Course title: Engineering Mathematics I · • Schmidt: Grundlagen der Geotechnik, Teubner Verlag...
Transcript of Course title: Engineering Mathematics I · • Schmidt: Grundlagen der Geotechnik, Teubner Verlag...
Course title: Engineering Mathematics I
Course code: IEB 1011
Type of course: Lecture
Level of course: Bachelor
Year of study: First year
ECTS Credits:
6
Semester: 1st Semester
Name of the lecturer: Claudia Tack
Course contents:
- Functions of one and multiple variables - Differential and Integral Calculus of one and multiple variables - Financial Mathematics
Prerequisites: None
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of mathematical methods, have practical experience in using mathematical methods, be able to interpret mathematical results, be able to deal with abstract problems, be able to utilise the gained data in software environments.
Language of instruction: German
Teaching methods: Lecture supported by a script, blackboard notes and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: - script - Papula, L.: Mathematik für Ingenieure und Naturwissenschaftler - Dürrschnabel, K..: Mathematik für Ingenieure
Course title: Mechanics
Course code: IEB 1021
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: First year
ECTS Credits:
6
Semester: 1st Semester
Name of the lecturer: Prof. Jan Akkermann
Course contents:
Loads on structures, force vectors, static friction, coplanar force systems, parallel force systems, general force systems, center of gravity and centroid, structural supports, statical determinancy, internal forces (straight, sloped and kinked beams, pin-jointed beams, frames), pin-jointed systems and trusses. Strength of Materials: Basic terms, tension and compression, moment of an area, bending, torsion, shear loads, composite loads, stability.
Prerequisites: High school Mathematics and Physics
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
understand the basics of Statics, be able to qualitatively and quantitatively determine reactions and
internal forces of statically determinate systems, be able to model statical systems and to formulate the necessary
equilibrium conditions, be able to determine internal forces and to calculate reaction
forces, hinge forces and internal forces of statically determinate structures such as trusses, beams and frames, understand the performance of components under various loads such as uniaxial and biaxial bending and thrust, shear and torsion,
be able to handle an assignment ranging from the studies in an appropriate time.
Language of instruction: German
Teaching methods: Lecture supported by a script, task-collection, transparencies, blackboard notes and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: Will be announced in the lecture.
Course title: Geomatics
Course code: IEB 1031
Type of course: Lecture and Field Work
Level of course: Bachelor
Year of study: First year
ECTS Credits:
6
Semester: 1st Semester
Name of the lecturer: Dr. Michael Mayer
Course contents:
- methods of measurement - earth representation in planes - systems of measurement - cartography - tolerances in measurements
Prerequisites: None
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
be able to interpret and determine geometrical data as to their quality and quantity,
be able to conduct basic geometrical measuring and data collection.
Language of instruction: German
Teaching methods: Lecture supported by a script, task-collection, transparencies, blackboard notes and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: • Bauer, M.: Vermessung und Ortung mit Satelliten, Wichmann • Bernard, L. et al.: Geodateninfrastruktur, Wichmann • Hake, G. und Grünreich, D.: Kartographie, de Gruyter • Hennermann, K.: Kartographie und GIS, Wiss. Buchgesellschaft • Kahmen, H.: Vermessungskunde, de Gruyter • Kohlstock, P.: Topographie, de Gruyter • Kohlstock, P.: Kartographie • Matthews, V.: Vermessungskunde, 2 Bände, Teubner • Resnik, B. und Bill, R.: Vermessungskunde für den Planungs-, Bau- und Umweltbereich, Wichmann • Witte, B. und Schmidt, H.: Vermessungskunde und Grundlagen der Statistik, Wittwer
Course title: Natural Sciences
Course code: IEB 1032
Type of course: Lecture
Level of course: Bachelor
Year of study: First year
ECTS Credits:
6
Semester: 1st Semester
Name of the lecturer: Prof. Dr. Andreas Gerdes (Environmental Chemistry) Dr. Andreas Thiem (Environmental Biology)
Course contents:
- dispersal of chemical and biological contaminants in the ground, water and atmosphere
- impacts on humans, environment and infrastructure facilities - avoidance and minimisation of contaminants
Prerequisites: None
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of the dispersal of chemical and biological contaminants in the ground, water and atmosphere,
have background knowledge of the impacts on humans, environment and infrastructure facilities of contaminants.
Language of instruction: German
Teaching methods: Lecture supported by a script, task-collection, blackboard notes, one-day excursions and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: V. Koß: Umweltchemie - Eine Einführung für Studium und Praxis, Springer Verlag, 1. Auflage, 1997
K. Fent: Ökotoxikologie – Umweltchemie, Toxikologie, Ökologie, Thieme Verlag, 2. Auflage, 2007
G. Schwendt: Taschenatlas der Umweltchemie, Wiley-VCH-Verlag, 1. Auflage 1996
C. Bliefert: Umweltchemie, Wiley-VCH-Verlag, 3. Auflage, 2002 W. Reineke, M. Schlömann: Umweltmikrobiologie, Spektrum
Akademischer Verlag, 1. Auflage, 2006 H.-D. Janke: Umweltbiotechnik, UTB Verlag, 1. Auflage, 2002 H. Cypionka: Grundlagen der Mikrobiologie, Springer Verlag, 4. Auflage,
2010
Course title: Construction Materials
Course code: IEB 1041
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: First year
ECTS Credits:
6
Semester: 1st Semester
Name of the lecturer: Prof. Stefan Linsel Prof. Jan Akkermann
Course contents:
• Material structure • Macroscopic and microscopic observations • Material production, material behaviour and properties • Corrosion • Physical properties of materials • Basics for durability and serviceability • Optimal selection of materials • Introduction to concrete technology • Metals and Wood in Construction • Building within existing structures (supplemented by demonstration lectures in the laboratories of the Construction Materials Testing Center)
Prerequisites: None
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
be acquainted with the topics mentioned above.
