BEng Modules, Course of Studies Civil Engineering BIB … · BIB 1011 Engineering Mathematics and...

BEng Modules, Course of Studies Civil Engineering

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BIB 1011 Engineering Mathematics and Geomatics

Lecturer: Prof. Dr. R. Pollandt M. Mayer

Type of course unit: Compulsory

Level of course unit: First-cycle

Year of study:

Semester when the course is delivered:

First

First / winter semester, summer semester

ECTS credits: 10 ECTS

Prerequisites: None

Language of instruction: German

Teaching method / learning activities:

Mode of delivery:

Lectures, practical exercises

Face-to-face

Attendance:

Workload:

6 hours/week

90 contact hours, 120 hours of independent study

Assessment methods and criteria:

Practical exercises at the PC pool, study assignment, written exam

Recommended optional programme components:

Student can choose courses from the General Studies’ program

Course content: Mathematics: functions (general remarks, standard functions, curve

sketching) differential calculus (general remarks, rules, higher derivatives, extremum problems, bending)

integral calculus (general remarks, rules, methods of integration, technical examples)

linear algebra (general remarks, vector operations, analytical geometry)

Geomatics: methods of measurement earth representation in planes systems of measurement use of measurement in civil engineering cartography tolerances in measurements

Learning outcomes: 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 use software in a responsible manner, be able to interpret mathematical results, be able to deal with abstract problems, be able to set out and to measure buildings,



have practical experience in measurement, know different measuring methods, know attachments in measurement, be able to handle the gained data in software

environments, be able to handle drawings in civil engineering.

Work placements: n/a

Recommended reading: Lecture handout Papula, L.: Mathematik für Ingenieure und Naturwissenschaftler Dürrschnabel, K..: Mathematik für Ingenieure Div. DIN – Vorschriften Witte, B.; Schmidt, H. W.: Vermessungskunde und Grundlagen der Statistik für das Bauwesen Petrahn, G.: Taschenbuch Vermessung



BIB 1021 Technical Mechancis I

Lecturer: Prof. M. Aberle



Year of study:


First


ECTS credits: 6 cp

Prerequisites: Knowledge of mathematics and physics at higher secondary school level



Mode of delivery:


Face-to-face

Attendance:

Workload:

6 hours/week



Written exam



Course content: Loads on structures, force vectors, 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, arches, thrust line, cable structures), pin-jointed systems and trusses

Learning outcomes: 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, frames, and arch and cable structures.


Recommended reading: Will be communicated in class



BIB 1031 Building Physics

Lecturers: Prof. Dr.-Ing. H.-J. Walther Assistant Lecturers



Year of study:


First


ECTS credits: 6 cp

Prerequisites: None



Mode of delivery:


Face-to-face

Attendance:

Workload:

4 hours/week



Written exam



Course contents: Basic concepts of structural design Elements of supporting structures and systems Action, Static Stability, Foundations and Soil Mechanics Walls, Floors, Ring beams Beams, lintels, ceilings, covers, balconies and loggias, Floor Constructions, Screeds, Stairs and Doors Roof Constructions Issues of Building Physics Building within Existing Structures History of Mansory Construction Construction Standard Specification, DIN EN 1996-1-1 as

well as the National Appendix Basic Principles, Mathematical Methods, Structural

fundamentals

Learning outcomes: Basic knowledge of Loads on Structures Structural Design Selected and alternative building materials, there

application and behavior while changing expositions (regarding bearing capacity, serviceability and durability)

Support structure planning (EC0) Student is able to apply Safety concepts Laws of combination of ultimate limit states of bearing



capacity and serviceability Basic laws to identify the loads on structures (EC1)

focussing working loads and dead loads, snow load and wind load

The student has developed an overall view of the design procedure.


Recommended reading: Fricke / Knöll: Baukonstruktionslehre Teil 1 und 2 – Teubner-Verlag Dierks / Schneider / Wormuth: Baukonstruktion – Werner-Verlag Neufert: Bauentwurfslehre – Vieweg-Verlag DIN EN 1996-1-1 + NA , DIN EN 1996-2 + NA DIN EN 1990 + NA: Grundlagen der Tragwerksplanung (EC0)DIN EN 1991-1-1, -3, -4 (EC1) / (Nutz- und Eigenlasten, Schneelasten, Windlasten)



BIB 1041 Construction Materials Technology

Lecturers: Prof. Dr.-Ing. S. Linsel



Year of study:


First


ECTS credits: 8 ECTS

Prerequisites: None



Mode of delivery:


Face-to-face

Attendance:

Workload:

6 hours/week



Written exam



Course content: • Material structure • Macroscopic and microscopic observations • Material production, material behaviour and properties • Physical properties of materials • Basics for durability and serviceability • Optimal selection of materials • Introduction to concrete technology, metals in

construction, masonry, wood, plastics, glass, clay, bamboo

(supplemented by demonstration lectures in the laboratories of the public building inspectorate)

Learning outcomes: Basic knowledge about structure, characteristics and properties of various construction materials. Students can understand the properties of construction materials based on their structures and are able to use them accordingly. Constructions can be optimized in terms of technology, finance and energy efficiency by selecting the most suitable materials.




Recommended reading: • Dehn, König, Marzhan: Konstruktionswerkstoffe im

Bauwesen, Verlag Ernst & Sohn • Knoblauch, H./Schneider U.: Bauchemie; Werner Verlag • Wesche, K.: Baustoffe für tragende Bauteile (Teil 1:

Eigenschaften, Messtechnik, Statistik; Teil 2: Beton, Mauerwerk; Teil 3: Stahl, Aluminium; Teil 4: Holz, Kunststoffe); Bauverlag

• Hornbogen, E.: Werkstoffe; Springer Verlag • Härig / Günther / Klausen: Technologie der Baustoffe; C.F.

