thermal systems; they are able to choose appropriate types according to the
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specification of the application. Overall the students are able to perform exergetic analysis of
energy systems and to develop optimized systems also under economical boundary conditions.
Also the behavior of electrical grids is covered in Energy Systems. The student learn about the
structure of the electrical grid, the most important components needed, e.g. power lines,
transformers, power switch gears, etc. They are able to describe the structure of electric power
systems and have an understanding for the development of electrical grids with respect to
additional generation capacities. They are able to calculate stationary power flows and other
properties of power systems.
Duration
Hours per week
Overview
ECTS
Responsible
person
Max. participants
Recommended
semester
Frequency
Lectures
1 Semester
6.0
Classes:
Individual/
Group work:
Workload:
6.0
Prof. Dr. Reiner Staudt
90 h
90 h
180 h
25
ECM 1
Annually (ws)
Thermische Systeme
Type
Lecture
Nr.
M+V3041
Hours
4.0
per week
Lecture
1. Brief review of thermodynamic background and thermodynamic power
contents
cycles
2. Chemical thermodynamics with respect to combustion
3. Treating mass and energy balances of large thermal systems (steady
state)
4. Software tools in thermal engineering (property data bases, EES
(Engineering Equation Solver))
5. Designing heat exchangers
Literature
CENGEL, Y.A., BOLES, M.A.: Thermodynamics - An Engineering Approach.
New York : McGraw Hill, 2008.
VAN WYLEN, J., SONNTAG, R.E., BORGNAKKE, C.: Fundamentals of
Thermodynamics. 6th edition, New York : Wiley, 2003
MAREK, R., NITSCHE, K.: Praxis der Wärmeübertragung. München :
Hanser, 2007.
Elektrische Energietechnik
Type
Lecture
Nr.
M+V3021
Hours
4.0
per week
Lecture
1. Brief review of thermodynamic background and thermodynamic power
contents
cycles
2. Chemical thermodynamics with respect to combustion
3. Treating mass and energy balances of large thermal systems (steady
state)
4. Software tools in thermal engineering (property data bases, EES
(Engineering Equation Solver))
5. Designing heat exchangers
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Literature
Campus Offenburg
CENGEL, Y.A., BOLES, M.A.: Thermodynamics - An Engineering Approach.
New York : McGraw Hill, 2008.
VAN WYLEN, J., SONNTAG, R.E., BORGNAKKE, C.: Fundamentals of
Thermodynamics. 6th edition, New York : Wiley, 2003
MAREK, R., NITSCHE, K.: Praxis der Wärmeübertragung. München :
Hanser, 2007.
Scientific Skills
Teaching methods
Learning target
Lecture
The students are able to perform systematically literature research. They are able to develop a
structure for a scientific paper based on argumentation models. The student are aware of
standards in scientific writing and apply them when writing own papers.
Within the language part of the module students, who are not native German speakers, shall
become proficient in German. Depending on their pre-knowledge those students should at least
take "Deutsch als Fremdsprache 3 (DaF3)". Students, who are already proficient in German, shall
first use the language courses to get proficient in English. Following that, students might choose
other languages.
Duration
Hours per week
Overview
1 Semester
3.0
ECTS
Max. participants
Recommended
semester
Frequency
Lectures
Classes:
Individual/
Group work:
Workload:
4.0
25
ECM 1
60 h
60 h
120 h
Annually (ws)
Wissenschaftliches Arbeiten
Type
Lecture/seminar
Nr.
M+V3042
Hours
1.0
per week
Lecture
1. Introduction
contents
2. Literature Research in Science
3. Structure and Contents of Scientific Papers, Thesis, etc.
- Dialectic Three-Step, Toulmin Model of Argument
4. Wording in Scientific Papers
5. Important Elements in Scientific Papers
-Figures, -Tables, -References
6. Case Study: Writing a Scientific Paper (Therefore a current topic in the
energy sector is given in the frame of the mandatory lecture Energy
Economics 1. Working on the topic is acknowledged in Energy Economics
1 with 1 C!)