Language of instruction: German
Teaching methods: • Blackboard notes • Powerpoint presentations • Film material
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: • established scientific works on construction materials, • Issues of trade associations of the building materials industry • Guidelines and Data sheets dealing with repair products (e. g. of the DAfStb) • Current Journals
Course title: Engineering Mathematics II
Course code: IEB 2011
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: First year
ECTS Credits:
6
Semester: 2nd Semester
Name of the lecturer: Claudia Tack
Course contents:
- Statistics - Differential Equations - Excel / VBA
Prerequisites: None
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of mathematical methods, have practical experience in using mathematical methods, be able to interpret mathematical results, have practical experience in using a modern programming
language, be able to apply the acquired knowledge.
Language of instruction: German
Teaching methods: Lecture supported by a script, blackboard notes and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: - script - Papula, L.: Mathematik für Ingenieure und Naturwissenschaftler - Dürrschnabel, K..: Mathematik für Ingenieure
Course title: Dynamics
Course code: IEB 2021
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: First year
ECTS Credits:
6
Semester: 2nd Semester
Name of the lecturer: Prof. Jan Akkermann
Course contents:
- Dynamics - Kinematics and Kinetics - Moving Mechanics - Loads on structures
Prerequisites: High school Mathematics and Physics
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of kinematics and kinetics, be able to apply the acquired knowledge.
Language of instruction: German
Teaching methods: Lecture supported by a script, task-collection, transparencies, blackboard notes and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: Will be announced in the lecture.
Course title: Geotechnics
Course code: IEB 2051
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: First year
ECTS Credits:
6
Semester: 2nd Semester
Name of the lecturer: Prof. Christian Holldorb Stephan Johmann
Course contents:
- Subsoil investigations - Water in subsoil: flow-pressure and permeability - Settlement analyses - Shear Strength - Bearing capacity and stability of Shallow and deep foundations - Stability against ground failure, overturning and sliding - Stability of position - retaining structures - mechanical slope stabilisations, - securing excavation - calculation of earth pressure (theories, active earth pressure, at-
rest earth pressure, earth resistance and special cases - bored and displacement piles - groundwater maintenance
Prerequisites: Mechanics I, Construction Materials, Hydromechanics, Load on Structures
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of geotechnical methods, have practical experience in using theoretical methods, be able to interpret results from subsoil investigations, be able to apply the acquired knowledge.
Language of instruction: German
Teaching methods: Lecture supported by a script, task-collection, transparencies, blackboard notes and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: • Gudehus: Physical Soil Mechanics, Springer Verlag Verlag • Gudehus: Bodenmechanik, Enke Verlag • Ziegler: Geotechnische Nachweise an Beispielen • Lang/Huder/Amann: Bodenmechanik und Grundbau, Springer Verlag • Möller: Geotechnik, Werner Verlag • Schmidt: Grundlagen der Geotechnik, Teubner Verlag • Schulze/Simmer: Grundbau, Teuber Verlag • Smoltzyk [Herausgeber]: Grundbautaschenbuch, Ernst & Sohn • Arbeitsblätter und Skriptum zur Vorlesung • Dörken/Dehne: Grundbau in Beispielen, Werner Verlag • Smoltzyk [Herausgeber]: Grundbautaschenbuch, Ernst& Sohn • Skriptum Bodenmechanik (BIB 2061) Arbeitsblätter und Skripten Grundbau • Arbeitsblätter und Skripten Grundbau
Course title: Fluid Mechanics
Course code: IEB 2061
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: First year
ECTS Credits:
6
Semester: 2nd Semester
Name of the lecturer: Prof. Norbert Eisenhauer
Course contents:
- Main principles of fluid mechanics - Main principles of gas dynamics - Main principles of thermodynamics - Main principles of channel and pipe hydraulics
Prerequisites: None
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
know the fundamental principles of fluid mechanics, be able to use fluid mechanics to analyse and solve practical
problems.
Language of instruction: German
Teaching methods: Lecture supported by a script, task-collection, transparencies, blackboard notes, film material and computer presentations. (supplemented by demonstration lectures in the laboratory of hydraulic engineering)
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: • Heinemann/Paul: Hydromechanik für Bauingenieure, Teubner-Verlag, 1998 • Schröder: Grundlagen des Wasserbaus, Werner-Verlag1999 • Strybny: Keine Panik-Strömungsmechanik, Vieweg-Verlag 2003 • Bollrich, Technische Hydromechanik 1-2, Verlag Bauwesen 1996 • Egon Krause: Strömungslehre, Gasdynamik und Aerodynamisches Laboratorium, Teubner-Verlag, 2003 • Ernst Doering et al.: Grundlagen der technischen Thermodynamik. Lehrbuch für Studierende der Ingenieurwissenschaften. Teubner-Verlag, 2005 • Further literature listed in lecture notes
Course title: Building Physics and Building Construction
Course code: IEB 2041
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: First year
ECTS Credits:
6
Semester: 2nd Semester
Name of the lecturer: Prof. Jan Akkermann
Course contents:
Building Physics: • Heat: heat transport, heat resistance, U-value of building constructions,
thermal bridges, basics of EnEV (German Energy Saving Regulation) • Humidity: fundamental terms (relative humidity, water content, ...),
dew point, condensation, transport of humidity (capillar transport, diffusion, …)
• Sound: fundamental terms (sound as a wave, sound level, frequency spectrum,…), technical terms (sound insulation, sound absorption, reverberation time)
Building Physics: • Main Principles in structural design • Structural components • walls, ceilings, ring beams • slabs, beams, sidings, balconies, loggias • floor constructions, screeds, stairs, windows, doors, roofs • structural physics • construction in existing contexts
Prerequisites: None
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of building physics (heat, humidity, sound and fire protection),
have practical experience in using calculation methods, have background knowledge of the main principles of
performance and selection of construction materials, be able to estimate construction materials under various
conditions due to bearing strength, serviceability and durability.
