English Descriptions of Courses - TU Berlin · 2011-01-26 · English Descriptions of Courses ......

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English Descriptions of Courses

Master Degree

Civil Engineering

Fakultät VI Planen Bauen Umwelt

Technische Universität Berlin

Ausgabe 2010

Herausgeber: Institut für Bauingenieurwesen

Fakultät VI Planen Bauen Umwelt Technische Universität Berlin

Gustav – Meyer – Allee 25, 13355 Berlin

Redaktion: Björn Rauscher & Katharina Teuber (Studentische Studienfachberatung)

Stand:

Dezember 2010

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Field of Expertise: Allgemeine Bauingenieurmethoden .................................................................. 4

Applied Technology of Construction Materials ..................................................................... 4

Concrete Technology .................................................................................................................. 6

Diagnostics and retrofitting of building constructions.......................................................... 8

Modern analytical methods in construction material testing ............................................. 10

Theory of thin‐walled structures ............................................................................................ 12

Finit Element Method I ............................................................................................................ 14

Finite Element Method II ......................................................................................................... 16

Finite Element Method III ........................................................................................................ 18

Structural Reliability Analysis ................................................................................................ 20

Advanced Issues of Building Physics I .................................................................................. 22

Advanced Issues of Building Physics II ................................................................................. 24

Optimization of Constructions under Aspects of Building Physics .................................. 26

Sustainable Building ................................................................................................................. 28

Models in Computation in Civil Engineering ....................................................................... 30

Geometric Models in Computation in Civil Engineering ................................................... 32

Process Models in Computation in Civil Engineering ........................................................ 34

Student Research Project – Computation in Civil Engineering .......................................... 36

Selected Topics in Computation in Civil Engineering ......................................................... 38

Field of Expertise: Entwerfen und Konstruieren ......................................................................... 40

Shells I ......................................................................................................................................... 41

Buildings II ................................................................................................................................. 43

Bridges II .................................................................................................................................... 45

Shells II ....................................................................................................................................... 47

Selected topics of structural engineering ............................................................................... 49

Design Seminar ......................................................................................................................... 51

Field of Expertise: Geotechnik ....................................................................................................... 52

Soil Dynamics ............................................................................................................................ 52

Numerical Methods in Geotechnical Engineering ............................................................... 53

Geotechnical Earthquake Engineering ................................................................................... 55

Geotechnical Laboratory .......................................................................................................... 56

Specialized Techniques for Large Geotechnical Projects .................................................... 58

Tunneling ................................................................................................................................... 60

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Geo‐Environmental Engineering ............................................................................................ 61

Special Topics in Geotechnical Engineering ......................................................................... 62

Geotechnical Seminar ............................................................................................................... 63

Field of Expertise: Wasserwesen ................................................................................................... 64

Water Resources Management ................................................................................................ 64

Hydro‐ and Environmental Numerical Modeling I ............................................................. 65

Hydro‐ and Environmental Numerical Modeling II............................................................ 67

Colloquium Hydro‐Engineering............................................................................................. 69

Urban Water Management ...................................................................................................... 70

Urban Water Management‐ Water supply ............................................................................ 72

Urban Water Management‐ Modern sanitary systems ....................................................... 74

Urban Water Management‐ Wastewater Treatment ............................................................ 75

Field of Expertise: Management .................................................................................................... 77

Life cycle I – Project development .......................................................................................... 77

Life cycle II – Project Management ......................................................................................... 79

Life cycle III – Property Management .................................................................................... 80

Project development in application ........................................................................................ 81

Management .............................................................................................................................. 82

Field of Expertise: Infrastruktur ................................................................................................... 84

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Field of Expertise: Allgemeine Bauingenieurmethoden

Applied Technology of Construction Materials Title of Module: Applied Technology of Construction Materials (Angewandte Baustofftechnologie)

Credit Point (ECTS): 6

Vertiefungsmodul

Person responsible for the module: Prof. Dr.‐Ing. B. Hillemeier

Secr.:TIB 1‐B4

Email:[email protected]‐berlin.de

Description of the module: 1. Aims of QualificationThe module “Applied Technology of construction materials” will deepen the theoretic knowledge especially regarding the mechanical behaviour of building materials. The students shall be able to calculate the failure of materials by means of the previously acquired abilities in mechanics and mathematics. Thereby students learn about the behaviour of several materials under different operational demands. The macroscopic material properties will be explained based on their microscopic configuration. Through statistical methods students shall be able to assess the reliability and the life expectancy of construction materials. Professional competence 50 % Methodical competence 20 % Scheme competence 15 % Social competence 15 % 2. Contents ‐ Composite materials ‐ Long term behaviour (permanent loading and non‐static loads) ‐ Fibre‐reinforced concrete technology ‐ Material strength hypothesis ‐ Fracture mechanics ‐ Moisture and deformation ‐ Transport processes ‐ Porosity and Corrosion ‐ Theories of reliability and statistical methods of quality assurance 3. References, Lecture notes Lecture notes as hardcopy: Lecture notes in electronic format: Further reading: 4. Modulbestandteile LV‐Titel LV‐Art SWS LP P / W / WP Semester

WiSe / SoSe Applied technology of construction materials

VL 2 3 WiSe

Applied technology of construction materials

UE 2 3 WiSe

5. Pre‐conditions for taking part Bachelor Degree

5

6. Workload and Creditpoints Presence VL 15 x 2 h = 30 h Presence UE 15 x 2 h = 30 h Prep and Post processing 15 x 2 h = 60 h Homework 30 h Prep for exam 60 h Total 180 h = 6 ECTS 7 Examination and Grading of the ModuleAdvance achievements during course (homework) ; Written exam (90 min) 8. Term of the Module Module can be finished within one Semester

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Concrete Technology Title of Module: Concrete Technology (Betontechnologie)


Vertiefungsmodul


Secr.:TIB 1‐B4


Description of the module: 1. Aims of QualificationThe module “Concrete Technology” teaches special knowledge in production, processing and curing of conventional concrete and concrete with special properties. Apart from strength, the quality characteristics of durability and robustness will be discussed. The results of concrete development towards a 6‐substance‐system will be conveyed. Each student prepares a course paper dealing with a specific concrete and its mixture composition. The theoretical knowledge will be verified through laboratory exercises. Professional competence 30 % Methodical competence 40 % Scheme competence 15 % Social competence 15 % 2. Contents ‐ Cement chemistry ‐ Conformity ‐ Site construction (Production, Processing, Curing) ‐ Concrete exposed to ambient conditions (exposition classes) ‐ Concretes for special applications ‐ Special concretes: self‐compacting concrete (SCC), acid resistant concrete (ARC), ultra high performance concrete (UHPC) 3. References, Lecture notes Lecture notes as hardcopy: Lecture notes in electronic format: Further reading: 4. Modulbestandteile LV‐Titel LV‐Art SWS LP P / W / WP Semester

WiSe / SoSe Concrete Technology VL 1 2 SoSe

Concrete Technology UE 1 1 SoSe


6. Workload and Creditpoints Presence VL 15 x 1 h = 15 h Presence UE 15 x 1 h = 15 h Prep and Post processing 15 x 1 h = 15 h Course paper 45 h Total 90 h = 3 ECTS 7 Examination and Grading of the ModulePS 8. Term of the Module Module can be finished within one Semester 9. Amount of participants No specification

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Diagnostics and retrofitting of building constructions Title of Module: Diagnostics and retrofitting of building constructions (Diagnostik und Ertüchtigung von Bauwerken)


Vertiefungsmodul


Secr.:TIB 1‐B4


Description of the module: 1. Aims of QualificationThe module “Diagnostics and retrofitting of building constructions” teaches knowledge for assessing existing buildings. Given the physical and chemical basics, students learn about the application of different non‐destructive testing methods. On the basis of practically relevant structural damage the different causes of damage, examination methods and possibilities of reconstruction will be discussed. Experts will report about the latest findings in research as well as on‐site applications. Professional competence 50 % Methodical competence 20 % Scheme competence 15 % Social competence 15 % 2. Contents ‐ Measuring and testing in civil engineering ‐ Non‐destructive testing: ultrasonic, radar, impulse echo ‐ Operational demands of construction materials ‐ Classification of harmful substances ‐ Mechanisms of deterioration ‐ Protection and corrective maintenance of structural elements ‐ Surface protection systems 3. References, Lecture notes Lecture notes in paperform: Lecture notes in electronic document form: Further reading: 4. Modulbestandteile LV‐Titel LV‐Art SWS LP P / W / WP Semester

WiSe / SoSe Diagnostics and retrofitting of building constructions

VL 2 3 SoSe

Diagnostics and retrofitting of building constructions

UE 2 3 SoSe


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6. Workload and Creditpoints Presence VL 15 x 2 h = 30 h Presence UE 15 x 2 h = 30 h Prep and Post processing 15 x 2 h = 30 h Homework 30 h Prep for exam 60 h Total 180 h = 6 ECTS 7 Examination and Grading of the ModuleWritten exam (90 min) 8. Term of the Module Module can be finished within one Semester 9. Amount of participants No specification

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Modern analytical methods in construction material testing Title of Module: Modern analytical methods in construction material testing (Moderne analytische Methoden in der Baustoffprüfung)