Müller Verlag • Grübl, P./ Weigler, H./ Karl, S.: Beton: Arten, Herstellung

und Eigenschaften; Ernst-und Sohn-Verlag • Stark, J.: Zement und Kalk: Der Baustoff als Werkstoff;

Birkhäuser-Verlag • Betonkalender: Teil I und II; Taschenbuch für Beton-,

Stahlbeton- und Spannbetonbau sowie verwandten Fächern • Textbooks for physics and chemistry • Information by professional associations • Hefte der Schriftenreihe der Zementindustrie • Periodicals



BIB 2011 Engineering Mathematics II

Lecturer: Prof. Dr. R. Pollandt Dr. M. Paule



Year of study:


First

Second / winter semester, summer semester

ECTS credits: 6 cp

Prerequisites: Engineering Mathematics I (BIB 1011)


Teaching method/learning activities:

Mode of delivery:


Face-to-face

Attendance:

Workload:

6 hours/week



Written exam



Course content: Functions of several variables: graphical representation differential calculus (methods,use in optimisation,

adaption to given data, Taylor series) multiple integrals (methods, double and triple integrals,

numerical integration, examples, use in statics) Financial mathematics Differential equations: exact and numerical methods,

examples in civil engineering Statistics: descriptive statistics (samples, parameters,

representation, confidence intervals, linear regression) calculus of probabilities (axioms, calculus with

probabilities, event tree, one- and moredimensional distributions)

Learning outcomes: 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 use software in a responsible manner, be able to interpret mathematical results be able to deal with abstract problems.




Recommended reading: • Script • Papula, L.: Mathematik für Ingenieure und

Naturwissenschaftler • Dürrschnabel, K.: Mathematik für Ingenieure • Kreyszig: Statistische Methoden und ihre

Anwendungen • Siegner: Angewandte Statistik Plate: Statistik und angewandte

Wahrscheinlichkeitslehre für Bauingenieure



BIB 2021 Technical Mechanics II

Lecturers: Prof. M. Aberle



Year of study:


First


ECTS credits: 6 cp

Prerequisites: Engineering Mathematics I (BIB 1011), Technical Mechanics I (BIB 1021)



Mode of delivery:

Lectures, practical exercises Face-to-face

Attendance:

Workload:

6 hours/week



Written exam



Course content: Moments of inertia, tension and compression members, bending stresses, bending deformations, combined stresses, combined bending and axial stresses, kern of a section, nonlinear materials, shear stresses, shear centre, shear deformations, torsional stresses, torsional deformations, plain strain and plain stress, stability, three-dimensional systems

Learning outcomes: After having successfully completed the course, the students should • have acquired basic skills in calculating stresses,

strains and deformations, • be able to model and dimension structural systems in

consideration of allowable stresses and deformations.

Work placements n/a

Recommended reading: Will be communicated in class

BIB 2051 Natural Sciences and Building Physics

Lecturers: Prof. Dr. Andreas Gerdes Prof. Dr. Hubert Schwab





Year of study:


First


ECTS credits: 6 cp

Prerequisites: Construction Materials Technology (BIB 1041)



Mode of delivery:


Face-to-face

Attendance:

Workload:

6 hours/week



Written exam



Course content: 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, reveberation time)

Behavior of Walls, Law of Mass, difference of flexible and bending-resistant

Calculation of acoustiv insulation according to construction standard specification

Basic principles of Chemistry (Atoms, Molecules, chemical bondings)

Nature of Materials (Gas, Fluids, Emulsions, Concrete Additives)

Chemical-physical Properties of Water (Water vapour, water, ice, surface tension, diffusion, capillary sinking, osmosis, drying and shrinking)

Reactive Transportion Processes in porous construction materials

Chemistry of selected adhesive agents (cement, chalk, plaster)

Chemistry of concrete additives and admixtures Corrossion of metals Reactions of Polymerisation (Reaction resins,

Thermoplasts, Elastomers) Kinetic of chemical Reactions (Carbonatisation, Ageing

of Polymers) Construction Material harming chemical reactions



Basic principles of Analysis (Spectroscopy, Chromatography, Potentio-metry)

Building Chemistry and Climate Change Selected Case Studies of the fields of technical

infrastructure (drinking water reservoirs, swimming pools and bridges)

Learning outcomes: After having successfully completed the course, the students should know the fundamental heat transport processes, be able to calculate U-values of all possible building

constructions, know how to realise a good thermal insulation, know the different aspects of water in building

constructions (water vapor in the air, water content in building constructions, sorption isotherm),

be able to calculate the heat and moisture transport through building constructions,

know the principles of building acoustics, know how to measure sound insulation and impact

sound levels, be able to calculate the sound reduction index of

building constructions and the impact sound level index of ceilings


Recommended reading: H.K. Cammenga, J. Daum, C. Gloistein, U. Gloistein, A. Steer, B. Zielas-ko: 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

J. Stark und B. Wicht: Zement und Kalk, Birkhäuser Verlag, Basel, 2000

P. Lutz, R. Jenisch et. al.: Lehrbuch der Bauphysik, 5. Auflage, Teubner Verlag, 2002

K. Gösele, W. Schüle, H. Künzel: Schall, Wärme, Feuchte, 10. Auflage, Bauverlag, 1997

W. Bläsi, Bauphysik, Europa Lehrmittel-Verlag, Haan Gruiten, 2004

TH. Ackermann: Energieeinsparverordnung, 1. Auflage, Teubner Ver-lag, 2003

G. Lohmeyer et. Al: Praktische Bauphysik, 5. Auflage, Teubner Verlag 2005

Hrsg. DIN e.V.: DIN-Taschenbuch 158 Wärmeschutz 1, 8. Auflage, Beuth Verlag, 2004