Language of instruction: German
Teaching methods: Lecture supported by a task-collection, blackboard notes, and computer presentations. (supplemented by demonstration lectures)
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: Current editions of: • EnEV • Lohmeyer, G. u.a.: Praktische Bauphysik, Teubner Verlag, • W. Bläsi, Bauphysik, Europa Lehrmittel-Verlag, Haan Gruiten • Fricke / Knöll: Baukonstruktionslehre Teil 1 und 2 – Teubner-Verlag • Dierks / Schneider / Wormuth: Baukonstruktion – Werner-Verlag • Neufert: Bauentwurfslehre – Vieweg-Verlag
Course title: Energy Infrastructure
Course code: IEB 3071
Type of course: Lecture
Level of course: Bachelor
Year of study: Second year
ECTS Credits:
6
Semester: 3rd Semester
Name of the lecturer: Prof. Jan Akkermann Dr. Engin Kotan
Course contents:
- Energy sources - Fundamentals of power plant technology - Fundamentals of regenerative power generation - Basics of energy storage - Thermic energy: heat store - Chemic energy: accumulators, hydrogen technology - Mechanic energy: flywheel accumulator, pumped-storage
hydropower plants - Fundamentals of energy distribution - Electricity grid - Gas grid
Prerequisites: None
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of the energy sector’s demands (energy generation, storage and distribution) and relevant constructions and facilities,
have background knowledge of theoretical aspects such as the implementation of the key principles regarding energy supply,
be able to understand the methods of running and maintenance of infrastructure facilities,
be able to apply the acquired knowledge.
Language of instruction: German
Teaching methods: Lecture supported by a script, task-collections, blackboard notes, computer presentations and one-day excursions.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: • G. Herold: Grundlagen der elektrischen Energieversorgung, Teubner Verlag, 2. Auflage, 2002 • E. Rebhan: Energiehandbuch: Gewinnung, Wandlung und Nutzung von Energie, Springer Verlag, 1. Auflage, 2002 • V. Quaschning: Regenerative Energiesysteme: Technologie – Berechnung – Simulation, Carl Hanser Verlag, 7. Auflage, 2011 • R. Gasch et al.: Windkraftanlagen: Grundlagen, Entwurf, Planung und Betrieb, Vieweg und Teubner, 7. Auflage, 2011 • K. Mertens: Photovoltaik: Lehrbuch zu Grundlagen, Technologie und Praxis, Carl Hanser Verlag, 1. Auflage, 2006 • K. Strauß: Kraftwerkstechnik: zur Nutzung fossiler, nuklearer und regenerativer Energiequellen, Springer Verlag, 6. Auflage, 2009 • G. Cerbe: Grundlagen der Gastechnik: Gasbeschaffung – Gasverteilung – Gasverwendung, Carl Hanser Verlag, 7. Auflage, 2008 • P. Konstantin: Praxisbuch Energiewirtschaft: Energieumwandlung, -transport und –beschaffung im liberalisierten Markt, Springer Verlag, 2. Auflage, 2009
Course title: Construction Engineering
Course code: IEB 3081
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: Second year
ECTS Credits:
6
Semester: 3rd Semester
Name of the lecturer: Prof. Jan Akkermann
Course contents:
Fundamentals: - comparison of materials - materials’ principle area of application - advantages and disadvantages (fire protection, heat and sound
insulation) Reinforced Concrete Design:
- main principles of construction - design (column, beam, slabs) - design / notation of details - construction work and structural damage
Steel Design: - main principles of construction - design (column, beams) - design / notation of details
Timber Structures: - main principles of construction - design (roof structures)
- design / notation of details - construction work and structural damage
Masonry Construction: - main principles of construction - construction work and structural damage
Prerequisites: Mechanics, Construction Materials
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of reinforced concrete design, steel design, timber structures and masonry construction,
be able to practically apply the acquired knowledge, comprehend the load-bearing capacity and serviceability of
reinforced concrete, steel, timber and masonry structures in civil engineering.
Language of instruction: German
Teaching methods: Lecture supported by a script, exercise sheets, blackboard notes, transparencies and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: • DIN-EN 1990 bis 1996 • Goris, Stahlbetonbau Praxis • Wagenknecht, Stahlbau Praxis • Steck /Nebgen Holzbau kompakt • Schubert, Schneider Schoch Mauerwerksbau Praxis
Course title: Transport Infrastructure
Course code: IEB 3091
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: Second year
ECTS Credits:
6
Semester: 3rd Semester
Name of the lecturer: Prof. Christian Holldorb
Course contents:
- fundamentals of mobility - demands of traffic participants and public transportation - planning processes - design of urban street areas - legal frameworks and financing - stopping points and train stations
- earthwork and road construction - traffic surveys and analysis - design of rural traffic facilities - capacity of traffic junctions without a light-signal system
Prerequisites: None
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of the tasks, constructions and facilities regarding transport infrastructure,
comprehend the fundamental correlations of mobility, urban traffic, public transportation and road construction in civil engineering.
Language of instruction: German
Teaching methods: Lecture supported by a script, exercise sheets, blackboard notes, transparencies and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: �Richtlinien für die Anlage von Stadtstraßen (RASt) �Empfehlungen für Anlagen des öffentlichen Personennahverkehrs (EAÖ) � Richtlinien für die Standardisierung des Oberbaus von Verkehrsflächen (RStO) �Skript �Technische Lieferbedingungen, Technische Prüfvorschriften und Zusätzliche Technische Vertragsbedingungen und Richtlinien zum Erdbau, zu Schichten ohne Bindemittel sowie zu Asphalt, Beton- und Pflasterbauweisen � Eisenmann, J.: Leykauf, G.: Betonfahrbahnen. 2. Auflage, Ernst-Verlag, Berlin, 2003. � Velske,S. et al.: Straßenbautechnik, 5. überarb. Auflage, Werner Verlag, Düsseldorf, 2002. � Elsner Handbuch für Straßen- und Verkehrswesen, Otto Elsner Verlagsgesellschaft � Handbuch für die Bemessung von Straßenverkehrsanlagen (HBS) � Empfehlungen für Verkehrserhebungen (EVE) � Richtlinien für den Entwurf von Knotenpunkten (RAS-K) � Richtlinien für die Anlage von Straßen – Teil: Linienführung (RAS-L)
Course title: Hydro Infrastructure
Course code: IEB 3101
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: Second year
ECTS Credits:
6
Semester: 3rd Semester
Name of the lecturer: NN
Course contents:
- hydrological planning - fundamentals of urban water management
(water supply and sanitation) - hydraulic engineering
(flood control, maritime traffic and waterpower engineering)
Prerequisites: Module Fluid Mechanics IEB 2061
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have gained all the relevant theoretical background knowledge in the field of water supply and sanitation engineering, flood control, maritime traffic and waterpower engineering.