Vertiefungsmodul


Secr.:TIB 1‐B4


Description of the module: 1. Aims of QualificationThe module “Recent methods of construction material analytics” combines chemistry and civil engineering. On the basis of known civil engineering problems analytical chemical methods will be presented. In laboratory sessions students will work self‐consistent with modern equipment. Professional competence 50 % Methodical competence 20 % Scheme competence 15 % Social competence 15 % 2. Contents ‐ Thermodynamics (phase transition, frost‐proofing) ‐ Kinetics, phase and contact surfaces (surface tension, osmotic pressure, adhesion of coating) ‐ Thermal analysis (material composition) ‐ Calorimetric measurements (prevention of cracking) ‐ Composition of atoms and molecules, interaction of light and matter ‐ Infrared spectroscopy, chromatography (Fogging) ‐ Grain‐size analysis (Lasergranulometry, high performance concrete) ‐ Material composition (efflorescence, atomic absorption spectroscopy, chromatography ) 3. References, Lecture notes Lecture notes as hardcopy: Lecture notes in electronic format: Further reading: 4. Modulbestandteile LV‐Titel LV‐Art SWS LP P / W / WP Semester

WiSe / SoSe Recent methods of construction material analytics

VL 2 3 WiSe

Recent methods of construction material analytics

PR 2 3 WiSe


6. Workload and Creditpoints Presence VL 15 x 2 h = 30 h Presence PR 15 x 2 h = 30 h Prep and Post processing 15 x 4 h = 60 h Prep for exam 60 h Total 180 h = 6 LP

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7 Examination and Grading of the ModuleWritten exam (90 min) 8. Term of the Module Module can be finished within one Semester 9. Amount of participants No specification

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Theory of thin‐walled structures Name of the module: Theory of thin‐walled structures (Theorie der Flächentragwerke)

Credits (ECTS):6

Abbreviation: TFT

Person in charge: Prof. Dr.‐Ing. Y. Petryna

Secr.:TIB 1‐B5

Email:statik@tu‐berlin.de

Brief description 1. Objectives Competence in the theory of thin‐walled structures and in their static analysis by use of classical analytical methods. Ability to distinguish essentials in structural behaviour of shear walls, plates, membranes and shells, to choose appropriate mechanical models and solution approaches as well as to correctly interpret obtained results. Competence in application of the theory to practical problems of civil engineering. 2. Content Theory of shear walls, plane stress problems Technical plate theory Plastic line theory for plates Plate buckling Theory of shells with rotational symmetry, membrane theory Differential equations and solution approaches Ritz approach 3. Recommended literature, lecture notesHard and soft copies of lecture notes are available (in German). Details of recommended literature will be given during the course

4. Module elements Name Type SWS Credits Compulsory (P) /

compulsory optional (WP) / optional (W)

Semester (WiSe / SoSe)

TFT Lecture (VL)

2 3 P WiSe

TFT Exercises (UE)

2 3 P WiSe

5. Entry requirements Recommended: courses mechanics and continuum mechanics

6. Workload Attendance 15 x 4= 60 h Preparation and postprocessing 15 x 6= 90 h Preparation for written test 30 h Total 180 h = 6 Credits

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7. Examination Written test 120 min 8. Duration 1 semester 9. Maximum number of participants VL: unlimited, UE: 30

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Finit Element Method I Name of the module: Finite Element Method I (Lineare Finite‐Elemente‐Methode in der Baustatik)

Credits (ECTS):6

Abbreviation: FEM I


Secr.:TIB 1‐B5


Brief description 1. Objectives Competence in the theory of the finite element method and its application to linear static analysis of civil engineering structures. Competence in developing proper finite element models, choosing proper elements, discretization approaches and solution algorithms as well as to correctly interpret obtained results. 2. Content Ritz method, weighted residuals, displacement method and FEM Truss, beam, plane stress, plate, shell and volume elements Approximation functions, stiffness matrices and load vectors Isoparametric elements Assembling and transformations Accuracy, convergence and error processing Modelling aspects, application to civil engineering structures 3. Recommended literature, lecture notesHard and soft copies of lecture notes are available (in German). Details of recommended literature will be given during the course




FEM I Lecture (VL)

2 3 P WiSe

FEM I Exercises (UE)

1 2 P WiSe

FEM I Training (PR)

1 1 P WiSe

5. Entry requirements Theory of thin‐walled structures Recommended: courses in mechanics, strength of materials; Structural Analysis III 6. Workload Attendance 15 x 4= 60 h Preparation and postprocessing 15 x 4= 60 h Preparation for written test 60 h Total 180 h = 6 Credits

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7. Examination Written test 180 min 8. Duration 1 semester 9. Maximum number of participants VL: unlimited, UE: 20, Training 10

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Finite Element Method II Name of the module: Finite Element Method II (Nichtlineare Finite‐Elemente‐Methode in der Baustatik)

Credits (ECTS):6

Abbreviation: FEM II


Secr.:TIB 1‐B5


Brief description 1. Objectives Competence in the nonlinear theory of the finite element method and its application to a geometrically and physically nonlinear analysis of civil engineering structures. Competence in modelling nonlinear material behaviour including plasticity, cracking and damage. Competence in stability analysis of structures by FEM. Ability to develop proper finite element models, discretization approaches and nonlinear solution algorithms as well as to correctly interpret obtained results. 2. Content ‐ Basics of the beam buckling and plastic hinge theory; ‐ Elements of the plasticity theory, continuum, fracture and damage mechanics; ‐ Nonlinear material models for steel and concrete; ‐ Nonlinear kinematics, geometrical nonlinearity ‐ Geometrically and physically nonlinear stiffness relation; ‐ Incremental‐iterative solution algorithms; ‐ Stability analysis of frame, slab and shell structures ‐ Applications to civil engineering structures ‐ Nonlinear structural response to cyclic loading 3. Recommended literature, lecture notesHard and soft copies of lecture notes are available (in German). Details of recommended literature will be given during the course




FEM II Lecture (VL)

2 3 P SoSe

FEM II Exercises (UE)

1 2 P SoSe

FEM II Training (PR)

1 1 P SoSe

5. Entry requirements Obligatory: Theory of thin‐walled structures, FEM I Recommended: courses in mechanics, strength of materials; Structural Analysis III 6. Workload Attendance 15 x 4= 60 h Preparation and postprocessing 15 x 4= 60 h Preparation for written test 60 h Total 180 h = 6 Credits 7. Examination

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Written test 180 min 8. Duration 1 semester 9. Maximum number of participants VL: unlimited, UE: 20, Training 10

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Finite Element Method III Name of the module: Finite Element Method III (Finite‐Elemente‐Methode in der Baudynamik)

Credits (ECTS):6

Abbreviation: FEM III


Secr.:TIB 1‐B5


Brief description 1. Objectives Competence in the theory of the finite element method and its application to linear and nonlinear dynamic analysis of civil engineering structures. Competence in developing proper finite element models and solution algorithms as well as to correctly interpret obtained results. Competence in experimental and numerical modal analysis as well as earthquake structural analysis. 2. Content Linear and nonlinear differential equations of motion; Spatial and temporal discretization of dynamic boundary value problems; System mass, damping and stiffness matrices Modal analysis by FEM Model reduction and error estimates Linear and nonlinear solution algorithms Frequency and time domain approaches System identification and model update Application to civil engineering structures Structural response under earthquake loading Earthquake resistant design by FEM 3. Recommended literature, lecture notesHard and soft copies of lecture notes are available (in German). Details of recommended literature will be given during the course




FEM III Lecture (VL)

2 3 P WiSe

FEM III Exercises (UE)

1 2 P WiSe

FEM III Training (PR)

1 1 P WiSe

5. Entry requirements Structural Dynamics I (BSc), FEM I, II Recommended: courses in mechanics, strength of materials

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6. Workload Attendance 15 x 4= 60 h Preparation and postprocessing 15 x 4= 60 h Preparation for written test 60 h Total 180 h = 6 Credits 7. Examination Written test 180 min 8. Duration 1 semester 9. Maximum number of participants VL: unlimited, UE: 20, Training 10

Structural Reliability Analysis Name of the module: Structural Reliability Analysis (Stochastische Tragwerksanalyse und Tragwerkszuverlässigkeit)

Credits (ECTS):6

Abbreviation: ZUV


Secr.:TIB 1‐B5


Brief description 1. Objectives Competence in classical reliability theory and in simulation‐based stochastic methods of structural analysis in application to civil engineering structures. Ability to identify uncertain parameters in loading, geometry and material properties, to estimate their effect on structural safety and to choose a proper level of modelling and reliability analysis. Competence in the safety concept of European and German design codes. 2. Content ‐ Basics of the probability theory and statistics; ‐ Basic random variables and classical reliability theory; ‐ Probability of structural failure, convolution integral ‐ Reliability index, design point and partial safety factors ‐ Safety concept of Eurocodes and DIN codes ‐ Modelling of random processes and random fields ‐ Simulation‐based reliability methods, Monte Carlo approaches ‐ Response Surface Method and Latin‐Hypercube Sampling ‐ Stochastic aspects in fatigue analysis ‐ Time‐variant reliability analysis and lifetime estimation 3. Recommended literature, lecture notesHard and soft copies of lecture notes are available (in German). Details of recommended literature will be given during the course




ZUV Lecture (VL)

2 3 WP SoSe

ZUV Exercises (UE)

1 2 WP SoSe

ZUV Training (PR)

1 1 WP SoSe

5. Entry requirements Recommended: courses in mechanics, strength of materials; FEM I, MATLAB Introduction

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6. Workload Attendance 15 x 4= 60 h 4 Homeworks 4 x 15= 60 h Preparation for written test 60 h Total 180 h = 6 Credits 7. Examination Written test 180 min 8. Duration 1 semester 9. Maximum number of participants VL: unlimited, UE: 20, PR 10