Hrsg. DIN e.V.: DIN-Taschenbuch 357 Wärmeschutz 2, 1. Auflage, Beuth Verlag, 2004

Hrsg. DIN e.V.: DIN-Taschenbuch 35 Schallschutz, 10. Auflage, Beuth Verlag, 2002



BIB 2061 Soil Mechanics

Lecturers: Prof. Dr.-Ing. E. Schwing



Year of study:


First


ECTS credits: 6 cp

Prerequisites: Technical Mechanics I (BIB 1021)



Mode of delivery:


Face-to-face

Attendance:

Workload:

4 hours/week

60 contact hours, 30 hours laboratory classes, 90 hours of independent study


Successful lab work, written exam



Course content: • Subsoil investigations: geotechnical testings, in-situ

testings, laboratory testings (index testings), classification and identifying of soils

• Effects of Water in Building ground: Hydraulic pressure, permeability, hydraulic current network, groundwater maintainance

• Behavior of compression: load-settlement test, consolidation, spatial stress distribution in the ground, direct and indirect calculation of settlement

• Shear strength: determination of specific values regarding shear strength, fundamentals of soil behaviour

• Earth pressure calculations: Theories, active earth pressure, at-rest earth pressure and earth resistance as well as exceptional cases

• Ground Failure: Theoretical failure models, equations for proofing stability

Learning outcomes: Knowledge of basic theory of experiments in soil mechanics and their realization. Due to their knowledge of soil characteristics, students can classify the building ground.

The students know the fundamentals to describe building grounds - with a special focus on soil mechanical testings -regarding their physical properties. The students are



capable of classifying soils in a critical manner as well as analysing them due to their mechanical and hydraulic properties. The students learn to describe the stress distribution in the ground as well as to calculate the resulting settlement. Knowing the theories of earth pressure the students can determine the relevant loads of building components in contact with the ground. They know technical guidelines and building standard specifications and can apply them.


Recommended reading: Gudehus: Physical Soil Mechanics, Springer Verlag Gudehus: Bodenmechanik, Enke Verlag 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 Worksheets and handouts



BIB 2071 Hydromechanics

Lecturers: Prof. Dr.-Ing. Norbert Eisenhauer M.Sc. Niklas Zumbroich



Year of study:


First


ECTS credits: 6 cp

Attendance:

Workload:

4 hours/week

60 contact hours, 30 hours laboratory classes, 90 hours of independent study

Prerequisites: Engineering Mathematics I (BIB 1011) Technical Mechanics I (BIB 1021)



Mode of delivery:


Face-to-face


Written exam, practical assignment



Course content: Properties of water, hydrostatics, basics of hydrodynamics (stationary flow, continuity, Bernoulli's equation, momentum), pipeflow, open channel flow, flow resistance of submerged bodies, overview of instationary flows

Learning outcomes: After having successfully completed the course, the students should • know the fundamental basics of hydromechanics, • be able to use hydromechanics to analyse and solve

practical hydraulic problems.


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 • Other recommendations will be given in the handout



BIB 3061 Foundation Engineering

Lecturers: Prof. Dr.-Ing. E. Schwing



Year of study:


Second

Third / winter semester, summer semester

ECTS credits: 6 cp


Attendance:

Workload:

6 hours/week


Prerequisites: Technical Mechanics I+II (BIB 1021, BIB 2021) Soil Mechanics (BIB 2061) Hydromechanics (BIB 2071)


Mode of delivery:


Face-to-face


Written exam



Course content: • Shallow foundations: (Bearing capacity and stability of

shallow foundations, stability against ground failure, sliding and overturning, standard proofing methods)

• Deep foundations: (Bearing capacity of vertically and horizontally loaded drilled piles and displacement piles)

• Retaining walls (proofs of stability) • Embankments (Investigations regarding the stability of

terraces and embankments with plane and slightly curved sliding surfaces, appliance of different methods)

• Securing excavation (desing and construction, general methods of calculation using earth pressure redistribution, anchored retaining constructions, underpinning for securing built structures)

• Groundwater maintainance (impact of groundwater flow and management, groundwater maintainance appliances)

Learning outcomes: Fundamental theoretical knowledge and knowledge of their practical application of ground construciton engineering. The students can design and calculate general foundation and retaining constructions of ground construction. They know the technical guidelines and building standard specifications and can apply them.


Recommended reading: Dörken/Dehne: Grundbau in Beispielen, Werner Verlag 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 Handout Soil Mechancis (BIB 2061) Worksheets and handout

BIB 3081 Basics of Transportation Engineering

Lecturers Prof. Dr.-Ing. Christoph Hupfer Assistant Lecturers



Year of study:


Second


ECTS credits: 6 cp


Attendance:

Workload:

6 hours/week


Prerequisites: None


Mode of delivery:

Lectures

Face-to-face


Written exam



Course content: • Basic principles of mobility • Demands of traffic participants • Planning process • Design of urban traffic areas • Demands of public transportation • Legal framework and financing • Fundamentals of schedule programming • Stops and Stations • Design and Construction of Public Transportation

Facilities • Fundamentals of Road Construction • Design of road superstructure • Earthwork • Production of Building Materials • Quality control of Building Material Construction • Construction of Traffic Infrastructure Facilities



Learning outcomes: The student knows: the main principles and context of mobility, urban traffic, public transportation and road construction The student can: Determine and apply different aspects of traffic planning and is able to select appropriate methods and implement them. Is able to successfully complete a construction project due to its requirements of traffic areas as well as to select the appropriate building materials, methods and processes of quality control in the production of building materials and in the construction of road construction projects. The student is acquainted with handling standards safely as well as with factors for traffic planning coming from outside his field and can find appropriate solutions. These solutions can be anaylesed in general without doing a detailed planning and be used for a decision-making. He is also capable of preparing and coordinating road construction projects as well as the subsequent quality control and securing.