be able to apply the main principles and methods related to the
concept and design hydro infrastructure facilities.
Language of instruction: German
Teaching methods: Lecture supported by a script, task-collection, exercise sheets, blackboard notes, computer presentations and one-day excursions.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: • G. Martz: Siedlungswasserbau – Teil 1 Wasserversorgung / Abwasserentsorgung: • DWA (früher ATV-DVWK): ATV-Handbücher zu folgenden Themen: • Planung, Bau und Betrieb der Kanalisation • Mechanische Abwasserreinigung • Biologische und weitergehende Abwasserreinigung • Klärschlamm • Betriebstechnik, Kosten und Rechtsgrundlagen der Abwasserreinigung • Karl und Klaus R. Imhoff: Taschenbuch der Stadtentwässerung, 29. Auflage, 1999 • W. Hosang, W. Bischof: Abwassertechnik, 11. Auflage, 1998 • G. Martz: Siedlungswasserbau – Teil 2 Kanalisation • G. Martz: Siedlungswasserbau – Teil 3 Klärtechnik • Patt: Hochwasserhandbuch; Springer-Verlag 2001 • Giesecke, Mososnyi: Wasserkraftanlagen, Springer-Verlag 1997 • Partenscky: Binnenverkehrswasserbau, Springer-Verlag 1986 • Bundesanstalt für Wasserbau: Diverse Mitteilungen • further references in the script
Course title: Damage Analysis
Course code: IEB 3111
Type of course: Lecture, practical exercises and project work
Level of course: Bachelor
Year of study: Second year
ECTS Credits:
6
Semester: 3rd Semester
Name of the lecturer: Prof. Jan Akkermann, Prof. Dr. Andreas Gerdes
Course contents:
Lecture: Corrosion of building materials: - selected basics of chemistry (e. g. acid- base reaction, solutions,
gases) - materials in civil engineering: selected properties (e. g. porosity,
permeability, chemical reactivity) - basics of reactive transport of structural damaging connections - effect of concrete corrosive water (“lime dissolving carbonic acid”,
soft water) on mineral materials - carbonisation of reinforced concrete - chlorine induced corrosion of reinforced concrete structures - alkali-aggregate reaction - freeze-thaw and freeze-thaw de-icing salt attacks - corrosion processes on masonry and stonework - corrosion of metallic materials (e. g. steel, copper, aluminium) - corrosion of polymeric materials (e. g. thermosetting resins,
thermoplastics) - organic damaging processes (e. g. organic formations of sulphuric
acid, biofilms of facades) - preventive measures in buildings of technical infrastructure - selected case studies of the fields of technical infrastructure
(drinking water reservoirs, swimming pools, bridges) Practical lessons: State Analysis built structures Using modern instruments, selected parameters will be determined in practical lessons. Material technological parameters:
- water absorption coefficient of mineral materials - capillary porosity of mineral materials - permeability of concrete
Mechanical parameters: - pressure resistance of building materials - elastic modulus of building materials - adhesive tensile strength of the system concrete/coat
Evaluation of damaging causes: - carbonisation - structural damaging salts - chloride induced corrosion
Risk assessment/sustainability: - reinforcement cover - measurement of the potential field - Ca(OH)2- and CaCO3-concentration
Instrumental analytical chemistry: - light and electron microscopy - high pressure mercury intrusion - x-ray diffraction - ion chromatography - thermogravimetry - radar and ultrasonic devices
Exercises: Project In the framework of the project the students work on real buildings developing concepts for state analysis, evaluating results and examining sources of structural damage.
Prerequisites: Modules Naturals Sciences and Construction Materials
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of scientific and technical fundamentals, which are relevant in terms of harming processes to buildings and their analyses.
have background knowledge of scientific and technical basics for the modules or rather activities of “Restoration”, “Energy” and “Construction” in order to refurbish existing damage in sustainable manner or rather to avoid it by preventive measures when planning.
obtain knowledge of chemical, physical and biological structural damaging effects on buildings and their detection on the building using methods and processes on site and in the laboratory for the purpose of preparation of the refurbishment measures.