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Advanced Issues of Building Physics I Name of the module: Advanced Issues of Building Physics I (Vertiefte Themen der Bauphysik I)

Credits (ECTS):6

Abbreviation: MScBauphysik I

Person in charge: Prof. Dr.‐Ing. Frank Ulrich Vogdt

Secr.:TIB 1‐B3

Email:bauphysik@tu‐berlin.de

Brief description 1. Objectives The students acquire an advanced knowledge in selected fields of building physics. The priority of this module is to show students the state of the art to solve building physical problems with computer‐aided modeling and to give them a basic understanding of the software that is used in practice. Specific fields are the coupled heat and moisture transport, questions of building acoustics and fire protection as well as thermal comfort. professional competence 50 % methods competence 25 % system competence 20 % social competence 5 % 2. Content advanced knowledge of moisture protection thermal bridges, avoidance of mildews, weather protection coupled heat and moisture transport transient hygrothermal calculation methods building simulation (Gebäudesimulation)

3. Recommended literature, lecture notesHard and soft copies of lecture notes are available. Details of recommended literature will be given in the lecture or on the homepage of the chair (www.bauphysik@tu‐berlin.de). 4. Module elements Name Type SWS Credits deepening (V) /

basis (B) Semester (WiSe / SoSe)

Vertiefte Themen der Bauphysik I

VL

2 3 V WiSe

Vertiefte Themen der Bauphysik I

UE 2 3 V WiSe

5. Entry requirements none

6. Workload Attendance 15 x 4= 60 h Preparation and postprocessing 15 x 4= 60 h Preparation for written test 60 h Total 180 h = 6 Credits 7. Examination Study effort equivalent to the examination (PS)

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8. Duration 1 semester 9. Maximum number of participants no specification

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Advanced Issues of Building Physics II Name of the module: Advanced Issues of Building Physics II (Vertiefte Themen der Bauphysik II)

Credits (ECTS):6

Abbreviation: MScBauphysik II


Secr.:TIB 1‐B3


Brief description 1. Objectives The students acquire an advanced knowledge in energetic balancing of residential‐ and non residential buildings. The purpose is to provide an understanding of the optimization possibilities with relation to the interaction between structural thermal protection and installation systems (heating, cooling, ventilation, domestic hot water, lighting). Subsequently the students will apply their knowledge in practical exercises up to the issuance of the energy performance certificates for buildings. professional competence 50 % methods competence 25 % system competence 20 % social competence 5 % 2. Content historical development (DIN 4108, Energy Saving Law (EnEG), Heat Insulation Ordinance (WschVo), European Energy Performance of Buildings Directive (EPBD)) structural thermal protection, building services energetic balancing according to the Energy Saving Ordinance (EnEV) for residential buildings energetic balancing according to DIN V 18599 for non‐residential buildings (typology of building, reference building method, zoning, etc.) reference values, benchmarks and target values for evaluation of the energetic efficiency issuance of the energy performance certificate for buildings 3. Recommended literature, lecture notesHard and soft copies of lecture notes are available. Details of recommended literature will be given in the lecture or on the homepage of the chair (www.bauphysik@tu‐berlin.de). 4. Module elements Name Type SWS Credits deepening (V) /


Vertiefte Themen der Bauphysik II

VL

2 3 V SoSe

Vertiefte Themen der Bauphysik II

UE 2 3 V SoSe

5. Entry requirements none

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6. Workload Attendance 15 x 4= 60 h Preparation and postprocessing 15 x 4= 60 h Preparation for written test 60 h Total 180 h = 6 Credits 7. Examination written test 8. Duration 1 semester 9. Maximum number of participants no specification

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Optimization of Constructions under Aspects of Building Physics Name of the module: Optimization of Constructions under Aspects of Building Physics (Bauphysikalische Optimierung von Baukonstruktionen)

Credits (ECTS):6

Abbreviation: MScOptBauko


Secr.:TIB 1‐B3


Brief description 1. Objectives The students obtain an advanced knowledge in optimizing constructions in terms of building physical problems under the consideration of the partly opposed requirements of the heat, moisture, sound and fire protection. Beyond those questions economic viability will also be considered. professional competence 50 % methods competence 25 % system competence 20 % social competence 5 % 2. Content roof structures (high‐pitched roof, flat roof) ceilings (conventional, thermo‐active, etc.) external walls (thermal insulation composite systems (WDVS), rear ventilated curtain wall (VHF), etc.) glass facades, windows, doors building components close to the ground (base slabs, basement walls)

3. Recommended literature, lecture notesHard and soft copies of lecture notes are available. Details of recommended literature will be given in the lecture or on the homepage of the chair (www.bauphysik@tu‐berlin.de). 4. Module elements Name Type SWS Credits deepening (V) /


Bauphysikalische Optimierung von Baukonstruktionen

VL 2 3 V/B SoSe

Bauphysikalische Optimierung von Baukonstruktionen

UE 2 3 V/B SoSe

5. Entry requirements certificate of performance for the module Basics of Building Physics (Grundlagen der Bauphysik)

6. Workload Attendance 15 x 4= 60 h Preparation and postprocessing 15 x 4= 60 h Preparation for written test 60 h Total 180 h = 6 Credits 7. Examination written test

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8. Duration 1 semester 9. Maximum number of participants no specification

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Sustainable Building Name of the module: Sustainable Building (Nachhaltiges Bauen)

Credits (ECTS):6

Abbreviation: MScNachBau


Secr.:TIB 1‐B3


Brief description 1. Objectives The students acquire a basic knowledge of sustainable building. The purpose is to provide a basic understanding of the dimensions of sustainability and their interactions within the whole life cycle of a building. The students will apply their attained knowledge in practical exercises within a quantitative economical and ecological valuation (Life Cycle Assessment (LCA) and Life Cycle Costing (LCC)) of variations of construction details or buildings. After finishing the module the students will be able to evaluate quantifiable criteria of sustainability on an objective base. professional competence 50 % methods competence 25 % system competence 20 % social competence 5 % 2. Content dimensions of the sustainable building (ecological, economical, socio‐cultural) life cycle phases: raw materials, construction, use phase, maintenance, modernization, demolition, recycling)protection goals (careful use of resources, protection of the environment, conservation of value, reduction of running costs, health protection, (thermal) comfort, etc.) life cycle consideration (ecological (LCA), economical (LCC)) indicators of sustainability and their data base 3. Recommended literature, lecture notesHard and soft copies of lecture notes are available. Details of recommended literature will be given in the lecture or on the homepage of the chair (www.bauphysik@tu‐berlin.de). 4. Module elements Name Type SWS Credits deepening (V) /


Nachhaltiges Bauen VL 2 3 V/B WiSe

Nachhaltiges Bauen UE 2 3 V/B WiSe

5. Entry requirements certificate of performance for the module Basics of Building Physics (Grundlagen der Bauphysik)

28

6. Workload Attendance 15 x 4= 60 h Preparation and postprocessing 15 x 4= 60 h Preparation for written test 60 h Total 180 h = 6 Credits 7. Examination written test 8. Duration 1 semester 9. Maximum number of participants no specification

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Models in Computation in Civil Engineering

Name of the module: Models in Computation in Civil Engineering (Modelle der Bauinformatik)

Credits (ECTS):6

Abbreviation: Models

Person in charge: Prof. Dr.‐Ing. Wolfgang Huhnt

Secr.:TIB 1‐B8

Email:wolfgang.huhnt@tu‐berlin.de

Brief description 1. Objectives Students learn fundamentals of modeling in computation in civil engineering. Professional competence 45% methodological competence 35% system competence 20%

social competence 0% 2. Content ‐ Data structures ‐ Persistent storage ‐ Versioning, dependencies and consistency ‐ CAE‐Models ‐ Models for operating facilities ‐ Information models for building constructions ‐ Information models for business administration ‐ Exemplary application on civil engineering problems 3. Recommended literature, lecture notesHard and soft copies of lecture notes are available. See recommended literature in lecture notes. 4. Module elements Name Lecture

Type SWS Credits Compulsory (P) /

compulsory optional (WP) /

optional (W)

Semester (WiSe /

SoSe)

Models in Civil Engineering VL 2 3 WiSe

Models in Civil Engineering UE 2 3 WiSe

Total 4 6

5. Entry requirements Compulsory modules in Computation in Civil Engineering

6. Workload and creditsAttendance 15 x 4 = 60 h Preparation and postprocessing 90 h Preparation for written test 30 h Total 180 h = 6 Credits 7. Examination Written test (2h)

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8. Duration 1 semester 9. Maximum number of participants not specified

31

Geometric Models in Computation in Civil Engineering

Name of the module: Geometric Models in Computation in Civil Engineering (Geometric Modelle der Bauinformatik)

Credits (ECTS):6

Abbreviation: Geometric Models


Secr.:TIB 1‐B8


Brief description 1. Objectives

Students learn about geometric models in civil engineering. They acquire the skills and methods for the description of geometrical properties of buildings and natural systems. They gain a theoretical foundation and understanding of computation in geometric modeling

Professional competence 45% methodological competence 35% system competence 20% social

competence 0% 2. Content ‐ Mathematical basics in geometry ‐ Suitable descriptions of geometrical properties of buildings and natural systems and their visualization

on computers ‐ Mesh generation ‐ Construction of models on the computer ‐ Visualization of physical variables ‐ Exemplary application on civil engineering problems. 3. Recommended literature, lecture notesHard and soft copies of lecture notes are available. Details of recommended literature will be given in the lecture.