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) • Vorlesungsumdruck • Technische Lieferbedingungen, Technische

Prüfvorschriften und Zu-sätzliche 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,



BIB 3091 Basics of Structural Engineering

Lecturers: Prof. Dr.-Ing. M. Baumann Prof. Dr.-Ing. Ch. Enderle



Year of study:


Second


ECTS credits: 6 cp


Attendance:

Workload:

6 hours/week


Prerequisites: Technical Mechanics I (BIB 1021) Technical Mechanics II (BIB 2021) Construction Materials Technology (BIB 1041)


Mode of delivery:


Face-to-face


Written exam



Course content: Steel design: notation, peculiarities, specification drawings the material steel influencing factors problems of mechanics and stability bolted connections welded connections tension members compression members compression and bending members Reinforced concrete design: reinforced concrete, usage, terms, standards bearing capacity of composite material reinforced concreteconception of safety, safety factors DIN 1055-100 constitutive equations of steel and concrete environmental influence, concrete cover, spacer foundation of design of DIN 1045-1 rectangle beams under bending and axial force T-beams under bending and axial force foundation of construction, reinforcement standards

Learning outcomes: After having successfully completed the course, the students should



• be able to use the basic German steel and concrete codes,

• be able to practically design steel and concrete constructions.


Recommended reading: • DIN EN 1993-1-1, 1-8 und NA-D • Hirt, Bez: Stahlbau • Wagenknecht: Stahlbau Praxis nach Eurocode 3

Band 1 und Band 2 • DIN – EN 1992 1-1 (EC 2) und NA-D • Heft 600 DAfSt, Erläuterungen zu DIN – EN 1992 (EC

2) • DIN – EN 1990 (EC 1) und NA-D • Wommelsdorff, Albert: Stahlbetonbau – Teil 1 und

Teil 2 • Goris: Stahlbetonabu-Praxis nach EC 2 – Band 1 und

Band 2 • Avak: Stahlbetonbau in Beispielen • DBV: Beispiele zur Bemessung nach EC 2



BIB 3092 Computer Science in Construction

Lecturers: Prof. Dr.-Ing. Ch. Enderle Prof. Dr.-Ing. R. Pollandt



Year of study:


Second


ECTS credits: 12 cp


Attendance:

Workload:

8 hours/week

180 contact hours, 20 hours of laboratory classes, 90 hours of independent study

Prerequisites: Technical Mechanics I+II (BIB 1021, BIB 2021) Engineering Mathematics (BIB 1011, BIB 2011) Construction Materials Technology (BIB 1041)


Mode of delivery:

Lectures, practical exercises, laboratory

Face-to-face


Written exam, lab work



Course content: Visual Basic for Applications (VBA): • Standard commands of VBA • Programming of functions and sub-routines • Modules in VBA • User-defined forms in VBA • Verification sheets • Graphical methods

Learning outcomes: After having successfully completed the course, the students should • be able to write small programs in VBA, • be able to compile sheets for standard tasks in civil

engineering, • understand given VBA programs • have some practical experience in software design.


Recommended reading: Handout Lohmeyer: Baustatik Schneider, Schweda: Baustatik kompakt Kämper, S.: Grundkurs Programmieren mit Visual Basic Kofler, M.: Excel programmieren, Addison-Wesley Skriptum zur Vorlesung DLUBAL: Programmbeschreibung RSTAB Friedrich und Lochner: Programbeschreibungen



BIB 4111 Basics of Water Supply and Sanitation Engineering

Lecturers: Prof. Dr.-Ing. N. Eisenhauer Prof. Dr.-Ing. C. Wittland

Type of course unit Compulsory


Year of study:


Second

Fourth / winter semester, summer semester

ECTS credits: 6 cp


Attendance:

Workload:

6 hours/week


Prerequisite: Natural Sciences and Building Physics (BIB 2051) Hydromechanics (BIB 2071)


Mode of delivery:


Face-to-face


Written exam



Course content: Water Supply: • Quality requirements drinking water • Raw water catchment from ground and surface water • Design and construction of wells • Water conveyance, pumping stations • Water treatment • Water storage • Water distribution Sanitation Engineering: • Different types of wastewater • Requirements for proper urban sanitation • Design and construction of sewerage systems • Wastewater treatment processes • Concepts and measures for stormwater management

Learning outcomes: 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,

• be able to apply the main principles and methods related to the concept and design of water supply and sanitation facilities.




Recommended reading: • Herrmann: Einführung in die Hydrologie, Teubner

Verlag1977 • Vischer: Wasserbau, Springer-Verlag 1993 • Lattermann: Wasserbaupraxis, Band I, II, Verlag

Bauwerk 1999 • Patt: Hochwasserhandbuch, Springer-Verlag 2001 • Naudascher: Hydraulik der Gerinne und

Gerinnebauwerke, Springer-Verlag 1987 • Other recommendations will be given in the handout •

J. Mutschmann, F., Stimmelmayr: Taschenbuch der Wasserversorgung, 13. Auflage, 2002

• P. Grombach, K. Haberer, et al.: Handbuch der Wasserversorgungs-technik, 3. Auflage, 2000

• H. Damrath, K. Cord-Landwehr: Wasserversorgung, 11. Auflage, 1998

• G. Martz: Siedlungswasserbau – Teil 1 Wasserversorgung



BIB 4121 Traffic Engineering I

Lecturers: Prof. Dr.-Ing. Christoph Hupfer Prof. Dr.-Ing. Markus Stöckner



Year of study:


Second


ECTS credits: 6 cp


Attendance:

Workload:

6 hours/week


Prerequisites: Basics of Transportation Engineering (BIB 3081)


Mode of delivery:


Face-to-face


Written exam



Course content: Traffic census • Concepts and fundamental correlations • Countings of flowing traffic and traffic at rest • Investigations of traffic flow • interrogation • organisation and execution Performance capacity of intersection without traffic light-signal systems • Concepts and requirements • Priority-ruled junctions and intersections • Roundabound • Levels of Transport Quality Design of rural traffic facilities • Relevant velocities • Design elements of the layout plan and gradient

diagram • Vertical alignment • Cross-sectional design elements • Design elements of view

Learning outcomes: Elaboration of a basis for the dimensioning and of local requirements for traffic projects, development and analysis of solution with a focus on rural roads. Elaboration of appropriate bases for the dimensioning for any local and traffic related constellations, targeted development of integrated solutions and decision-making



parameters due to the standards, decision-making and realisation.