Language of instruction: German
Teaching methods: Lecture supported by a script, exercise sheets, blackboard notes, transparencies and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: • H.K. Cammenga, J. Daum, C. Gloistein, U. Gloistein, A. Steer, B. Zielasko: Bauchemie – eine Einführung für das Studium, Vieweg Verlag, Braunschweig, 1996 • R. Benedix, Bauchemie: Einführung in die Chemie für Bauingenieure, 2. Aufl., B.G. Teubner, Stuttgart, 2003 • Kurt Schönburg, Korrosionsschutz am Bau, Fraunhofer IRB Verlag, 2006, Stuttgart • Silvia Weber, Betoninstandsetzung, Baustoff-Schadensfeststellung – Instandsetzung, Vieweg + Teubner Verlag, Wiesbaden 2009
Course title: Energy Management
Course code: IEB 4071
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: Third year
ECTS Credits:
6
Semester: 4th Semester
Name of the lecturer: NN
Course contents:
Energy Management: - operation, conservation and maintenance of energy generating
infrastructures (gas extraction, power plants, renewable energy sources)
- operation, conservation and maintenance of energy storage and distribution infrastructures (heat stores, accumulators, pumped-storage hydropower plants, condensers, electricity and gas grid)
Prerequisites: Module Energy Infrastructure (IEB 3071)
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of the tasks and methods of operation, conservation and maintenance of energy management infrastructure (energy generation, conversion, storage and distribution)
Language of instruction: German
Teaching methods: Lecture supported by a script, exercise sheets, blackboard notes, one day excursions and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: • K. Heuck, K.-D. Dettmann, D. Schulz: Elektrische Energieversorgung: Erzeugung und Verteilung elektrischer Energie für Studium und Praxis, Vieweg und Teubner Verlag, 8. Auflage, 2010 • S. Heier: Windkraftanlage: Systemauslegung, Netzintegration und Regelung, Vieweg und Teubner Verlag, 5. Auflage, 2009 • H.-J. Allelein, E. Bollin, H. Oehler, U. Schelling, R. Zahoransky: Energietechnik: Systeme zur Energieumwandlung, Vieweg und Teubner Verlag, 5. Auflage, 2010 • V. Quaschning: Erneuerbare Energien und Klimaschutz: Hintergründe – Techniken – Anlagenplanung – Wirtschaftlichkeit, Carl Hanser Verlag, 2. Auflage, 2009 • R. Flosdorff, G. Hilgarth: Elektrische Energieverteilung, Vieweg und Teubner Verlag, 9. Auflage, 2005 • J. Simon: Technische und wirtschaftliche Struktur der Gasversorgung in Deutschland, Grin Verlag, 1. Auflage, 2008 • R. Dolezal: Kombinierte Gas- und Dampfkraftwerke – Aufbau und Betrieb, Springer Verlag, 1. Auflage, 2001
Course title: Refurbishment
Course code: IEB 4111
Type of course: Lecture and lab work
Level of course: Bachelor
Year of study: Third year
ECTS Credits:
6
Semester: 4th Semester
Name of the lecturer: Prof. Jan Akkermann
Course contents:
- damage mechanisms in steel, wood and reinforced concrete structures: - evaluation of existing infrastructure - examination of refurbished structures
- possibilities in refurbishment with an examination of varieties - testing devices for state analyses (radar, ultrasound,…) - building site monitoring (measuring technology and sensor
systems) - refurbishment and durability models
Prerequisites: Basics of structural engineering, natural sciences, materials and damage analysis
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of modern refurbishment methods and their application
be able to examine an appropriate time of refurbishment evaluating the data obtained by a state analysis
able to evaluate the durability of different refurbishment methods be able to use modern detection devices such as radar and
ultrasound in practical lessons
Language of instruction: German
Teaching methods: Lecture supported by a script, exercise sheets, blackboard notes and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: Refurbishment guidelines e. g. of DBV, DAfStb Further reading on prevention and repair of wood, steel and reinforced concrete structures as well as relevant practical examples.
Course title: Infrastructure Construction
Course code: IEB 4091
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: Third year
ECTS Credits:
6
Semester: 4th Semester
Name of the lecturer: Prof. Christian Holldorb
Course contents:
Road Construction: - fundamentals of road construction - state analysis and evaluation of road traffic structures and
facilities
- maintenance management and refurbishment of road traffic constructions and facilities
- operation and maintenance of road traffic facilities Railway Engineering:
- fundamentals of railway engineering construction - state analysis and evaluation of railway structures and facilities - maintenance management and refurbishment of railway
constructions and facilities - operation and maintenance of railway structures
Prerequisites: Transport Infrastructure (3rd semester)
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of the tasks and methods of operation, conservation and maintenance of road traffic structures and railway engineering.
be able to examine state analyses serving as ground for a sustainable maintenance management
be able to design, maintain and evaluate infrastructure facilities of road and railway construction.
Language of instruction: German
Teaching methods: Lecture supported by a script, blackboard notes, practical project based data and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: • Handbuch für die Bemessung von Straßenverkehrsanlagen (HBS) • Richtlinien für Lichtsignalanlagen (RiLSA) • Richtlinien für den Entwurf von Knotenpunkten (RAS-K1) • Richtlinien für den Straßenoberbau (RStO) • Script
Course title: Water Management
Course code: IEB 4101
Type of course: Lecture
Level of course: Bachelor
Year of study: Third year
ECTS Credits:
6
Semester: 4th Semester
Name of the lecturer: NN
Course contents:
Urban Water Management: - operation, maintenance and conservation of infrastructure
facilities for water management (catchment, pumping, treatment, storage and distribution of water)
- operation, maintenance and conservation of infrastructure facilities for sanitation (sewage system and sewage-treatment plant)
Hydraulic Engineering:
- operation, maintenance and conservation of infrastructure facilities for hydraulic engineering (flood control, marine traffic and waterpower engineering)
Prerequisites: Fluid Mechanics (IEB 2061) and Hydro Infrastructure (IEB 3101)
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge in operating, maintaining and conserving infrastructure facilities for water management purposes (water supply, sanitation, flood control, marine traffic and waterpower engineering).
be able to apply the basic principles and methods in order to operate, maintain and conserve constructions and facilities of urban water management and hydraulic engineering.