4. Module elements Name Lecture



optional (W)

Semester (WiSe /

SoSe)

Geometric Models in civil engineering

VL

2 3 SoSe

Geometric Models in civil engineering

UE 2 3 SoSe

Total 4 6

5. Entry requirements

Compulsory modules in Computation in Civil Engineering

6. Workload Attendance 15 x 4 = 60 h Preparation and postprocessing 90 h Preparation for written test 30 h Total 180 h = 6 Credits

32

7. Examination Written test.(2h) 8. Duration 1 semester 9. Maximum number of participants not specified

33

Process Models in Computation in Civil Engineering Name of the module: Process Models in Computation in Civil Engineering (Prozessmodelle der Bauinformatik)

Credits (ECTS):6

Abbreviation: Process Models


Secr.:TIB 1‐B8


Brief description 1. Objectives Students learn about process models in civil engineering. They are trained on describing discrete processes.

They gain a theoretical foundation and understanding of computation in process modeling in formal and computable structures.

Professional competence 45% methodological competence 35% system competence 20% social

competence 0% 2. Content ‐ Process models: Sets and relations ‐ Model concepts for processes in civil engineering ‐ Graph theory, algorithms ‐ Process models in different detailed stages ‐ Disposition within specified fixed dates ‐ Exemplary application on civil engineering problems 3. Recommended literature, lecture notesHard and soft copies of lecture notes are available. Details of recommended literature will be given in the lecture.




optional (W)

Semester (WiSe /

SoSe)

Process Models in civil engineering

VL

2 3 SoSe

Process Models in civil engineering

UE 2 3 SoSe

Total 4 6


Compulsory modules in Computation in Civil Engineering

6. Workload Attendance 15 x 4 = 60 h Preparation and postprocessing 90 h Preparation for written test 30 h Total 180 h = 6 Credits Homework is optional.

34

7. Examination Written test.(2h) 8. Duration 1 semester 9. Maximum number of participants not specified

35

Student Research Project – Computation in Civil Engineering

Name of the module: Student Research Project – Computation in Civil Engineering (Projekt Bauinformatik)

Credits (ECTS):6

Abbreviation: Msc SRP‐Bauinfo


Secr.:TIB 1‐B8


Brief description 1. Objectives Students develop a pilot implementation for computationally solving a task in the field of civil engineering.

They learn a structured approach to address the selected task. According to the chosen task different working steps may be necessary such as planning, modeling, design, simulation, visualization and documentation.

professional competence 45% methodological competence 30% system competence 20% social

competence 10% 2. Content The contents vary depending on the chosen task. The task is chosen from topics which have previously been dealt with

in courses which the students have attended, for example geometry, process modeling or numerical calculation.

3. Recommended literature, lecture notesHard and soft copies of lecture notes are available. Details of recommended literature will be given in the lecture.



optional (W)

Semester (WiSe /

SoSe)

Student Research Project – Computation in Civil Engineering

PJ

4 6 WP WiSe and SoSe

5. Entry requirements Compulsory module in computation in civil engineering, models in civil engineering or another module

offered in computation in civil engineering 6. Workload Attendance 15 x 4 = 60 h Preparation and processing of presentation 120 h Total 180 h = 6 Credits 7. Examination Exam equivalent course achievement

36

8. Duration 1 semester 9. Maximum number of participants not specified

37

Selected Topics in Computation in Civil Engineering

Name of the module: Selected Topics in Computation in Civil Engineering (Ausgewählte Themen der Bauinformatik)

Credits (ECTS):6

Abbreviation: Selected Topics


Secr.:TIB 1‐B8


Brief description 1. Objectives Computing in civil engineering is a field, in view of the progress in the fields of information and

communication, which is open to new application areas for civil engineering. Examples include the acquisition of information on buildings, consolidation and evaluation leading towards effective implementation and control of working processes or the use of simulation techniques for complex construction processes. Students acquire deepened knowledge in selected topics of computation in civil engineering and are taught to solve special tasks independently.

professional competence 45% methodological competence 35% system competence 20% social

competence 0% 2. Content The contents vary depending on the chosen task, e.g. ‐ Sensors, storing large data sets, analysis of large data sets, control of buildings. ‐ Animation of planning and construction processes, simulation methods and their application, modeling of

constraints





optional (W)

Semester (WiSe /

SoSe)

Selected topics in civil engineering

VL

2 3 SoSe

Selected topics in civil engineering

UE 2 3 SoSe

Total 4 6

5. Entry requirements Compulsory modules in Computation in civil engineering, Models in Civil Engineering

6. Workload Attendance 15 x 4 = 60 h Preparation and postprocessing of presentation 90 h Preparation for written test 30 h Total 180 h = 6 Credits

38

7. Examination Written test (2h) 8. Duration 1 semester 9. Maximum number of participants not specified

39

Field of Expertise: Entwerfen und Konstruieren English descriptions of the modules „Hochbau I“, „Brückenbau I“, „Brückenbau III“, „Konstruieren von Stahltragwerken“ and „Entwurfsseminar“ will follow. Meanwhile, please use the german descriptions. Therefore, please visit the following homepage: http://www.bau.tu‐

berlin.de/uploads/media/030909_Studienf_hrer_Bauingenieurwesen__MSc__2009‐2010_Anhang.pdf

40

http://www.bau.tu-berlin.de/uploads/media/030909_Studienf_hrer_Bauingenieurwesen__MSc__2009-2010_Anhang.pdf



Shells I Name of the module: Shells I (Flächentragwerke I)

Credits (ECTS):6

Abbreviation: FT I

Person in charge: Prof. Dr.‐Ing. Volker Schmid

Secr.:TIB 1‐B 11

Email:ek‐verbundstrukturen@ tu‐berlin.de

Brief description 1. Objectives The students will gain a fundamental understanding for the conceptual and structural design of shells and plates, i.e. wide spanning and light weight cable, membrane, glass, steel and reinforced concrete structures. This module, part I of shells, deals with a special case of shells, which are plates and in particular with slender plates and folded plates. Aspects that will be looked at is the conceptual design of these structural systems, prestressing of slabs, cracked concrete properties and its effects on the structure, deflection behaviour and the dynamic behaviour. professional competence 60% method competence 20% system competence 10% social competence 10% 2. Content Conceptual and structural design of slender plates, using post‐tensioned slabs as an example Deflection calculation of slender concrete structures Cracked concrete sections properties Dynamic design Imposed strain on reinforced concrete structures Design of basements, crack width calculations FE for plates and deep beams Design of reinforced concrete folded plates This module is based on the introductory courses up to semester 6 and deepens the understanding for the topics of previous sessions focusing on a structure as whole. This module deepens also further the understanding for the method of “Conceptual and structural design”. As such it serves as a preparation for the “Design seminar” towards the end of the studies. 3. Recommended literature, lecture notesHard and soft copies of lecture notes are available. Details of recommended literature will be given in the lecture.

4. Module elements Name Ty

pe SWS

Credits

Compulsory (P) / compulsory optional (WP) / optional (W)

Semester WiSe / SoSe

Shells VL 2 3 P WiSe od SoSe

Shells UE 2 3 P WiSe od SoSe

5. Entry requirements BSc

6. Workload

41

Attendance VL 15 x 2 = 30 h Attendance UE 15 x 2= 30 h Preparation and postprocessing 40 h Presentation 20 h Preparation for written test 60h Total 180 h = 6 Credits 7. Examination presentation prior to test, written test (2h)

8. Duration 1 semester 9. Maximum number of participants N/A

42

Buildings II Name of the module: Buildings II (Hochbau II)

Credits (ECTS):6

Abbreviation: B II


Secr.:TIB 1‐B 11


Brief description 1. Objectives The students will be introduced to advanced concepts of the design of special buildings such as high rise buildings, warehouses and important building components such as façades. This course will enable students to produce concepts, analysis models and design such buildings independently. professional competence 60% method competence 20% system competence 10% social competence 10% 2. Content Conceptual design and structural engineering of high rise buildings, warehouses and façades: The topic warehouses deals in particular with timber warehouses, where the anisotropic material timber and its special properties are highlighted. High rise buildings are looked at as an example of tower like structures. Differences to conventional buildings are shown. Special importance is given to the dynamic behaviour of such structures. Furthermore the principles of façades are introduced and the design of glass façades will be shown. This module is based on the introductory courses up to semester 6 as well as the lecture “Buildings I”. As such it serves as a preparation for the “Design seminar” towards the end of the studies. 3. Recommended literature, lecture notesHard and soft copies of lecture notes are available. Details of recommended literature will be given in the lecture.


pe SWS

Credits



Buildings VL 2 3 P WiSe od SoSe

Buildings UE 2 3 P WiSe od SoSe


43

6. Workload Attendance VL 15 x 2 = 30 h Attendance UE 15 x 2= 30 h Preparation and postprocessing 40 h Presentation 20 h Preparation for written test 60h Total 180 h = 6 Credits 7. Examination Presentation prior to test, written test (2h) 8. Duration 1 semester 9. Maximum number of participants N/A

44

Bridges II Name of the module: Bridges II (Brückenbau II)

Credits (ECTS):6

Abbreviation: BR II

Person in charge: Prof. Dr. sc. techn. M. Schlaich

Secr.:TIB 1‐B2

Email:mike.schlaich@tu‐berlin.de

Brief description 1. Objectives Cables, cable supported bridges such as cable‐stayed bridges and suspension bridges as well as light‐weight pedestrian bridges are dealt with in this class. Students are introduced to classic structural solutions and new developments in the field of cable‐supported bridges. At the end of this course students will have an overview on all cable related structural issues and they will have exercised pre‐dimensioning of a cable‐stayed bridge. professional competence 60 % method competence 20 % system competence 10 % social competence 10 % 2. Content Theorie of cables (rigid and elastic) Cable types, matrerials and dimensioning of cables Typical connections and anchorages Conceptual and Structural Design of cable‐stayed bridges Conceptual and Structural Design of suspension bridges Variety in footbridge design Discussion of new bridge types like integral, extra dosed and movable bridges This module bases on the class “bridges I” (Brückenbau I). It prepares the students for the “design seminars” where bridges are designed frequently. 3. Recommended literature, lecture notesHard and soft copies of lecture notes are available. Details of recommended literature will be given in the lecture.