Literature
BLIEFERT, C., EBEL, H.F., RUSSEY, W.E.: The Art of Scientific Writing. 2nd
Edition. Weinheim : WILEY-VHC Verlag GmbH & Co. KGaA, 2004.
TOULMIN, ST: The Uses of Argument. Cambridge, UK : Cambridge Univ.
Press, 1958.
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Required Elective 1.1
Learning target
This module provides the student the possibility to specialise in specific aspects of energy
conversion, energy systems, energy economics, energy management, etc. The respective courses
are listed in section Required Elective Courses.
The first choice is courses with 4 C. However, also 2 courses with 2 C each can be chosen. In this
case in the certificate either the module name Selected Topics Energy Management /Vertiefung
Energiemanagement or the module name Selected Topics Energy Technology /Vertiefung
Energietechnik is taken. However, the names of courses are listed in the transcript of marks.
Hours per week
ECTS
Responsible
person
Max. participants
Lectures
4.0
4.0
0
Thermochemical Conversion Processes I
Type
Lecture
Nr.
M+V926
Hours
2.0
per week
Lecture
characterization of fuels for thermochemical conversion processes
contents
pyrolysis, gasification, incineration: chemical processes, mass and energy
balances, examples
Literature
Bridgwater, A.V.: Progress in thermochemical biomass conversion; Blackwell
Sciences Ltd, Oxford 2001.
Scholz, Reinhard: Abfallbehandlung in thermischen Verfahren: Verbrennung,
Vergasung, Pyrolyse, Verfahrens- und Anlagenkonzepte, Teubner 2001.
Demirbas, A.: Biofuels; Springer, London 2009.
Kaltschmitt, M.; Hartmann, H; Hofbauer, H. (ed.): Energie aus Biomasse Grundlagen, Techniken und Verfahren, Springer, Heidelberg, 2nd ed. 2009.
Deublein, D; Steinhauser, A.: Biogas from Waste and Renewable Resources;
Wiley-VCH, Weinheim, 2nd ed. 2010.
Thermochemical Conversion Processes II
Type
Lecture
Nr.
M+V927
Hours
2.0
per week
Lecture
processing of intermediate products from pyrolysis and gasification (synthetic fuels,
contents
biodiesel, methanol, electricity)
conversion of toxic substances by thermal processes (gases, heavy metals,
dioxins, and furans)
reduction of emissions of toxic substances
inertisation of residues from thermochemical processes (vitrification, solidification,
recycling)
Literature
Wiley-VCH, Weinheim, 2nd ed. 2010
Safety Engineering
Type
Lecture
Nr.
M+V912
Hours
2.0
per week
Lecture
general requirements and principles of safety orientated construction
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contents
Campus Offenburg
safety-relevant evaluation of systems - redundancy
safety-theoretical analytical methods
safety engineering in selected plants (steam boiler, acetylene plants, explosive
atmosphere, electrical systems, electrostatic charging)
safety-relevant construction units (burst disc, safety relief valves, flame safety
devices)
Literature
Arbeitssicherheit, Skiba (E.Schmidt-Verlag, Bielefeld, 1991)
Betriebliche Sicherheitstechnik, Skiba (E.Schmidt-Verlag, Bielefeld, 1991)
Biochemische Energiewandlung
Type
Lecture
Nr.
M+V3015
Hours
2.0
per week
Lecture
- Introduction lecture (Motivation, Regulatory Framework)
contents
- Biogas (engineering aspects, biological stages, economic and
ecologic aspects, present research topics)
- Biotechnological Ethanol process (microbiological background,
application, present research topics)
- Biotechnological Aceton/Butanol process
- Further relevant Fermentation Processes (e.g. biological Hydrogen
Production)
- Microbial Fuel cell
- Microalgae technology (Microbial Basics, Cultivation, Oil
Production)
- Syngas Fermentation
Literature
KHANNA, M: Handbook of Bioenergy Economics and Policy [E-BOOK] /
EDITED BY MADHU KHANNA, JÜRGEN SCHEFFRAN, DAVID ZILBERMAN. - New
York, NY : Springer Science+Business Media, LLC, 2010. - OnlineRessource.