Language of instruction: German
Teaching methods: Lecture supported by a script, blackboard notes, task-collections, one-day excursions, and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: • G. Martz: Siedlungswasserbau – Teil 1 Wasserversorgung / Abwasserentsorgung: • DWA (früher ATV-DVWK): ATV-Handbücher zu folgenden Themen: • Planung, Bau und Betrieb der Kanalisation • Mechanische Abwasserreinigung • Biologische und weitergehende Abwasserreinigung • Klärschlamm • Betriebstechnik, Kosten und Rechtsgrundlagen der Abwasserreinigung • Karl und Klaus R. Imhoff: Taschenbuch der Stadtentwässerung, 29. Auflage, 1999 • W. Hosang, W. Bischof: Abwassertechnik, 11. Auflage, 1998 • G. Martz: Siedlungswasserbau – Teil 2 Kanalisation • G. Martz: Siedlungswasserbau – Teil 3 Klärtechnik • Patt: Hochwasserhandbuch; Springer-Verlag 2001 • Giesecke, Mososnyi: Wasserkraftanlagen, Springer-Verlag 1997 • Partenscky: Binnenverkehrswasserbau, Springer-Verlag 1986 • Bundesanstalt für Wasserbau: Diverse Mitteilungen • Further references will be in the script
Course title: Project: Planning Infrastructure
Course code: IEB 4121
Type of course: Project work including presentations and CAD training
Level of course: Bachelor
Year of study: Third year
ECTS Credits:
6
Semester: 4th Semester
Name of the lecturer: Prof. Christian Holldorb, Prof. Jan Akkermann
Course contents:
The students work in groups on a practice-related project, which can be specialised by a division (structural, traffic or hydraulic engineering) or across all divisions, regarding design, dimensioning and constructional realisation. CAD knowledge
Prerequisites:
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
be able to select codes, guidelines and specific literature for the application in solving the proposed task of the project.
be able to present the results.
Language of instruction: German
Teaching methods: Lecture supported by a script, blackboard notes, models, CAD Software and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: • latest codes, guidelines, certifications and product information sheets • technical books recommended by the lecturer • manuals of the design-software • manuals of the CAD-program
Course title: Internship Preparation: Language and Presentation
Course code: IEB PV
Type of course: depends on the selected course
Level of course: Bachelor
Year of study: Third year
ECTS Credits:
4
Semester: 5th Semester
Name of the lecturer: Prof. Dr. Ingrid Rose-Neiger (Foreign Language Institute IFS), other lecturers
Course contents:
Individual training of language and rhetorical skills due to the student’s interest and preferences. However, courses benefiting for the future career are expected. The IFS exclusively offers two English courses for civil engineers. One course addresses students with very little knowledge (basic course) and the other addresses students with good English knowledge (English for Civil Engineering).
Prerequisites: Internship (IEB P)
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
be able to communicate effectively in a foreign language and in order to manage common situations of working life.
have obtained the practical-related abilities of presenting, taking part in meetings and conferences as well as informal conversations are focused on.
Language of instruction: German
Teaching methods: depend on the selected course
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: depends on the selected course
Course title: Internship
Course code: IEB P
Type of course:
Level of course: Bachelor
Year of study: Third year
ECTS Credits:
22
Semester: 5th Semester
Name of the lecturer: Prof. Hans-Joachim Walther
Course contents:
The Internship covers various areas of training: - becoming familiar with the tasks of construction management - job engineering - building construction and cost accounting - assistance in designing and dimensioning - elaboration of planning and final planning documents
Prerequisites: successful completion of the 4th semester
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
be able to apply the so far obtained knowledge. have first practical experiences in working as a civil engineer as
well as learning social skills.
Language of instruction: German
Teaching methods:
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading:
Course title: Internship Follow-up: technical-scientific reports
Course code: IEB PN
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: Third year
ECTS Credits:
4
Semester: 5th Semester
Name of the lecturer: NN
Course contents:
The focus will be on the formal requirement of writing technical-scientific reports such as composition, structure, bibliography, appendices and correct literature references.
Prerequisites:
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
be able to write technical-scientific reports such as student research projects, reports on practical experiences and final theses regarding the formal requirements.
Language of instruction: German
Teaching methods:
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading:
Course title: Decentralised Energy Concepts
Course code: IEB 6071
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: Third year
ECTS Credits:
6
Semester: 6th Semester
Name of the lecturer: NN
Course contents:
Decentralised Energy Concepts: - German Energy Saving Regulation EnEV - Solar Energy, Photovoltaic - Geothermal Energy - Wind Power - Heat Pumps
Prerequisites: Energy Infrastructure (IEB 3071) and Energy Management (IEB 4071)
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of the legal and organisational framework conditions.
have background knowledge of the different technologies and their application in order to operate decentralised energy concepts.
Language of instruction: German
Teaching methods: Lecture supported by a script, blackboard notes, task-collections, one-day excursions and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: • J. Karl: Dezentrale Energiesystem: Neue Technologien im liberalisierten Ener- giemarkt, Oldenbourg Verlag, 2. Auflage, 2006 • M. Schmidt: Dezentrale Energieversorgung: Potenzial und Wirtschaftlichkeit dezentraler Energiesysteme in Schwellenländern, VDM Verlag, 1. Auflage, 2011 • A. Lange: Dezentrale Energieversorgungssysteme, VDM Verlag, 1. Auflage, 2008 • H. Crome: Handbuch Windenergie-Technik, Ökobuch Verlag, 4. Auflage, 2012 • T. Bührke, R. Wengenmayr: Erneuerbare Energie: Alternative Energiekonzepte für die Zukunft, Wiley – VCH Verlag, 2. Auflage, 2009 • H.-J. Geist: Photovoltaik-Anlagen: planen – montieren – prüfen – warten, Elektor Verlag, 1. Auflage, 2007 • H. Ladener, F. Späte: Solaranlagen: Handbuch der thermischen
Solarenergienutzung, Ökobuch Verlag, 11. Auflage, 2008 • R. Hoffmann: Heizen mit Wärmepumpe, Franzis Verlag, 1. Auflage, 2008
Course title: Construction Operations
Course code: IEB 6081
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: Third year
ECTS Credits:
6
Semester: 6th Semester
Name of the lecturer: Prof. Dr.-Ing. Carolin Bahr
Course contents:
The lecture is divided into four major topics: cost management of building within existing structures calculation and accounting (in particular regarding analyses of
structures, elaboration of modernisation concepts as well as alternatives)
construction progress scheduling contract management with particular focus on building within
existing structures
Prerequisites: Knowledge of principal points of construction processes after Internship in the 5th semester
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of processes within conducting companies regarding construction operating focusing on building within existing structures.
have background knowledge of analysing structures, state analyses and elaborating of modernisation concepts.
have background knowledge of construction progress scheduling and accounting.
be able to deal with project requests and have background knowledge of country-specific peculiarities (also non-European).