4. Module elements Name Type SWS Credit

s Compulsory (P) / compulsory optional (WP) / optional (W)


Brückenbau II VL

2 2 P WiSe

Brückenbau II UE

2 2 P WiSe

5. Entry requirements Bachelor

6. Workload Attendance VL 15 x 2 = 30 h Attendance UE 15 x 2= 30 h Preparation and postprocessing 40 h Lecture 20 h Preparation for written test 60h Total 180 h = 6 Credits

45

7. Examination placement test (lecture), written test (2h) 8. Duration 1 semester 9. Maximum number of participants VL: n/a, UE: 45, TUT: 15

46

Shells II Name of the module: Shells II (Flächentragwerke II)

Credits (ECTS):6

Abbreviation: FT II


Secr.:TIB 1‐B2


Brief description 1. Objectives This class deals with double‐curved light‐weight shell and membrane structures made of different materials. Student obtain an introduction to the membrane theory as well as issues of conceptual and structural design issues and attain knowledge about the characteristics of ʺnewʺ materials such as glass, membranes and synthetic materials (ʺcompositesʺ) and their possible application. Students will be provided with knowledge and insight to the design of long‐span and light‐weight roofs professional competence 60 % method competence 20 % system competence 10 % social competence 10 % 2. Content ‐ Description and explanation of the load bearing behaviour of structures with double curved surfaces such as concrete shells, cable nets, net domes, to spoked wheel roofs etc; ‐ Membrane and shell theory, double curvature with cable nets and membrane buildings structures. ‐ Construction with new materials: design criteria for membranes, glass, synthetic materials, application possibilities in the civil engineering and calculation methods; ‐ Execution of pneumatic supported membrane structures; ‐ tank building: construction and special load problems This module is based on the introducing lectures of the first 6 terms as well as on the lectures to the bases of the “shells I” (Flächentragwerke I). It serves as preparation for the design seminar at the end of the study. 3. Recommended literature, lecture notesHard and soft copies of lecture notes are available. Details of recommended literature will be given in the lecture.




Flächentragwerke II VL

2 2 P WiSe

Flächentragwerke II UE 2 2 P WiSe


47

6. Workload Attendance VL 15 x 2 = 30 h Attendance UE 15 x 2= 30 h Preparation and postprocessing 40 h Lecture 20 h Preparation for written test 60h Total 180 h = 6 Credits 7. Examination placement test (lecture), written test (2h) 8. Duration 1 semester 9. Maximum number of participants VL: n/a, UE: 45, TUT: 15

48

Selected topics of structural engineering Name of the module: Selected topics of structural engineering (Ausgewählte Kapitel aus dem Konstruktiven Ingenieurbau)

Credits (ECTS):6

Abbreviation:


Secr.:TIB 1‐B 11


Brief description 1. Objectives The students will be introduced to advanced concepts in particular areas of reinforced concrete construction, light weight structures and timber construction. This course will enable students to solve problems relating to these special fields independently. The students will gain the knowledge to understand the complex behaviour of the material reinforced concrete and hence understand its influences on the structure comprehensively. The students will also gain understanding in the area of construction of existing buildings, i.e. evaluation of existing buildings as well as the conceptual design of remedial work and retrofitting. professional competence 60% method competence 20% system competence 10% social competence 10% 2. Content From the area of reinforced concrete construction, the following 4 topic will be covered in detail, which where only briefly introduced during the Bachelor courses: Creep, shrinkage (starting with the knowledge from KI3) Plasticity (Condition II and III) Advanced prestressed concrete High strength and fibre reinforced concrete From the area of light weight structures, the following topics will be covered in detail: Wind engineering Glass construction From the area of timber construction, the following topics will be covered in detail: Further study of the fundamentals of construction with timber as well as Timber composite structures, and timber and wood based products Conceptual design of timber structures Structures of buildings as well as civil structures Special problems of the design From the area of construction with existing structures, the following topics are covered in detail: Fundamentals in the use with existing materials and structures Evaluation of existing structures Formulation of construction and design fundamentals for remedial work and retrofitting of structural elements and its connections. 3. Recommended literature, lecture notesHard and soft copies of lecture notes are available. Details of recommended literature will be given in the lecture.

49


pe SWS

Credits



Selected topics of rc SE 2 3 P WiSe od SoSe

Selected topics of light weight structures

SE 2 3 P WiSe od SoSe

Selected topics of timber construction

SE 2 3 P WiSe od SoSe

Construction in existing buildings SE 2 3 P WiSe od SoSe


6. Workload Attendance SE 30 x 2 = 60 h Preparation and postprocessing 60 h Preparation for written test 60 h Total 180 h = 6 Credits 7. Examination Written test (2x1,5h) about two of the four offered module parts 8. Maximum number of participants SE: 10 8. Duration 1 semester 9. Maximum number of participants N/A

50

Design Seminar Name of the module: Design Seminar (Entwurfsseminar)

Credits (ECTS):6

Abbreviation: ES


Secr.:TIB 1‐B2


Brief description 1. Objectives The conceptual design phase is the birth of a structure and defines its quality. The knowledge acquired up to now in classes such as “buildings”, “bridges” and “shells” is used here to actually design a structure, i.e. to conceive, model, dimension and detail a bridge a tower or a building. Creativity and the application of theoretical knowledge is trained. At the end of the course the individual teams will present and explain their project. professional competence 20 % method competence 20 % system competence 20 % social competence 40 % 2. Content Design of an engineering structure (bridge or building construction) based on the local boundary conditions. Realistic problems such as the ones given in the annual “Schinkel competition” are used the task. The module will be supervised and guided by scientific assistants and the professors for Conceptual and Structural Design.





Entwurfsseminar SE 4 6 P WiSe


6. Workload Presence IV 15 x 4 = 60 h Draft development and presentation 120 h Total 180 h = 6 Credits

7. Examination oral consultation and presentation 8. Duration 1 semester 9. Maximum number of participants VL: n/a, UE: 45, TUT: 15

51

Field of Expertise: Geotechnik

Soil Dynamics Name of the module: Soil Dynamics (Baugrunddynamik)

Credits (ECTS):6

Module of basics and specialization

Person in charge: Prof. Dr.‐Ing. S. Savidis

Secr.:TIB 1‐B7


Brief description 1. Objectives Students acquire deep scientific and practical knowledge from the field of soil dynamics. They will be able to design foundations subject to non‐stationary loads. Expertise 40% Method skills 30% System skills 20% Social skills 10% 2. Content Fundamentals of systems in structural dynamics, systems with lumped masses, homogenous solutions of free vibrating discrete models, wave propagation in soils, foundations subject non‐stationary loads.




Baugrunddynamik VL

2 3 WP SoSe

Baugrunddynamik UE 2 3 WP SoSe


5. Examination Oral examination 6. Duration of the Module The module can be accomplished in one semester. 7. Workload Attendance 15 x 4= 60 h Preparation and postprocessing 15 x 4= 60 h Preparation for oral test 15 x 4= 60 h Total 180 h = 6 Credits 8. Maximum number of participants VL: n/a, UE: 30

52

Numerical Methods in Geotechnical Engineering Name of the module: Numerical Methods in Geotechnical Engineering (Numerische Verfahren in der Geotechnik)

Credits (ECTS):6

Module of basics and specialization


Secr.:TIB 1‐B7


Brief description 1. Objectives Students acquire deep theoretic and practical knowledge about numerical methods and their geotechnical appliance. They are able to create numerical models of complex foundations and retaining structures, to understand the influence of loading history on the soil‐structure interaction, and finally to solve this influence with appropriate numerical methods. They are being trained in small groups on computers and learn how to apply FEM Software to specific examples from practice, and they are qualified to solve complex problems in design firms. Throughout the project students will gain hands‐on experience by solving real‐word problems. Expertise 35% Method skills 30% System skills 20% Social skills 15% 2. Content Introduction to the geotechnical FEM Software, stress state at rest, constitutive modelling of the non‐linear behaviour of soil, numerical implementation of non‐linear constitutive equations, comparison of different constitutive equations, drained and undrained behaviour of soil, consolidation, simulation of construction stages, examples from practice. 3. Module elements Name Type SWS Credit



Numerische Verfahren in der Geotechnik

VL

2 3 WP SoSe

Numerische Verfahren in der Geotechnik

PR 2 3 WP SoSe

4. Entry requirements Bachelor. Basic knowledge of finite elements is desirable.

5. Examination Study effort equivalent to the examination (PS): Oral discussion, and project with written report and short presentation of the results. 6. Duration The module can be accomplished in one semester.

53

7. Workload Attendance 60h Preparation and post processing 60h Project 30h Preparation for written test 30h Total 180h = 6 Credits 8. Maximum number of participants VL: n/a, PR: 10

54

Geotechnical Earthquake Engineering Name of the module: Geotechnical Earthquake Engineering (Geotechnisches Erdbebeningenieurwesen)

Credits (ECTS):3

Module of specialization


Secr.:TIB 1‐B7


Brief description 1. Objectives Students acquire scientific and practical knowledge of geotechnical earthquake engineering. They will be in position to project simple foundations in seismic areas for seismic loads. Expertise 40% Method skills 30% System skills 20% Social skills 10% 2. Content Impact and formation of earthquakes, seismological basics, propagation of earthquakes, determination of parameters of seismic loads, procedure for the calculation of seismic soil‐structure interaction, seismic design of foundations, improvement of buildings in seismic areas, methods of active and passive seismic isolation for buildings, comparison of international codes.




Geotechnisches Erdbebeningenieurwesen

VL

2 3 WP WiSe

4. Entry requirements Bachelor. Completed module “Soil Dynamics” is desirable.

5. Examination Oral examination. 6. Duration The module can be accomplished in one semester. 7. Workload Attendance 15 x 2= 30 h Preparation and post processing 30 h Preparation for oral test 30 h Total 90 h = 3 Credits

55

Geotechnical Laboratory Name of the module: Geotechnical Laboratory (Bodenmechanisches und bodendynamisches Praktikum)

Credits (ECTS):6



Secr.:TIB 1‐B7


Brief description 1. Objectives Students acquire theoretical and experimental knowledge of soil‐mechanical and soil‐dynamical experiments. By means of individual performance of laboratory experiments the students acquire a sound understanding of soil mechanical test to improve their skill to evaluate and prepare geotechnical reports, as well as to supervise laboratory experiments and field tests. Expertise 40% Method skills 20% System skills 30% Social skills 10% 2. Content Basics of geotechnical measurement, methods of monitoring, laboratory experiments, subsoil‐characteristics, oedometric tests, triaxial tests, direct shear tests, in situ tests like: drilling, sounding, sampling, plate‐loading test and more. Vibration propagation due to traffic load and construction operations, design of protection against vibrations induced by railway traffic, methods of vibration insulation, soil‐dynamical tests in the laboratory and field including the demonstration of soil‐dynamical measurement.




Bodenmechanisches Labor‐ und Feldpraktikum (Geotechnical Laboratory and Field Testing)

PR

2 3 WP SoSe

Erschütterungsschutz und bodendyn. Versuchswesen (Vibration Isolation and Soil Testing)

PR 2 3 WP WiSe

4. Entry requirements preferable: „Fluid and Soil Mechanics“ (Strömungs‐ und Bodenmechanik) module.

5. Examination Study effort equivalent to the examination (PS): Written report with oral discussion. 6. Duration The module can be accomplished in one semester.

56

7. Workload Attendance (6+6) x 5= 60 h Preparation (6+6) x 1= 12 h Post processing (6+6) x 3= 36 h Written composition 2x 26= 52h Preparation for oral test 20h= 20 h Total 180 h = 6 Credits 8. Maximum number of participants PR: 4

57

Specialized Techniques for Large Geotechnical Projects Name of the module: Specialized Techniques for Large Geotechnical Projects (Verfahren des Spezialtiefbaus für Geotechnische Großprojekte)

Credits (ECTS):6



Secr.:TIB 1‐B7


Brief description 1. Objectives Students acquire theoretical and practical knowledge of ground improvement and ground stabilization techniques and learn more about the design and the realization of large geotechnical projects. They are able to design ground improvement and ground stabilization projects in different soils. Furthermore, students are also able to design complex foundation structures with engineers of other specializations considering difficult boundary conditions. They learn to consider the interaction of the processes with other constructions and the importance of environmental aspects. Expertise 60% Method skills 20% System skills 10% Social skills 10% 2. Content Processes of ground improvement and ground stabilization, fields of application, soil compaction and soil replacement, injection procedure and injection materials. Technological, environmental, and infrastructural boundary conditions of the design and realization of large geotechnical projects, applicability of special construction methods for walls, bases and anchors, design options and applications in large projects.




Bodenverbesserung und Bodenverfestigung (Soil Improvement Techniques)

IV

2 3 WP WiSe

Planung und Ausführung geotechnischer Großprojekte (Designing and Realisation of Large Geotechnical Projects)

IV 2 3 WP SoSe

4. Entry requirements Bachelor.

5. Examination Oral examination.

58

6. Duration The module can be accomplished in one semester. 7. Workload Attendance (15+15) x 2= 60 h Preparation and postprocessing (15+15) x 2= 60 h Project 60 h Total 180 h = 6 Credits

59

Tunneling Name of the module: Tunneling (Tunnelbau)

Credits (ECTS):3



Secr.:TIB 1‐B7


Brief description 1. Objectives Students acquire theoretical and practical knowledge of tunneling. They learn the features of open and closed tunnel constructions and they are in position to create tunnels for different types of soil with and without groundwater. They learn to consider the interaction of the tunnel with other subsoil constructions and with the environment. Expertise 60% Method skills 20% System skills 10% Social skills 10% 2. Content Open and closed tunnel constructions, tunnel driving techniques, securings.




Tunnelbau IV

2 3 WP WiSe


5. Examination Oral examination. 6. Duration The module can be accomplished in one semester. 7. Workload Attendance 15 x 2= 30 h Preparation and postprocessing 30 h Preparation for oral test 30 h Total 90 h = 3 Credits

60

Geo‐Environmental Engineering Name of the module: Geo‐Environmental Engineering (Umweltgeotechnik)

Credits (ECTS):3



Secr.:TIB 1‐B7


Brief description 1. Objectives Students acquire theoretical and practical knowledge of geo‐environmental engineering: exploration and cleanup of former waste deposits, types of landfill sites and manufacturing technologies of sealing systems. Furthermore the students acquire knowledge of the legal basis, geotechnical qualification tests and quality control. The students are able to design safe sealing systems for different profiles of the subsoil. Expertise 60% Method skills 20% System skills 10% Social skills 10% 2. Content Waste deposits, exploration and decontamination and landfill technology.




Umweltgeotechnik IV

2 3 WP SoSe


5. Examination Oral examination. 6. Duration The module can be accomplished in one semester. 7. Workload Attendance 15 x 2= 30 h Preparation and postprocessing 30 h Preparation for oral test 30 h Total 90 h = 3 Credits

61

Special Topics in Geotechnical Engineering Name of the module: Special Topics in Geotechnical Engineering (Spezielle Kapitel der Geotechnik)

Credits (ECTS):6



Secr.:TIB 1‐B7


Brief description 1. Objectives Students will acquire deep theoretical and practical knowledge of special topics in geotechnical engineering. They will be able to design sophisticated foundation structures in consideration of complex constraints and in cooperation with planners and designers of various specialisations. They will learn to consider the interaction of foundation structures with other constructions and the environment. Expertise 60% Method skills 20% System skills 10% Social skills 10% 2. Content Special topics in foundation engineering and soil mechanics, proof of safety and serviceability of foundation structures under complex constraints and soil conditions, 3‐D earth pressure theories, elastic pad foundations, soil‐structure interaction. 3. Module elements Name Type SWS Credit



Spezielle Kapitel der Geotechnik

VL

2 3 P WiSe

Spezielle Kapitel der Geotechnik

UE 2 3 P WiSe


5. Examination Study effort equivalent to the examination (PS): Written report and oral discussion. 6. Duration The module can be accomplished in one semester. 7. Workload Attendance VL & UE 15 x 4= 60 h Preparation and post processing 80 h Preparation for discussion 40 h Total 180 h = 6 Credits 8. Maximum number of participants VL: n/a, UE: n/a

62

Geotechnical Seminar Name of the module: Geotechnical Seminar (Grundbauseminar)

Credits (ECTS):3



Secr.:TIB 1‐B7


Brief description 1. Objectives Students expand their knowledge and skills in reporting and presenting. They meet experienced engineers and get insight into the research activities of the department. Thus, they become able to discuss and evaluate complex coherencies in geotechnics, especially regarding current developments in practical applications and research. Expertise 30% Method skills 30% System skills 20% Social skills 20% 2. Content Advanced topics of soil mechanics, of foundation engineering and dynamics and of environmental geotechnics; lectures of national and international experts, either live or by video conference, presentations by PhD‐candidates, reports by students. 3. Module elements Name Type SWS Credit



Grundbauseminar SE

2 3 WP WiSe / SoSe


5. Examination Participation in seminar presentations is obligatory, personal presentation including a written conception will be evaluated. 6. Duration The module can be accomplished in one semester. 7. Workload Attendance 15 x 2= 30 h Preparation for report 1,5 week= 60 h Total 90 h = 6 Credits 8. Maximum number of participants SE: 12

63

Field of Expertise: Wasserwesen

Water Resources Management Name of the module: Water Resources Management (Wasserwirtschaft)

Credits (ECTS):6

Specialization module and basic module

Person in charge: Prof. Dr.‐Ing. R. Hinkelmann

Secr.:TIB 1‐B14

Email:reinhard.hinkelmann @wahyd. tu‐berlin.de

Brief description 1. Objectives The fundamentals of water resources management and different hydrological based modelling concepts are taught. The student shall obtain a solid and trendsetting education which prepares him for the planning tasks under consideration of the environment and the water resources. The lecture teaches: Professional Competence: 40% Methods competence: 20% System Competence: 30% Social Competence: 10% 2. Content statistical methods, river basin modelling, reservoir management, water quality, environmental sustainability, water resources planning, computer exercise with engineering relevant examples 3. Module elements Name Type SWS Credits Compulsory(P) /

Compulsory optional(W) optional(WP)


Water resources management

VL 2 3 P 7, WiSe

Water resources management

PR 2 3 P 7, WiSe

4. Entry requirements basics of fluid mechanics, hydrology, and hydro‐engineering

5. Examination oral examination 6. Duration semester 7. Workload Attendance 15 x 4h 60 h Preparation and post‐processing 15 x 4h 60 h Exam preparation 1.5 weeks 60 h Total : 180 h = 6 Credits 8.Maximum number of participants VL: n/a, PR: 10

64

Hydro‐ and Environmental Numerical Modeling I Name of the module: Hydro‐ and Environmental Numerical Modeling I (Hydrosystemmodellierung und Hydroinformatik I)

Credits (ECTS):6



Secr.:TIB 1‐B14


Brief description 1. Objectives Advanced fundamentals of hydromechanics and an inside in modern simulations methods and techniques of hydro‐ and environmental systems will be taught. Modelling systems are an essential requirement for planning and managing water and environmental issues. The student shall obtain a solid and trendsetting education which enables him to deal with numerical modeling systems and tools in the fields of hydro‐ and environmental sciences and engineering. The lecture teaches: Professional Competence: 30% Methods competence: 30% System Competence: 30% Social Competence: 10% 2. Content Physical foundation of flow‐ and transport processes in the subsurface and in free‐surface flow systems, modeling concepts, discretisations‐ and stabilisation methods (FDM, FEM, FVM, …), components of modeling systems, computer exercise with engineering relevant examples 3. Module elements Name Type SWS Credits Compulsory(P) /



Hydro‐ and Environmental Numerical Modeling I

VL 2 3 P 8, SoSe

Hydro‐ and Environmental Numerical Modeling I

PR 2 3 P 8, SoSe

4. Entry requirements Basics of fluid mechanics, hydrology, and hydro‐engineering 5. Examination oral examination 6. Duration 1 semester

65

7. Workload Attendance 15 x 4h 60 h Preparation and post‐processing 15 x 4h 60 h Exam preparation 1.5 week 60 h Total : 180 h = 6 Credits 8.Maximum number of participants VL: n/a, PR: 10

66

Hydro‐ and Environmental Numerical Modeling II Name of the module: Hydro‐ and Environmental Numerical Modeling II (Hydrosystemmodellierung und Hydroinformatik II)

Credits (ECTS):6

Specialization module


Secr.:TIB 1‐B14


Brief description 1. Objectives Methods and techniques dealing with special areas from the fields of modeling of hydro‐ and environmental systems and hydro‐informatics will be taught. The student shall obtain a solid and trendsetting education which enables him to deal with numerical modelling systems and tools in the fields of hydro‐ and environmental sciences and engineering. The lecture teaches: Professional Competence: 30% Methods competence: 30% System Competence: 30% Social Competence: 10% 2. Content A selection of the following special topics will be treated: large scale hydrological modelling, CFD in hydraulic engineering, multi‐phase‐flow in porous media, high performance computing, information modeling and management, special topics, computer exercise with engineering relevant examples 3. Module elements Name Type SWS Credits Compulsory(P) /



Hydro‐ and Environmental Numerical Simulation II

VL 2 3 P 9, WiSe

Hydro‐ and Environmental Numerical Simulation II

PR 2 3 P 9, WiSe

4. Entry requirements Hydro‐ and Environmental Numerical Simulation I

5. Examination oral examination 6. Duration 1 semester

67

7. Workload Attendance 15 x 4h 60 h Preparation and post‐processing 15 x 4h 60 h Exam preparation 1.5 weeks 60 h Total : 180h = 6 Credits 8.Maximum number of participants VL: n/a, PR: 10

68

Colloquium Hydro‐Engineering Name of the module: Colloquium Hydro‐Engineering (Kolloquium Wasserwesen)

Credits (ECTS):6

Vertiefungsmodul MSc


Secr.:TIB 1‐B14


Brief description 1. Objectives On the one hand the student will learn about special fields of hydro‐engineering, on the other hand he will learn to use modern presentation techniques. The lecture teaches: Professional Competence: 30% Methods competence: 30% System Competence: 20% Social Competence: 20% 2. Content Selected topics from the field of hydo‐ and environmental engineering, presentations from national and international experts, presentations of doctoral students 3. Module elements Name Type SWS Credits Compulsory(P) /



Seminar SE 2 3 P 7, WiSe Seminar SE 2 3 P 8, SoSe 4. Entry requirements fluid mechanics, hydro‐engineering I, preferable hydro‐engineering II

5. Examination Attendance at the seminar is required as well an own presentation and a written concept which will be evaluated. 6. Duration semester 7. Workload Attendance 15 x 2h x 2 Sem. 60 h Development of the presentations 2 x 1.5 weeks 120 h Total : 180 h = 6 Credits 8.Maximum number of participants SE: 10

69

Urban Water Management Name of the module: Urban Water Management (Siedlungswasserwirtschaft)

Credits (ECTS):6


Person in charge: Prof. Dr.‐Ing. M. Barjenbruch

Secr.:TIB 1 B‐16

Email:matthias.barjenbruch@tu‐berlin.de

Brief description 1. Objectives Graduates shall be enabled to generally understand water supply and waste water systems and to be able to economically and ecologically plan and calculate the most important plant parts. The basic calculation methods will be teached and trained so that graduates are able to stay up to date with changes and rules of these methods on their own afterwards. This course imparts: professional competence 60%, methods competence 20%, system competence 20%, social competence 0% 2. Content Planning and calculating of plants and methods of water supply and wastewater treatment. Water supply will cover water and groundwater pollution control, water exploitation and catchment, water processing, transportation and storage as well as water allocation in small towns. The waste water part will include the design and calculation of sewer systems and their buildings as well as wastewater treatment, rainwater treatment and sewage sludge treatment. These topics will be completed with corresponding methods of town planning and water management. The exercise part of this course will cover practical calculation examples, e.g. the calculation of mutiple well systems, waterworks (softening, deacidification, iron removal, decontamination, filter plants), pumping installation, detention tanks, pipeline networks, sewage water systems, biological und advanced wastewater treatment, rainwater treatment plants (tank, stormwater with overflow, stormwater holding tanks) and sludge treatment plants. In the laboratory substances of water, waste water and waterbodes will be determined that are relevant to evaluate the quality of natural water, drinking water, waste water and water body conditions. The determination of these parameters is the precondition for selecting and controlling treatment and cleaning methods as well as internal and external plant controls. 3. Module elements Name Type SWS Credit



Urban Water Management

IV 2 3 P 7., WiSe

Laboratory

PR 2 3 P 7., WiSe

4. Entry requirements Water‐Engineering I and II

5. Workload Attendance 15 x 4= 60 h Preparation and postprocessing 15 x 4= 60 h Exma preparation 1,5 weeks= 60 h Total 180 h = 6 Credits

70

6. Examination oral examination 7. Duration 1 semester 8. Maximum number of participants VL: n/a, PR: 10

71

Urban Water Management‐ Water supply Name of the module: Urban Water Management‐ Water supply (Siedlungswasserwirtschaft‐ Wasserversorgung)

Credits (ECTS):6



Secr.:TIB 1 B‐16


Brief description 1. Objectives Graduates shall be enabled to grap and evaluate all functions of water supply systems. The essential methods will be coped and graduates shall be able to plan, dimension and operate common facilities under the current technical rules. Initial principles will be covered as far as to enable an independent incorporation into particular cases and to be able to work in research and development. This course imparts: professional competence 60%, methods competence 20%, system competence 20%, social competence 0% 2. Content Special water supply methods During this course we will deal with water supply methods and facilities, amongst others: legal basics (drinking water ordinance), forms of organisations, pipe material, corrosion, fittings, wells regeneration, drinking water emergency supply, conditioning (subsurface de‐ironing, nitrates, absorption, bathwater), desalination of seawater, drinking water substitution, water quality (flowing waters, lake restoration) Exercises (water) This course will cover concrete examples to assess and dimension plants partly parallel with theoretical introductions. Range of topics are e.g. inter‐stationary yieldings (shock pressure calculation), pipeline network calculations under different circumstances, economical nominal diameters, water treatment plants (e.g. charcoal absorber) 3. Recommended literature, lecture notesHard and soft copies of lecture notes are available. Details of recommended literature will be given in the lecture.




special water supply methods

VL

2 3 P 8, SoSe

Exercises (water)

UE 2 3 P 8, SoSe


6. Workload

72

Attendance 15 x 4= 60 h Preparation and postprocessing 15 x 4= 60 h Preparation for written test 1,5 weeks= 60 h Total 180 h = 6 Credits 7. Examination oral examination 8. Duration 1 semester 9. Maximum number of participants VL: n/a, UE: 45, TUT: 15

73

Urban Water Management‐ Modern sanitary systems Name of the module: Urban Water Management‐ Modern sanitary systems (Siedlungswasserwirtschaft‐ Moderne Sanitärsysteme)

Credits (ECTS):3



Secr.:TIB 1 B‐16


Brief description 1. Objectives Graduates shall be able to economically and ecologically plan, calculate and dimension water supply and wastewater treatment systems under special and extreme conditions. Forward‐looking technologies and systems will be teached, trained and discussed so that graduates are able to refine them and to put them across after their studies. This course imparts: professional competence 40%, methods competence 30%, system competence 10%, social competence 20% 2. Content Decentralised sewage disposal, customized water supply and wastewater treatment technologies in developing and emerging countries, cycle of materials in urban water management, urine separation, faecal composting and fermentation, system examination




Modern sanitary systems IV 2 3 P 7., WiSe

4. Entry requirements Water‐Engineering I and II, Urban Water Management

5. Workload Attendance 15 x 2= 30 h Preparation and postprocessing 15 x 2= 30 h Exma preparation 1,5 weeks= 30 h Total 90 h = 3 Credits 6. Examination oral examination 7. Duration 1 semester

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Urban Water Management‐ Wastewater Treatment Name of the module: Urban Water Management‐ Wastewater Treatment (Siedlungswasserwirtschaft‐ Abwassertechnik)

Credits (ECTS):6



Secr.:TIB 1 B‐16


Brief description 1. Objectives Graduates shall be enabled to understand and to assess all functions of wastewater treatment systems. The essential methods will be coped and graduates shall be able to plan, dimension and operate common facilities under the current technical rules. Initial principles will be covered as far as to enable an independent incorporation into particular cases and to be able to work in research and development. This course imparts: professional competence 60%, methods competence 20%, system competence 20%, social competence 0% 2. Content Design, construction, building and operation of urban water management plants This course will cover methods and plants focussing on wastewater technology, et al. integrative management, controlling and monitoring of sewerage systems, special building, building methods, nitrification, denitrification, biological phosphorus elimination, filtration, micro sieving, flocculation, industrial wastewater, anaerobic techniques, adsorption, disinfection, reverse osmose, wastewater treatment in rural areas, grey water and alternatives, conserving drinking water, rainwater usage. Exercises (wastewater) This course will cover numerical examples of wastewater treatment methods and plants. Range of topics are e.g. wastewater filtration, small scale sewage treatment plants, wastewater lagoons, wastewater hydraulics, alternative methods for sewerage calculation, sewerage statics, surface water infiltration, introduction into urban water management software. 3. Module elements Name Type SWS Credit



Design, construction, building and operation of urban water management plants

VL 2 3 P 8., SoSe

Exercises (wastewater)

UE 2 3 P 8., SoSe


75

5. Workload Attendance 15 x 4= 60 h Preparation and postprocessing 15 x 4= 60 h Exma preparation 1,5 weeks= 60 h Total 180 h = 6 Credits 6. Examination oral examination 7. Duration 1 semester

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Field of Expertise: Management

Life cycle I – Project development Name of the module: Life cycle I – Project development (Lebenszyklus I ‐ Projektentwicklung)

Credits (ECTS):6

Abbreviation:

Person in charge: Prof. Dr.‐Ing. B. Kochendörfer

Secr.:TIB 1‐B6

Email:kochendoerfer@ baubetrieb.tu‐berlin.de

Brief description 1. Objectives In this module the students acquire knowledge on the development of structural engineering projects. With this techniques and approaches are meant which contain the phase before the real planning phase i.e. from the first project conception up to the preliminary planning. In this phase it is decided whether a project conception should be realized or not. The course conveys: Professional Competence 40% Methods Competence 20% System Competence 20% Soft Skills 20% 2. Content Property market Participants in the property sector Legal basis of the project development Project determining factors Tools and methods of project development Principles for building that creates value Practical examples 3. Recommended literature, lecture notesN/A




Project development VL

2 2 W WiSe

Project development Seminar

2 4 W WiSe

77

5. Entry requirements N/A 6. Workload Attendance LV 15 x 2= 30 h Preparation and postprocessing 15 x 1= 15 h Preparation for oral test 90 h = 90 h Attendance seminar 15 x 2= 30 h Elaboration of documents and 90 h= 90 h Final presentation Total 185 h = 6 Credits 7. Examination An oral examination of 20 minutes by the end of the module on the contents of project development (weighting 50%) and a seminar presentation on a selected theme (weighting 50%). 8. Duration 1 semester

78

Life cycle II – Project Management Name of the module: Life cycle II – Project Management (Lebenszyklus II ‐ Projektmanagement)

Credits (ECTS):6

Abbreviation:


Secr.:TIB 1‐B6


Brief description 1. Objectives In this module the students acquire knowledge on the realization of building projects from the principal’s and investor’s (to which building companies also belong to) point of view. Knowledge on managerial functions, managerial organization, managerial techniques and managerial instruments for the execution of building projects against the background of the property life cycle will be conveyed. The course conveys: Professional Competence 40% Methods Competence 20% System Competence 20% Soft Skills 20% 2. Content Services in the Project Management Project organization Scheduling Cost Management Quality Management from the principal’s point of view Project phases and operation fields Tools in the Project Management Practical examples 3. Recommended literature, lecture notesN/A




Project Management VL

2 3 W SoSe

Project Management UE 2 3 W SoSe

5. Entry requirements N/A 6. Workload Attendance IV 15 x 4= 60 h Preparation and postprocessing 15 x 4= 60 h Preparation for oral test 60 h = 60 h Total 180 h = 6 Credits 7. Examination An oral test by the end of the module on the contents of Project Management 8. Duration 1 semester

79

Life cycle III – Property Management Name of the module: Life cycle III – Property Management (Lebenszyklus III – Gebäudemanagement)

Credits (ECTS):6

Abbreviation:


Secr.:TIB 1‐B6

Email:Kochendoerfer@ baubetrieb.tu‐berlin.de

Brief description 1. Objectives In this module the students acquire knowledge on management services for the operating stage of structural engineering objects. As the costs of this operating stage may amount the fivefold of the investment costs, these management services are very important. The course conveys: Professional Competence 40% Methods Competence 20% System Competence 20% Soft Skills 20% 2. Content Differentiation to Facility Management Technical services Space Management Costs and services accounting Maintenance Building logistics Supply and Return Management 3. Recommended literature, lecture notesN/A 4. Module elements Name Type SWS Credit



Property Management VL

2 2 W WiSe

Property Management Seminar

2 4 W WiSe

5. Entry requirements N/A

6. Workload Attendance VL 15 x 2= 30 h Preparation and postprocessing 15 x 1= 15 h Preparation for oral test 20 h = 20 h Attendance seminar 15 x 2= 30 h Elaboration of documents and 90 h= 90 h final presentation Total 185 h = 6 Credits 7. Examination An oral examination of 20 minutes by the end of the module on the contents of project development (weighting 50%) and a seminar presentation on a selected theme (weighting 50%). 8. Duration 1 semester

80

Project development in application Name of the module: Project development in application (Projektentwicklung in der Anwendung)

Credits (ECTS):6

Abbreviation:


Secr.:TIB 1‐B6


Brief description 1. Objectives In this module the students consolidate their knowledge in the field Project development and Project Management. By means of a real project the several steps of project development in teamwork will be learned. The course conveys: Professional Competence 20% Methods Competence 20% System Competence 10% Soft Skills 50% 2. Content Market analysis Location study Investment analysis Financing Building law Planning 3. Recommended literature, lecture notesN/A




Project development in application

VL

2 6 W Ws or SoSe

5. Entry requirements Successful attendance on the modules Project Development or Project Management

6. Workload Attendance 15 x 2= 30 h Project work 110h= 110 h Preparation for presentation 40 h = 40 h Total 180 h = 6 Credits 7. Examination One intermediate presentation (weighting 25%) and one final presentation (weighting 75%) 8. Duration 1 semester

81

Management Name of the module: Management (Unternehmensführung)

Credits (ECTS):12

Abbreviation:


Secr.:TIB 1‐B6


Brief description 1. Objectives In this model the students acquire knowledge on the management of a building company on strategic and operational level. In the required subject basics are conveyed. Through the compulsory optional subject catalogue the students may then set an individual course, which may procure them competitive advantages in their later field of activity. The course conveys: Professional Competence 40% Methods Competence 20% System Competence 20% Soft Skills 20% 2. Content Operational company management Cost and services accounting Amount of coverage accounting Investment accounting Controlling Quality Management Risk Management Contract Management Errors in tender documents Amendments in calculation basics Calculation of special items Amended and additional services in building contracts Disturbed building processes Denunciation of contracts and their consequences Public Private Partnership Life cycle reflection Public Private Partnerships Structural engineering and infrastructure Profitability comparison PPP financing Operating model Risks allocation Strategic company management International Markets Competition factors Human Resources Corporate Governance Marketing Approaches of strategic management (ABC‐analysis, SWOT‐analysis, Balanced Scorecard, etc.)

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Financing and Balancing Object‐related financing Financial risk coverage Finance and solvency planning Building account frames Unfinished buildings in the annual accounts Balancing of consortiums 3. Recommended literature, lecture notes




Operational Management VL

2 2 P SoSe

Seminar Management Seminar

2 4 P SoSe

Contract Management IV 2 3 W SoSe

Operational Mangement IV 2 3 W SoSe

Public Private Partnership IV 2 3 W SoSe

Financing and Balancing IV 2 3 W SoSe


6. Workload Attendance VL 15 x 2= 30 h Preparation and postprocessing 15 x 1= 15 h Attendance elective subject 2 x 2 x 15= 60 h Preparation and postprocessing 2 x 2 x 15= 60 h Preparation for oral test 80 h = 80 h Attendance seminar 15 x 2= 30 h Elaboration of documents 85 h= 85 h and final presentation Total 360 h = 12 Credits 7. Examination An oral examination of 30 minutes by the end of the module on the contents of the chosen subjects (weighting 50%) and a seminar presentation on a selected theme (weighting 50%). 8. Duration 2 semester

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Field of Expertise: Infrastruktur English descriptions will follow. Meanwhile, please use the german descriptions. Therefore, please visit the following homepage: http://www.bau.tu‐

berlin.de/uploads/media/030909_Studienf_hrer_Bauingenieurwesen__MSc__2009‐2010_Anhang.pdf

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