(Natural Resource Management and Policy ; 33) (SpringerLink : Bücher)
ISBN 978-1-441-90369-3
PPN 327001704
Planspiel Unternehmensführung
Type
Lecture/seminar
Nr.
M+V3007
Hours
2.0
per week
Lecture
The concept of the (board) game is that students will "be in charge" for an
contents
already existing company. They act as members of the management
board. This means the following steps and tasks:
a strategic concept has to be developed (which will be realized during the
coming 5 business years);
this concept has to be transferred to the functional areas and its decisionmaking;
the company has to be controlled by using common ratios.
Additionally aspects of team management are also covered in context of
the game.
Literature
Handout (covering the input of topics e.g. Marketing, Cost Accounting,
Investment, Finance, Profit and Loss Controlling and Value Based
Management)
Einsatz von CAE-Instrumenten in der Projektierung
Type
Lecture
Nr.
M+V3025
Hours
2.0
per week
Lecture
The students know piping and instrumentation diagrams as important tools
contents
in project planning. They are aware of different standards applied. The
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students understand the requirements on CAE-Tools, which could be
employed through all project phases. They understand how CAE-Tools are
employed during all project phases, namely using isometric or 3D-views,
connecting to databases and creating efficiently project documentation.
Literature
DIN 2481: Wärmekraftanlagen - Graphische Symbole.
ISO/TS 16952-10:2008: Technical product documentation - Reference
designation system -- Part 10: Power plants.
KUHR, Harald, METT, Hans-Heinrich: MicroStation V8 Seminar. 3.
Auflage, Stuttgart : Teubner, 2003.
MESSMER, Harald: TRICAD MS. Wiesbaden : Teubner, 2004.
Kommunikation, Rhetorik, Präs entation
Type
Lecture/seminar
Nr.
M+V3031
Hours
2.0
per week
Lecture
Communication
contents
- Messages, Nonverbal communications, Intercultural communications
Rhetorics
- Speech, Voice
Presentations
- Structuring models, Visual aids, Handling objections
Literature
BARKER, Alan: Improve Your Communication Skills. London : Kogan Page,
2006.
BRADBURY, Andrew: Successful Presentation Skills. London : Kogan Page
2006.
Scientific literature
BARNES, Graham (1977): Transactional analysis after Eric Berne :
teachings and practices of three TA schools. New York: Harper,1977.
HOFSTEDE, Geert: Cultures and Organizations - Software of the Mind:
Intercultural Cooperation and Its Importance for Survival. 2. ed., New York
McGrawHill, 2005.
SCHULZ VON THUN, Friedemann: Miteinander reden. Störungen und
Klärungen. 45. Auflage, Reinbek : Rowohlt,2007.
WATZLAWICK, Paul, BEAVIN, Janet H., JACKSON, Don D.: Pragmatics of
Human Communication. A Study of Interactional Patterns, Pathologies,
and Paradoxes. New York: Norton & Company, 1967.
Energievertrieb in Deutschland
Type
Lecture/seminar
Nr.