Language of instruction: German
Teaching methods: Lecture supported by practice-related case studies, task collections, calculation software, AVA-programs and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: Examples: • [1] DBV-Merkblatt Rissbildung – Begrenzung der Rissbildung im Stahlbeton und Spannbetonbau. Deutscher Beton- und Bautechnik-Verein e.V., 2005 • [2] Dehn, F.; Holschemacher, K.; Tue; Nguyen Viet: Sanierung und Verstärkung
von Massivbauten. Innovationen im Bauwesen – Beiträge aus Praxis und Wissenschaft Bauwerk Verlag GmbH, Berlin (2007) • [3] Hankammer, Gunter: Schäden an Gebäuden – Erkennen und Beurteilen. Verlagsgesellschaft Rudolf Müller GmbH, 2. Auflage (2009) • [4] Beinhauer, P.: Standard-Detail-Sammlung Bauen im Bestand. Verlagsgesellschaft Rudolf Müller GmbH, 2. Auflage (2009) • [5] Beinhauer, P.: Standard-Detail-Sammlung Bauen im Bestand. Verlagsgesellschaft Rudolf Müller GmbH, 2. Auflage (2009) • [6] DBV-Merkblatt Beton und Betonstahl Deutscher Beton- und Bautechnik- Verein e.V., 2008 • [7] Wasser- und Feuchteschäden im Stahlbetonbau – Vermeiden, Beurteilen und Instandsetzen.(Tagungsband) Fraunhofer IRB Verlag, 2005 • [8] Häufige Fehlerquellen beim Bauen im Bestand. Heftreihe Deutscher Beton- und Bautechnik-Verein e.V., Heft 17, 2009 • [9] Typische Schäden im Stahlbetonbau – Vermeidung von Mängeln als Aufgabe der Bauleitung. Heftreihe Deutscher Beton- und Bautechnik-Verein e.V., Heft 16, 2009 • [10] Schäden im Betonbau und deren Vermeidung. Heftreihe Deutscher Beton- und Bautechnik-Verein e.V., Heft 13, 2007 • [11] DBV-Merkblatt Bauen im Bestand – Leitfaden. Deutscher Beton- und Bautechnik-Verein e.V., 2008
Course title: Logistics
Course code: IEB 6091
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: Third year
ECTS Credits:
6
Semester: 6th Semester
Name of the lecturer: Prof. Christian Holldorb
Course contents:
transport logistical production processes definition and requirements of logistic nodes planning process and criteria special installations planning exercise rail freight traffic route planning construction with circulating traffic
Prerequisites: Transport Infrastructure (IEB 3091) Infrastructure Construction (IEB 4091)
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
be acquainted with the planning processes regarding commercial transportation services focusing the logistical processes.
have background knowledge of freight logistics (combined transport, route planning and construction with circulating traffic).
Language of instruction: German
Teaching methods: Lecture supported by a script, blackboard-notes, task-collections in the intranet and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: Guidelines and recommendations (ICAO, AH FBF, NfL ….) Own publications Oelfke, Wolfgang: Güterverkehr – Spedition – Logistik; Speditionsbetriebslehre. Verlag Dr. Max Gehlen, Bad Homburg v.d.H., 1995 Thoma Lothar: City-Logistik; Konzeption – Organisation – Implementierung. Gabler Verlag, Wiesbaden, 1995. Schubert, Werner (Hrsg.): Verkehrslogistik – Technik und Wirtschaft Verlag Franz Vahlen, München, 2000. Sonntag, Herbert et al.: Städtischer Wirtschaftsverkehr und logistische Knoten – Wirkungsanalyse von Verknüpfungen der Güterverkehrsnetze auf den städtischen Wirtschafts- und Güterverkehr. Berichte der Bundesanstalt für Straßenwesen, Verkehrstechnik Heft V 68, Wirtschaftsverlag NW, Bremerhaven, 1999. Script
Course title: Environmental Engineering
Course code: IEB 6101
Type of course: Lecture
Level of course: Bachelor
Year of study: Third year
ECTS Credits:
6
Semester: 6th Semester
Name of the lecturer: NN
Course contents:
Sustainability in civil engineering:
sustainable construction resource-saving structures and constructions low energy construction
Soil Conservation and Remediation of contaminated sites
requirements of soil conservation risk assessment remediation of soil contamination and contaminated sites
Air Pollution Control: air properties air quality and air pollution methods of air pollution control
Prerequisites: Natural Sciences (IEB 1032)
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of main principles and methods to avoid and minimise environmental pollution due to constructional activities respectively construction-related industries.
be able to apply the basic principles and methods of environmental engineering (environmental protection on building sites, soil and air pollution control).