Recommended reading: • 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) • Handout



BIB 4131 Construction Engineering

Lecturers: Prof. Dr.-Ing. H. J. Walther Prof. Dr.-Ing. M. Baumann



Year of study:


Second


ECTS credits: 6 cp

Attendance:

Workload:

6 hours/week


Prerequisites: Basics of Structural Engineering (BIB 3091) Computer Sciene in Construction (BIB 3092)



Mode of delivery:

Lecture, practical exercises

Face-to-face


Written exam



Course content: Steel Design: • Roofs (Troughted sheets, sandwich elements) • Framestructures (Construction und Calculation) • Bracings (Construction und Calculation) • Purlins (Construction und Calculation) • Frontal sheets and splice joints • Frame Corners • Supporting Crosses and Shear Force Connection • Connection of columns at foundations Concrete Design: • Assessment of the state of strain • Safety concepts • Durability • Continuous plate supporting strucutres (uniaxial) • Continuous beam (t-beams) • Columns • Reinforced Concrete Walls • Concrete Walls • Standards for reinforcement and construction

Learning outcomes: The student is able to identify the theoretical background of standard specifications and can apply these as well as the structural principles when planning a construction made of steel or reinforced concrete. The student is capable of using standard specificaitons, can identify their theoretical background which will be one



of the key skills of a civil engineer working in the fields of support structure planning.


Recommended reading: • EC3 (DIN EN 1993-1 bis -6 + NA) • DAST Ringbuch; Typisierte Anschlüsse • Vogel, Heil: Traglasttabellen • Handbuch: Programmbeschreibung rstab • Internetlinks zu Stahltrapezblechen • Krüger U.: Stahlbau Teil 1 und Teil 2 • Petersen: Stahlbau • EC0, EC1 (Grundlagen der Tragwerksplanung,

Lastannahmen) • DIN EN 1992-1-1 + NA (EC2) • Hefte 599, 600 DAfStb – Erläuterungen zum EC2 • Goris,A.: Stahlbetonbau-Praxis nach Eurocode 2 –

Band 1: Grundlagen, Bemessung, Beispiele. 4. Auflage, Beuth Verlag, Berlin-Wien-Zürich, 2011

• Goris,A.: Stahlbetonbau-Praxis nach Eurocode 2 – Band 2: Schnittgrößen, Gesamtstabilität, Bewehrung und Konstruktion, Brandbemessung nach DIN EN 1992-1-2, Beispiele. 4. Auflage, Beuth Verlag, Berlin-Wien-Zürich, 2011

• Betonkalender (jährlich) – Verlag Ernst & Sohn Wommelsdorff, O.: Stahlbetonbau – Bemessung und Konstruktion, Teil 1: Grundlagen, Biegebeanspruchte Bauteile. 10. Auflage, Werner Verlag 2011

Fingerloos, F.; Hegger, J.; Zilch, K.: Eurocode 2 für Deutschland – Kommentierte Fassung, Ernst & Sohn – Beuth, 1. Auflage 2012



BIB 4141 Construction Operations and Management

Lecturers: Prof. Dr.-Ing. S. Linsel Prof. Dr.-Ing. Gerd Bergweiler Prof. Dr.-Ing. Matthias Urmersbach



Year of study:


Second


ECTS credits: 6 cp

Attendance:

Workload:

6 hours/week


Prerequisites: Basic knowledge of what is happening on a construction site (practical work on construction sites in a pre-internship) and in a company. Openness and willingness to learn about the economic conditions of a construction project, and general and specific construction processes.



Lectures


Written exam



Course content: Cost and management accounting (KLR-construction): • Pricing depending on the economic environment • Accounting and balance sheet accounts as accounting

cycle I • Cost and management accounting (CAA) as

accounting cycle II • Income calculation: based on operations, divisions,

branches and construction sites Construction management: • Basics of construction management • Management techniques • Scheduling • Quality management • Project development • Privatisation • HOAI Construction: • Planning and Construction • Job preparation, introduction to the calculation of

building projects • Organisational methods • Area and volume



• Investment, appointments, SiGeKo • Insurance / Guarantees • Implementation of construction projects

Learning outcomes: Theoretical background knowledge and practical implementation of the development of a meaningful balance of accounts, profit and loss statement of a construction company, operational sequences in a construction process of the planning and especially iof the constructional aspects, cost-based handling of a construciton project.


Recommended reading: • Behrendt, Dieter / Schmidt Heinrich Th.:

Baubetriebliche Begriffe, Beiträge zum Baubetrieb, Bd. 12, Karlsruhe 1993

• Breunig, Bernd:Zur Ermittlung des „Schadenersatzes“ bei Baupreisab-sprachen, in TAB, Technische Gebäudeausrüstung, Organ des Bundes-industrieverbandes Heizungs-, Klima-, Sanitärtechnik e.V. BHKS, Nr. 11, Gütersloh 1994, S. 116 ff

• Drees, Gerhard / Bahnen, Anton: Kalkulation von Baupreisen, Wiesbaden/ Berlin 1987 (2)

• HOAI Honorarordnung für Architekten und Ingenieure • Hofstadt: Abwicklung von Bauvorhaben, Verlag

Rudolf Müller • Vogel:Handbuch Immobilien-Projektentwicklung,

Verlag R. Müller • Aktuelle baubetriebliche Zeitschriften

BIB 4161 Project Design and Construction

Lecturers: Prof. Dr.-Ing. R. Pawlowski Prof. Dr.-Ing. Norbert Eisenhauer Assistant Lecturers



Year of study:


Third

Forth / winter semester, summer semester

ECTS credits: 6 cp

Attendance:

Workload:

2 hours/week

30 contact hours, 150 hours of independent study with supervision

Prerequisites: None



Mode of delivery:

Semester project with presentation

Face-to-face




Presentation (pass / fail)


n/a

Course content: A project related to practice, divicion-specific (structural engineering, traffic engineering or hydraulic engineering) or division-transcending, is to be worked on in groups regrading the design, dimensioning and construction.

Learning outcomes: Working on a complete project related to practice. Elaborating of a basis for dimensioning, design, calculations, structural design, presentation of the results.


Recommended reading: • aktuelle Normen, Richtlinien, Zulassungen,

Produktinformationen • Fachbücher für die Projektbearbeitung nach Angabe

des Dozenten • Handbücher zu den verwendeten

Bemessungsprogrammen • Handbücher zu den verwendeten CAD-Programmen



BIB PV Internship Preparation: Quantity Survey

Lecturers: Prof. Dr.-Ing. S. Linsel Assistant Lecturers



Year of study:


Third

Fifth / winter semester, summer semester

ECTS credits: 4 cp

Attendance:

Workload:

2 hours/week


Prerequisite: General principles of civil engineering Construction Operations and Management (BIB 4141)



Mode of delivery:

Lectures

Face-to-face


Practical exercise (pass / fail)



Course content: • Construction processes, construction machines and

appliances in the construction and engineering sector • VOB • Implementation due to bidding documents, tender

documents, types of contracts • Master data indices • Aids for calculation • Structure of contract documents/special positions and

their implementation on-site • Calculation of equipment costs/list of construction

equipment/typs of construction equipment costs • Material services and external services • Cost-splitting and price break-dowb • Specifications of calculation process in the

construction-operational context

Learning outcomes: Practical fundamental knowlegde of construction processes with a focus on economic issues (calculation); general proceeding in the preparation of construction projects. The students are prepared for the internship or can follow up their practical experiences with lectured examples. The content is supplemented by lectures about construction equipment for different projects (construction and engineering).




Recommended reading: • Keil, Martinsen, Vahland, Fricke: Kostenrechnung für

Bauingenieure, 10. Auflage • Drees/Paul: Kalkulation von Baupreisen, Bauwerk

Verlag, Berlin 2000 • KLR Bau: Kosten- und Leistungsrechnung der

Bauunternehmen, Wiesbaden, Bauverlag, Köln, Verlagsgesellschaft Rudolf Müller, 19. Aufl., Werner Verlag, Düsseldorf, 2001

• Baugeräteliste (BGL), Bauverlag, Wiesbaden/Berlin 2001

• HOAI, Verordnung über die Honorare für Leistungen der Architekten und der Ingenieure, Textausgabe und Honorartabellenbuch, Werner Verlag, Düsseldorf, 2001

• VOB, Vergabe- und Vertragsordnung für Bauleistungen, Ausgabe 2002, Beuth Verlag, Berlin/Wien/Zürich

BIB P Internship

Lecturers: Prof. Dr.-Ing. H.J. Walther



Year of study:


Third


ECTS credits: 22 cp

Attendance:

Workload: 22 weeks (minimum 95 contact days)

Prerequisite: Minimum of 30 ECTS from third and fourth semester



Mode of delivery:

Practical Internship

Face-to-face


Practical assignment, written report, presentation


n/a

Course content: The internship includes different training contents: Becoming familiar with duties of the site management Planning processes Construction and cost calculation Assistance at design and calculation Creating of planning documents and documents for



construction

Learning outcomes: The aim of the module is the implemenation of all learned knowledge until the 4th semester, it shall be supplemented by practical experiences.


Recommended reading: n/a

BIB PN Internship Follow-up: Language

Lecturers: Prof. Dr.-Ing. Markus Baumann Lecturers at the Foreign Language Institute



Year of study:


Third


ECTS credits: 4 cp

Attendance:

Workload:

2 hours/week


Prerequisite: Internship

Language of instruction: Depending on language course chosen


Mode of delivery:

Seminar in foreign language or communication. Special courses in English for civil engineers are offered.

Face-to-face


Depending on course chosen



Course content: Individual training of language and rhetorical skills, depending on the student's preferences. Expected are courses benefitting for the student's later carreer.

Learning outcomes: Students may improve their foreign language skills - especelly of spoken language - for the use in typical situations of business life. Professionally orientated topics such as participation in meetings and conferences as well as small talk situaitons are in the focus.


Recommended reading: Depending on course chosen



BIB 6111 Hydraulic Engineering

Lecturers: Prof. Dr.-Ing. C. Wittland Prof. Dr.-Ing. N. Eisenhauer Prof. Dr. M. Maier



Year of study:


Third

Sixth / winter semester, summer semester

ECTS credits: 6 cp


Attendance:

Workload:

6 hours/week


Prerequisites: Hydromechanics (BIB 2071) Basics of Water Supply and Sanitation Engineering (BIB 4111)


Mode of delivery:


Face-to-face


Written exam



Course content: Hydrology, hydraulics of open channel flow and hydraulic structures, 1D-hydronumeric modelling, basics of morphology, fluvial engineering, flood protection, inland waterways, European water guidelines, water management, planning of hydraulic structures

Learning outcomes: After having successfully completed the course, the students should

• have broad insights in the large field of water management and hydraulic engineering,

• be able to solve problems in water management and to design hydraulic structures up to a certain degree of complexity.

Work placements n/a

Recommended reading: • J. Mutschmann, F., Stimmelmayr: Taschenbuch der

Wasserversorgung, 13. Auflage, 2002 • P. Grombach, K. Haberer, et al.: Handbuch der

Wasserversorgungstechnik, 3. Auflage, 2000 • 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 • Lattermann: Wasserbaupraxis, Band I, II, Verlag

Bauwerk 1999 • Partenscky – Binnenverkehrswasserbau, Springer-

Verlag 1986 • Giesecke, Mosonyi : Wasserkraftanlagen, Springer-

Verlag 1997



BIB 6121 Traffic Engineering II

Lecturers: Prof. Dr.-Ing. Christoph Hupfer Dr. jur. Gerd Hager



Year of study:


Third


ECTS credits: 6 cp

Attendance:

Workload:

6 hours/week


Prerequisites: Basics of Transportation Engineering (BIB 3081) Traffic Engineering I (BIB 4121)



Mode of delivery:


Face-to-face


Written exam



Course content: • Dimensioning of intersections with traffic light-signal

systems Concepts, requirements, fundamentals, Phasing, signal periods and programs Control processes Traffic quality • Design of at-grad intersections Concepts, requirements, types of intersections Use and design of intersection elements roundabounds (large, small, mini) • Fundamentals planning law Legal planning instruments Civic participation Legal aspects of road usage

Learning outcomes: The student can: Elaborate a basis for dimensioning and local requirements of road, elaboration of solutions, their analysis, technical, legal and political realisation.


Recommended reading: • Handbuch für die Bemessung von

Straßenverkehrsanlagen (HBS) • Richtlinien für Lichtsignalanlagen (RiLSA) • Richtlinien für den Entwurf von Knotenpunkten (RAS-



K1) • Legal texts • Handout



BIB 6132 Reinforced Concrete and Prestressed Concrete Design

Lecturers: Prof. Dr. H.-J. Walther Prof. Dr. Ch. Enderle



Year of study:


Third


ECTS credits: 6 cp


Attendance:

Workload:

6 hours/week


Prerequisites: Basics of Structural Engineering (BIB 3091) Construction Engineering (BIB 4131) Computer Science in Construction (BIB 3092)


Mode of delivery:


Face-to-face


Written exam



Course content: • Foundations • Punching, single foundations, floor slabs • biaxial plate systems • flush beams • stairs • diaphragm beams • Rules for reinforcement work and design rules • serviceability limit state • Introduction • Building materials • types of pre-tensioning and pre-tensioning systems • pre-tensioning with immediate bond • verifications of the ultimate limit state • verifications of the serviceability limit state

Learning outcomes: Further and deepening knowledge and the related theoretical backgrounds of reinforced concrete construction and the basic principles of prestressed concrete construction.


Recommended reading: • EC0, EC1 (Grundlagen der Tragwerksplanung,

Lastannahmen) • DIN EN 1992-1-1 + NA (EC2) • Hefte 599, 600 DAfStb – Erläuterungen zum EC2



• Goris,A.: Stahlbetonbau-Praxis nach Eurocode 2 – Band 1: Grundlagen, Bemessung, Beispiele. 4. Auflage, Beuth Verlag, Berlin-Wien-Zürich, 2011

• Goris,A.: Stahlbetonbau-Praxis nach Eurocode 2 – Band 2: Schnittgrößen, Gesamtstabilität, Bewehrung und Konstruktion, Brandbemessung nach DIN EN 1992-1-2, Beispiele. 4. Auflage, Beuth Verlag, Berlin-Wien-Zürich, 2011

• Betonkalender (jährlich) – Verlag Ernst & Sohn • Wommelsdorff, O.: Stahlbetonbau – Bemessung und

Konstruktion, Teil 1: Grundlagen, Biegebeanspruchte Bauteile. 10. Auflage, Werner Verlag 2011

• Fingerloos, F.; Hegger, J.; Zilch, K.: Eurocode 2 für Deutschland – Kommentierte Fassung, Ernst & Sohn – Beuth, 1. Auflage 2012



BIB 6163 Measuring and CAD

Lecturers: Prof. Dr.-Ing. R. Pawlowski Prof. Dr.-Ing. Clemens Wittland Assistant Lecturers



Year of study:


Third


ECTS credits: 6 cp


Attendance:

Workload:

2 hours/week


Prerequisites: Project Design and Construction (BIB 4161)


Mode of delivery:

Semester project, presentation

Face-to-face


Presentation



Course content: A project related to practice, divicion-specific (structural engineering, traffic engineering or hydraulic engineering) Ein praxisbezogenes Projekt, das spartenspezifisch (Konstruktiver Ingenieurbau, Verkehrswesen oder Wasserbau) or division-transcending, is to be worked on in groups regrading the design, dimensioning and construction.

Learning outcomes: Inpendent selection of standard, specifications, guidelines and specific literature as well as their implementation in order to solve the given task of the project self-contained.


Recommended reading: aktuelle Normen, Richtlinien, Zulassungen, Produktinformationen

Fachbücher für die Projektbearbeitung nach Angabe des Dozenten

Handbücher zu den verwendeten Bemessungsprogrammen

Handbücher zu den verwendeten CAD-Programmen



BIB 7141 Construction Law

Lecturers: Prof. Dr. iur. Andreas Luckey



Year of study:


Fourth

Seventh / winter semester, summer semester

ECTS credits: 8 cp


Attendance:

Workload:

6 hours/week


Prerequisites: None


Mode of delivery:


Face-to-face


Written exam



Course content: Private Building Law Scheme of the Legal System Court types BGB General Part and General Contract Law Concepts / Definitions of Building Law Delimitation BGB and VOB System of the VOB (A, B and C) General types of building contracts and renumeration

calculation Changes of contract works Construction times Termination of Service Contracts Acceptance Renumeration / Accounting Liability for defects Lien Contract Penalty Limitation Independent procedure of taking evidence Default summons orders and execution orders Claim proceedings enforcement departments, register and rolls



Public Building Law Scheme of Public Building Law Fundamental strucures of Planning Law and

regulations on use of buildings Basics of urban development planning Presentation of the land-use plan and development

plan Planning permits of building projects Presentation of the construction licensing procedure

using as an example the construction licensing procedure of BW

Fundamental structures of the building regulation laws using as an example the BauO BW

Building Law Orders Legal Protection in the Public Building Law out of

court and in court

Learning outcomes: In the lecture "construction law" the students learn to create solutions with legal certainty in the field of construction processes. They learn to deal with risk and liability-relevant cases. The students learn about the important interplay and fields of tension between the real world and meeting the challenges in the legal framework of a more and more globalised market. The abiltily to discuss about legal problems with colleguages in a professional manner as well as the ability to take the others' arguments in consideration without prior judgement for the decision-making process are the main aims of the lecture. The students will be in the situation to argue their postitions open to constructive criticism and in a sustainable manner against a team. They will learn to accept minority viewpoints as well as argue for these themselves. The lecture will provide the tools to identify the important issues of a complex construction project as a group and find a best possible solution.


Recommended reading: Privates Baurecht Kapellmann/Langen, Einführung in die VOB/B,

Basiswissen für die Praxis Kimmich/Bach, VOB für Bauleiter Werner/Pastor, Der Bauprozess Ingenstau/Korbion, VOB Teile A und B Kapellmann/Messerschmidt, VOB Teile A und B Messerschmidt/Voit, Privates Baurecht Kniffka/Koeble, Kompendium des Baurechts Roquette/Otto, Vertragsbuch Privates Baurecht Hök, Handbuch des internationalen und

ausländischen Baurechts Öffentliches Baurecht Erbguth/Wagner, Grundzüge des öffentlichen

Baurechts Finkelnburg/Ortloff, Öffentliches Baurecht Band I:

Bauplanungsrecht Finkelnburg/Ortloff, Öffentliches Baurecht Band II:

Bauordnungsrecht, Nachbarschutz Gas, Baurecht schnell erfasst Schrödter, Baugesetzbuch Boeddinghaus, BauNVO Baunutzungsverordnung



BIB 7133 Steel Design and Timber Structures

Lecturers: Prof. Dr.-Ing. R. Pawlowski Prof. Dr.-Ing. M. Baumann Assistant Lecturers



Year of study:


Fourth


ECTS credits: 7 cp


Attendance:

Workload:

6 hours/week


Prerequisites: Technical Mechanics I+II (BIB 1021, BIB 2021) Engineering Mathematics (BIB 1011, BIB 2011) Construction Materials Technology (BIB 1041) Construction Engineering (BIB 4131)


Mode of delivery:


Face-to-face


Written exam, study assignment



Course content: Introduction in the standards and technical regulations Construction material wood and derived timber products Design and Construction of wooden support structures Mechanical joints in timber construction Torsional buckling (possibilites of verification beyond standards) Crane runways Service strength and fatigue Selection of construction material (lamellar fracture, brittle fragture) Steel Composite Girders Steel Composite Columns Buckling according to DIN EN 1993 Teil 1-5. Basic Principles of Torsion (St. Venant‘sche Torsion, Warping Torsion) Elastic and plastic ultimate load state in consideration of torsion at open thin-walled sections Verification of stability in consideration of torsion (theory of second order, approximation methods)

Learning outcomes: Ability to analyse and design timber supporting structures and evaluation of timber constructions.



Furhter and deepening knowledge and the appendant theoretical background knowledge of construction engineering in the field of steel design.


Recommended reading: handout aktuelle Fassung DIN EN 1995 mit Nationalen

Anhang für Deutschland DIN EN 1993 Teil 1-1, 1-5, 1-9, 1-10 und 6 DIN EN 1994 Ergänzende DAST Richtlinien Handbücher: Rstab, rfem Petersen: Statik und Stabilität Lindner, Scheer, Schmidt, Beuth Kommentare zum

EC NA-D und NA-F zum EC SIA 264



BIB 7161 Project Presentation

Lecturers: Prof. Dr.-Ing. Christoph Hupfer All Professors of the Faculty



Year of study:


Fourth


ECTS credits: 3 cp

Total workload: 90 hours

Prerequisites: None



Mode of delivery:

Project presentation

Face-to-face


Presentation


n/a

Course content: Set task from the area of civil engineering; generally subject of bachelor’s thesis

Learning outcomes: Indepent performance of a project using relevant methods for practical construction.





BIB BT Bachelor’s Thesis

Lecturers: Prof. Dr.-Ing. Christoph Hupfer All Professors of the Faculty



Year of study:


Fourth


ECTS credits: 12 cp

Total workload: 3 months

Prerequisites: Successful completion of minimum 7 subject examinations from the semesters 4 and 6



Mode of delivery:

Applying the learnt skills by independent treatment of a set task, with supervision

Independent work


Written Bachelor Thesis


n/a

Course content: Set task form the area of civil engineering

Learning outcomes: General: Independent work on a predetermined topic in a given time. Correlations /Deliminations to other modules: Contrary to a project work and the internship, the Bachelor's Thesis has to be conducted independently and without prohibited assistance. The duration is 3 months and therefore the first long-term work of the students. Integration in the vocational preparation: Verification of the independent performance of a project using relevant methods for practical construction.



BEng Modules, Course of Studies Civil Engineering BIB … · BIB 1011 Engineering Mathematics and...

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