M+V3010
Hours
2.0
per
week
Lecture 1. Die europäische Liberalisierung der Energiewirtschaft als Auslöser für
contents die heutigen wirtschaftlichen Rahmenbedingungen der Branche
a) Historie b) Rechtlicher Rahmen c) Vertragsverhältnisse in der
Energiewirtschaft und Wertschöpfungskette d) Exkurs: EFET Verträge
2. Internationale Energierohstoffmärkte und ausgewählte Projekte
a) Europäische Energiebörsen b) Begriffliche Grundlagen c) Marktregeln
d) Reserven/Ressourcen am Beispiel Erdöl e) Pipelineprojekt Nord Stream
f) Pipelineprojekt Nabucco
3. Einflussfaktoren auf die Energiemärkte
a) Ausgewählte Variablen b) Marktanalyse c) Exkurs: Erzeugungskosten
der verschiedenen Kraftwerkstypen d) Exkurs: Merit Order Kurve des
deutschen Kraftwerksparks
4. Die EEX in Leipzig
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a) Geschichte b) Commodities c) Produkte (OTC-Markt, Spot-Markt,
Termin-Markt, Futures, Forwards)
5. Portfoliomanagement
a) Produktgrundsätze b) Bilanzkreismanagement c) Langfristprognose /
Absatzprognose d) Exkurs: Realoptionen in der Energiewirtschaft e)
Exkurs: Einbindung von Erdgasspeichern
6. Kostenbestandteile eines „Energiepreises"
a) Verteilung der einzelnen Kostenbestandteile b) Termin- und
Spotmarktpreise c) Regelenergie, Ausgleichsenergie d) Risikozuschläge
e) Netznutzung f) Steuern und Abgaben
7. Risikomanagement
a) Marktpreisänderungsrisiko b) Mengenrisiko c) Kontrahentenausfallrisiko
d) Operatives Risiko e) Liquiditätsrisiko
8. Marketing und Kommunikation in der Energiewirtschaft aus Sicht eines
Energielieferanten
a) Wechselbereitschaft der Industrie- und Privatkunden in Deutschland
b) Kundensegmentierung
c) Produktstrategien und -beispiele
Energiemanagement in der Industrie
Type
Lecture/seminar
Nr.
M+V3008
Hours
2.0
per week
Lecture
The course gives practical insight in projects on which energy consulting
contents
companies are working on. This covers topics like consulting on energy
procurement and contracting/outsourcing of energy services, energy
efficiency checks of plants or facilities etc. Special emphasis is taken to
explain decision-making processes in industry regarding energy supply,
whereby the key factors cost, security and reliability play a crucial role.
Literature
a) Handouts from the lecturer
b) Literature list form the lecture (if necessary)
c) www.search
Managing Complexity
Type
Lecture/seminar
Nr.
M+V3032
Hours
2.0
per week
Lecture
The course is designed to provide a fundamental basis for management
contents
and leadership in the information age. It will introduce a scientific and
philosophical approach to management that emphasises the importance of
theory and teaches that management is prediction. It explores the
historical origins of an analytical methodology for transforming raw data
into knowledge that allows profound insight into the behaviour of
processes and systems and thus secures a sound basis for future action.
Case histories will demonstrate how the costly errors of inappropriate
action and sub-optimisation can be avoided and how a scientific basis for
continual improvement in quality of product and service and hence
sustainable competitiveness is achieved.
Links to system thinking, human behaviour (knowledge of psychology) and
the theory of knowledge (epistemology) will be maintained throughout the
course.
Literature
WHEELER, Donald J.: Understanding Variation - The Key to Managing
Chaos, 2. ed. Knoxville, Tenn. : SPC Press Inc, 2000.
WHEELER, Donald J.: Advanced Topics in Statistical Process Control,
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Knoxville, Tenn.: SPC Press Inc, 1995.
DEMING, Edwards, W.: Out of the Crisis, 2. ed. Boston, MA :
Massachusetts Institute of Technology, 2000.
NEAVE, Henry, R.: The Deming Dimension, Knoxville, Tenn. : SPC Press
Inc, 1990.
SCHOLTES, Peter, R.: The Leaders Handbook, New York : McGraw Hill,
1998.
DEMING, Edwards, W.: The New Economics, 2. ed. Boston, MA :
Prozessleittechnik
Type
Lecture
Nr.
M+V3026
Hours
2.0
per week
Lecture
A) The automation pyramid
contents
B) Norms and regulations
C) The most relevant DCS systems
D) Sensors and actuators
E) Fieldbus systems
F) Controller Level
G) DCS Level
Literature
SCHILDT, H.-H., KASTNER, W.: Prozeßautomatisierung. Berlin : Springer,
1998.
POLKE, M. (ED.): Process Control Engineering. Weinheim : VCh, 1994.
Siemens: Manual of Siemens Simatic PCS 7, part 1 and 2.
Available online:
http://www.pacontrol.com/siemens-manuals/Process-Control-System-PCS-7Part1.pdf
http://www.pacontrol.com/siemens-manuals/Process-Control-System-PCS-7-Part2.p
Labor Energiewandlung mit Biomasse
Type
Lab
Nr.
M+V3014
Hours
2.0
per week
Lecture
A) Basics:
contents
- analysis of exhaust gases
- calorific value measurements of solid, liquid and gaseous fuels
- immediate analyse of fuels
B)Thermal treatment by pyrolysis in the fixed bed
C)Thermal treatment by gasification in the pit reactor
D) Inertisation by vitrification and solidification
E) Balance of a firing process.
F) Gas development during fermentation process (methanisation)
Literature
KALTSCHMITT, M.; HARTMANN, H.; HOFBAUER, H. (Hrsg.): Energie aus
Biomasse - Grundlagen, Techniken und Verfahren. 2. Auflage, Berlin :
Springer, Heidelberg, 2009.
DEUBLEIN, D., STEINHAUSER, A.:Biogas from Waste and Renewable
Resources, 2nd ed. Weinheim : Wiley-VCH, 2010.
Advanced Thermal Systems
Teaching methods
Learning target
Lecture
Module Advanced Thermal Systems deepens the understanding of energy systems with respect to
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Campus Gengenbach
Campus Offenburg
transient behavior. As the role of energy storages is increasing in future decentralized energy
systems, the students get a deeper insight into energy storage. The students are aware of the
different types of thermal energy storages and understand their limits regarding temperature
ranges, energy density, charging and discharging. The students can select appropriate storages
for respective applications. The students know a systematic approach to access the transient
behavior of thermal systems. They are able to formulate a set of differential equations for thermal
systems and to solve initial value problems by Computer-Algebra-Tools.
Duration
Hours per week
Overview
ECTS
Max. participants
Recommended
semester
Frequency
Lectures
1 Semester
4.0
Classes:
Individual/
Group work:
Workload:
4.0
25
ECM 3
60 h
60 h
120 h
Annually (ws)
Vertiefung Thermische Energiesysteme
Type
Lecture/seminar
Nr.
M+V3043
Hours
4.0
per week
Lecture
1. Fluid machinery in thermal systems
contents
positive displacement and turbo machinery
2. Thermal energy storages
3. Combined heat and power
4. Transient behaviour of thermal systems
5. Solving problems in thermal system engineering
Literature
CENGEL, Y. A., BOLES, Ma. A: Thermodynamics - An Engineering
Approach. New York : McGraw Hill, 2008.
KALIDE, W.: Energieumwandlung in Kraft- und Arbeitsmaschinen. München
: Hanser, 2005.
STOECKER, W. F.: Design of Thermal Systems. New York : McGraw-Hill,
1989.
TILLER, M.D .: Introduction to physical modeling with Modelica. Norwell
(MA) : Kluwer Academica Publishers, 2004.
Project Planning of Energy Facilities
Teaching methods
Learning target
Lecture
Energy facilities must be looked on having technical, economical, legislative and operational
requirements in mind, which according to the long life time of the facilities eventually change
several times, e.g. because of changing emission and/or safety standards, etc. The students learn
about the impact of such changes and are able to anticipate proper reaction to future
developments by means of a business game.
Designing of energy facilities is complex and therefore supported by Computer Aided Engineering
(CAE) Tools instead of building plant models in small scale. The students learn about the
application of Computer Aided Design (CAD) in project planning of energy facilities, especially
about object-oriented tools, which support processes lasting from first design until delivery of parts.
Duration
Hours per week
Overview
1 Semester
8.0
Classes:
120 h
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12/30
Campus Gengenbach
ECTS
Responsible
person
Max. participants
Recommended
semester
Frequency
Lectures
Individual/
Group work:
120 h
Workload:
240 h
Campus Offenburg
8.0
Prof. Dr. Jens Pfafferott
25
ECM 3
Annually (ws)
Planung und Betrieb energietechnischer Anlagen
Type
Lecture
Nr.
M+V3044
Hours
4.0
per week
Lecture
1. Introduction
contents
2. Legislative background (BGB, contracts)
3. Requirements to obtain permission
4. Operation of power plants
5. Economic boundaries
6. Communication
7. Documentation
8. Trends in power plant technology
Literature
EL-WAKIL, M.: Powerplant Technology. New York : McGraw Hill,
1985.
KUGELER, Kurt, PHLIPPEN, Peter-W.: Energietechnik-Technische,
ökonomische und ökologische Grundlagen. Berlin : Springer, 1993.
VERBAND DER TECHNISCHEN ÜBERWACHUNGS-VEREINE E.V. (Hrsg.): TRD Technische Regeln Dampfkessel. Köln : Carl Heymanns Verlag, 2007.
LINKE, Wolfgang, MAYR, Fritz (Hrsg.): Handbuch der
Kesselbetriebstechnik - Kraft- und Wärmeerzeugung in Praxis und
Theorie. 12. Auflage, Gräfelfing : Resch, 2009.
DITTMANN, Achim, ZSCHERNIG, Joachim : Energiewirtschaft. Stuttgart :
Teubner, 1998.
DOLEŽAL, Richard : Energetische Verfahrenstechnik. Stuttgart : Teubner, 1983.
KONSTANTIN, P.: Praxisbuch Energiewirtschaft - Energieumwandlung, transport und -beschaffung im liberalisierten Markt. Berlin : Springer, 2009.
SCHIFFER, Hans-Wilhelm : Energiemarkt Deutschland. 10. Auflage, Köln :
TÜV Media, 2008.
DOLEŽAL, Richard: Kombinierte Gas- und Dampfkraftwerke. Berlin :
Springer, 2001.
Teaching methods
Learning target
Lecture
Duration
1 Semester
Hours per week
4.0
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13/30
Campus Gengenbach
Overview
Classes:
Individual/
Group work:
Workload:
ECTS
Responsible
person
Max. participants
Recommended
semester
Frequency
Lectures
Campus Offenburg
60 h
60 h
120 h
4.0
25
ECM 3
Annually (ws)
Type
Lecture
Nr.
M+V926
Hours
2.0
per week
Lecture
contents
balances, examples
Literature
Type
Lecture
Nr.
M+V927
Hours
2.0
per week
Lecture
contents
recycling)
Literature
Safety Engineering
Type
Lecture
Nr.
M+V912
Hours
2.0
per week
Lecture
contents
16 Jan 2017 00:58:43
14/30
Campus Gengenbach
Campus Offenburg
devices)
Literature
Type
Lecture
Nr.
M+V3015
Hours
2.0
per week
Lecture
contents
Production)
Production)
Literature
ISBN 978-1-441-90369-3
PPN 327001704
Type
Lecture/seminar
Nr.
M+V3007
Hours
2.0
per week
Lecture
contents
the game.
Literature
Management)
Type
Lecture
Nr.
M+V3025
Hours
2.0
per week
Lecture
contents
16 Jan 2017 00:58:43
15/30
Campus Gengenbach
Literature
Campus Offenburg
Type
Lecture/seminar
Nr.
M+V3031
Hours
2.0
per week
Lecture
Communication
contents
Rhetorics
- Speech, Voice
Presentations
Literature
2006.
2006.
McGrawHill, 2005.
Type
Lecture/seminar
Nr.
M+V3010
Hours
2.0
per
week
16 Jan 2017 00:58:43
16/30
Campus Gengenbach
Campus Offenburg
7. Risikomanagement
Energielieferanten
Type
Lecture/seminar
Nr.
M+V3008
Hours
2.0
per week
Lecture
contents
Literature
c) www.search
Managing Complexity
Type
Lecture/seminar
Nr.
M+V3032
Hours
2.0
per week
Lecture
contents
course.
Literature
16 Jan 2017 00:58:43
17/30
Campus Gengenbach
Campus Offenburg
Inc, 1990.
1998.
Prozessleittechnik
Type
Lecture
Nr.
M+V3026
Hours
2.0
per week
Lecture
contents
E) Fieldbus systems
F) Controller Level
G) DCS Level
Literature
1998.
Available online:
Type
Lab
Nr.
M+V3014
Hours
2.0
per week
Lecture
A) Basics:
contents
Literature
Teaching methods
Learning target
Lecture
16 Jan 2017 00:58:43
18/30
Campus Gengenbach
Campus Offenburg
Duration
Hours per week
Overview
ECTS
Max. participants
Recommended
semester
Frequency
Lectures
1 Semester
4.0
Classes:
Individual/
Group work:
Workload:
4.0
25
ECM 3
60 h
60 h
120 h
Annually (ws)
Type
Lecture
Nr.
M+V926
Hours
2.0
per week
Lecture
contents
balances, examples
Literature
Type
Lecture
Nr.
M+V927
Hours
2.0
per week
Lecture
contents
recycling)
Literature
Safety Engineering
Type
Lecture
Nr.
M+V912
Hours
2.0
16 Jan 2017 00:58:43
19/30
Campus Gengenbach
per week
Lecture
contents
Campus Offenburg
devices)
Literature
Type
Lecture
Nr.
M+V3015
Hours
2.0
per week
Lecture
contents
Production)
Production)
Literature
ISBN 978-1-441-90369-3
PPN 327001704
Type
Lecture/seminar
Nr.
M+V3007
Hours
2.0
per week
Lecture
contents
the game.
Literature
Management)
Type
Lecture
Nr.
M+V3025
Hours
2.0
per week
Lecture
16 Jan 2017 00:58:43
20/30
Campus Gengenbach
Campus Offenburg
contents
Literature
Type
Lecture/seminar
Nr.
M+V3031
Hours
2.0
per week
Lecture
Communication
contents
Rhetorics
- Speech, Voice
Presentations
Literature
2006.
2006.
McGrawHill, 2005.
Type
Lecture/seminar
Nr.
M+V3010
Hours
2.0
per
week
16 Jan 2017 00:58:43
21/30
Campus Gengenbach
Campus Offenburg
7. Risikomanagement
Energielieferanten
Type
Lecture/seminar
Nr.
M+V3008
Hours
2.0
per week
Lecture
contents
Literature
c) www.search
Managing Complexity
Type
Lecture/seminar
Nr.
M+V3032
Hours
2.0
per week
Lecture
contents
course.
Literature
16 Jan 2017 00:58:43
22/30
Campus Gengenbach
Campus Offenburg
Inc, 1990.
1998.
Prozessleittechnik
Type
Lecture
Nr.
M+V3026
Hours
2.0
per week
Lecture
contents
E) Fieldbus systems
F) Controller Level
G) DCS Level
Literature
1998.
Available online:
Type
Lab
Nr.
M+V3014
Hours
2.0
per week
Lecture
A) Basics:
contents
Literature
Teaching methods Lecture
16 Jan 2017 00:58:43
23/30
Campus Gengenbach
Campus Offenburg
Learning target
Duration
Hours per week
Overview
1 Semester
6.0
ECTS
Responsible
person
Max. participants
Recommended
semester
Frequency
Lectures
Classes:
Individual/
Group work:
Workload:
6.0
90 h
90 h
180 h
25
ECM 3
Annually (ws)
Type
Lecture
Nr.
M+V926
Hours
2.0
per week
Lecture
contents
balances, examples
Literature
Type
Lecture
Nr.
M+V927
Hours
2.0
per week
Lecture
contents
recycling)
Literature
16 Jan 2017 00:58:43
24/30
Campus Gengenbach
Campus Offenburg
Safety Engineering
Type
Lecture
Nr.
M+V912
Hours
2.0
per week
Lecture
contents
devices)
Literature
Type
Lecture
Nr.
M+V3015
Hours
2.0
per week
Lecture
contents
Production)
Production)
Literature
ISBN 978-1-441-90369-3
PPN 327001704
Type
Lecture/seminar
Nr.
M+V3007
Hours
2.0
per week
Lecture
contents
the game.
Literature
Management)
16 Jan 2017 00:58:43
25/30
Campus Gengenbach
Campus Offenburg
Type
Lecture
Nr.
Hours
per week
Lecture
contents
M+V3025
2.0
Literature
Type
Lecture/seminar
Nr.
M+V3031
Hours
2.0
per week
Lecture
Communication
contents
Rhetorics
- Speech, Voice
Presentations
Literature
2006.
2006.
McGrawHill, 2005.
Type
Lecture/seminar
Nr.
M+V3010
Hours
2.0
per
week
16 Jan 2017 00:58:43
26/30
Campus Gengenbach
Campus Offenburg
7. Risikomanagement
Energielieferanten
Type
Lecture/seminar
Nr.
M+V3008
Hours
2.0
per week
Lecture
contents
Literature
c) www.search
Managing Complexity
Type
Lecture/seminar
Nr.
M+V3032
Hours
2.0
per week
Lecture
contents
16 Jan 2017 00:58:43
27/30
Campus Gengenbach
Campus Offenburg
course.
Literature
Inc, 1990.
1998.
Prozessleittechnik
Type
Lecture
Nr.
M+V3026
Hours
2.0
per week
Lecture
contents
E) Fieldbus systems
F) Controller Level
G) DCS Level
Literature
1998.
Available online:
Type
Lab
Nr.
M+V3014
Hours
2.0
per week
Lecture
A) Basics:
contents
Literature
16 Jan 2017 00:58:43
28/30
Campus Gengenbach
Campus Offenburg
Scientific Project
Teaching methods
Learning target
internship
Within the Scientific Project the foreign students shall experience the working culture of companies
or institutions working in the energy sector whereas the German students shall explore
international aspects of the energy sector. The students shall apply their theoretical knowledge
when working on a first scientific question. After completing the Scientific Project the student shall
understand the strong interaction between economics and technology in the energy sector.
Duration
Hours per week
Overview
1 Semester
0.0
ECTS
Responsible
person
Max. participants
Recommended
semester
Lectures
Classes:
Individual/
Group work:
Workload:
30.0
450 h
450 h
900 h
0
ECM 2
Wissenschaftliches Projekt
Type
Project
Nr.
M+V3033
Master's Thesis
Teaching methods
Learning target
Thesis/seminar
On the successful completion of the master thesis the student shall be able: to elaborate a course
of action in order to solve the scientific task definition of the thesis, to become acquainted with the
frame of a scientific field within a limited time, to use scientific methods when working on complex
problems, to write a scientific report and to defend its chosen procedure and results obtained.
Duration
Hours per week
Overview
1 Semester
0.0
ECTS
Responsible
person
Max. participants
Recommended
semester
Frequency
Lectures
Classes:
Individual/
Group work:
Workload:
30.0
450 h
450 h
900 h
0
ECM 4
Annually (ss)
Master-Arbeit
Type
Thesis
Nr.
M+V3035
Präsentation und Verteidigung
Type
Seminar
Nr.
M+V3035
16 Jan 2017 00:58:43
29/30
Campus Gengenbach
Campus Offenburg
16 Jan 2017 00:58:43
30/30

Module description

Transcription

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