Language of instruction: German
Teaching methods: Lecture supported by a script, blackboard-notes and computer presentations.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: • C.-A. Graubner, K. Hüske: Nachhaltigkeit im Bauwesen, Grundlagen – Instrumente – Beispiele, Ernst & Sohn Verlag, 1. Auflage, 2003 • A. Schmidbauer: Nachhaltigkeit im Bauwesen – Prototyp oder Unikat: Definition und Analyse einer nachhaltigen Gebäudetypologie im Wohnungsbau, VDM Verlag, 1. Auflage, 2009 • L. Dorsch, U. Jung: Kursbuch: Von der Energieeffizienz zur Nachhaltigkeit, 1. Auflage, 2012 • U. Jung: Handbuch Energieberatung, 1. Auflage, 2010 • R. Hirschberg: Energieeffiziente Gebäude – Bau- und anlagentechnische Lösungen, vereinfachte Verfahren zur energetischen Bewertung, Rudolf Müller Verlag, 1. Auflage, 2011 • K.-P. Fehlau, B. Hilger, W. König: Vollzugshilfe Bodenschutz und Altlastensanierung, Erich Schmidt Verlag, 1. Auflage, 2000 • A. Hugo, M. Koch, H. Lindemann, H. Robrecht: Altlastensanierung und Bodenschutz: Planung und Durchführung von Sanierungsmaßnahmen – Ein Leitfaden, Springer Verlag, 1. Auflage, 1999 • R. Guderian: Handbuch der Umweltveränderungen und Ökotoxikologie, Band 1 A: Atmosphäre, Springer Verlag, 1. Auflage, 2000 • D. Möller: Luft: Chemie – Physik – Biologie – Reinhaltung – Recht, 1. Auflage 2011 • K. Görner, K. Hübner: Gasreinigung und Luftreinhaltung, Springer Verlag, 1. Auflage 2002
Course title: Project: Operation and Maintenance of Infrastructure
Course code: IEB 6121
Type of course: Project including report and presentation
Level of course: Bachelor
Year of study: Third year
ECTS Credits:
6
Semester: 6th Semester
Name of the lecturer: Prof. Christian Holldorb, Prof. Jan Akkermann and different professors from various specialization areas on the subject of infrastructure
Course contents:
The students work in groups self-reliantly on a practice-related project, which can be specialised by a division (structural, traffic, hydraulic or energy engineering) or across all divisions.
Prerequisites:
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
be able to compile self-reliantly a problem and apply acquainted methods and instruments to operate, maintain respectively refurbish infrastructure facilities.
Language of instruction: German
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading:
Course title: Environmental and Construction Law
Course code: IEB 7131
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: Fourth year
ECTS Credits:
6
Semester: 7th Semester
Name of the lecturer: NN
Course contents:
public construction law main principles of the construction law code and federal land
utilisation basics of area development planning illustration of the land-use plan and development plan planning admissions of building projects illustration of the construction licensing procedure (in Baden-
Württemberg) main principles of the building regulations law by means of the
BauO BW building law orders VOB protection of ancient monuments European Water Framework Directive environmental risk assessment
laws pertaining to water and waterways Federal Immission Control Ordinance Energy Conservation Act
Prerequisites:
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
have background knowledge of main principles and methods to avoid and minimise environmental pollution due to constructional activities respectively construction-related industries.
be able to apply the basic principles and methods of environmental engineering (environmental protection on building sites, soil and air pollution control).
Language of instruction: German
Teaching methods: Lecture supported by a script, blackboard-notes and practical exercises.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: • Erbguth/Wagner, Grundzüge des öffentlichen Baurechts, 4. Auflage 2005 • Finkelnburg/Ortloff, Öffentliches Baurecht Band I: Bauplanungsrecht, 6. Auflage 2007 • Finkelnburg/Ortloff, Öffentliches Baurecht Band II: Bauordnungsrecht, Nachbarschutz, Rechtsschutz, 5. Auflage 2005 • Gas, Baurecht, 1. Auflage 2006 • Schrödter, Baugesetzbuch, 7. Auflage 2006 • Boeddinghaus, BauNVO Baunutzungsverordnung, 5. Auflage 2005 • Pieper, Skript Öffentliches Baurecht, 3. Auflage 2006 • Kapellman/Langen: Einführung in die VOB/B, Basiswissen für die Praxis, 15. Auflage 2006 • Kimmich/Bach: VOB für Bauleiter, 2004 • Erbguth et al.: Lehrbuch Umweltrecht • Stuttmann: Alpmann-Schmidt, 2009
Course title: Project Management
Course code: IEB 7132
Type of course: Lecture and practical exercises
Level of course: Bachelor
Year of study: Fourth year
ECTS Credits:
6
Semester: 7th Semester
Name of the lecturer: Prof. Dr.-Ing. Carolin Bahr, NN
Course contents:
Next to working on practical-related projects the lecture is structured as follows:
management technics during the work on a project focusing infrastructure facilities
project development and conception operating models (PPP) analysis of built infrastructure in business and economic terms
Prerequisites: Basics of Construction Operations, Internship
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
be able to relate the implementation of building within existing structures of infrastructural projects to business and economic aspects in a worthwhile manner.
be able to manage construction knowing the characteristics of a project in infrastructural building as well as recognise new projects in existing structures.
Language of instruction: German
Teaching methods: Lecture supported by a script, blackboard-notes and practical exercises.
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: Common reading upon Project Management including norms and guideline which are relevant for building in existing structures (e. g. Guideline for Refurbishment of the DAfStb)
Course title: Project Presentation
Course code: IEB 7121
Type of course: Project presentation, generally thesis project
Level of course: Bachelor
Year of study: Fourth year
ECTS Credits:
3
Semester: 7th Semester
Name of the lecturer: All Professors of the faculty
Course contents:
Topics related to Infrastructure Engineering; generally of the final thesis
Prerequisites:
Course objectives expressed in learning outcomes and
After having successfully completed the course, the students should
competences:
present the result of their work. be able to self-reliantly conduct a project with practical-related
methods of civil engineering.
Language of instruction: German
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading:
Course title: Bachelor Thesis
Course code: IEB BT
Type of course: Individually created thesis supervised by a professor
Level of course: Bachelor
Year of study: Fourth year
ECTS Credits:
15
Semester: 7th Semester
Name of the lecturer: All Professors of the faculty
Course contents:
Topics related to Infrastructure Engineering
Prerequisites: 78 ECTS (acquired in the 3rd, 4th and 6th semester)
Course objectives expressed in learning outcomes and competences:
After having successfully completed the course, the students should
be able to self-reliantly conduct a project on a prescribed topic within a set period of time (3 months).
Language of instruction: German
Assessment methods: Written exam Presentation
Written assignment Project work
Exercises Oral exam
Recommended reading: