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Module code: BIBA356 |
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6VU (6 hours per week) |
6 |
Semester: 3 |
Mandatory course: yes |
Language of instruction:
German |
Assessment:
Written exam
[updated 28.09.2020]
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BIBA356 (P110-0046) Civil and structural engineering, Bachelor, ASPO 01.10.2011
, semester 3, mandatory course
BIBA356 (P110-0046) Civil and structural engineering, Bachelor, ASPO 01.10.2017
, semester 3, mandatory course
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90 class hours (= 67.5 clock hours) over a 15-week period. The total student study time is 180 hours (equivalent to 6 ECTS credits). There are therefore 112.5 hours available for class preparation and follow-up work and exam preparation.
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Recommended prerequisites (modules):
BIBA160 Study Project I BIBA250-17 Engineering Mechanics II
[updated 19.10.2022]
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Recommended as prerequisite for:
BIBA435-17 Building Mechanics and Structural Analysis II BIBA450-17 Project: Building Industry II BIBA671-17 Building Mechanics and Structural Analysis III BIBA770-17 Wood Engineering and Construction II
[updated 19.10.2022]
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Module coordinator:
Prof. Dr.-Ing. Gudrun Djouahra |
Lecturer: Prof. Dr.-Ing. Gudrun Djouahra Prof. Dr. Markus Enders-Comberg Prof. Dr.-Ing. Christian Lang
[updated 19.10.2022]
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Learning outcomes:
Concrete I: After successfull completing this module, students will understanding the load bearing behavior of reinforced concrete components (reinforced concrete principle). - They will have material-specific knowledge about concrete and steel and their significance for architectural design. - Application of actions and safety concepts in reinforced concrete construction. - Students will be able to create and understand drawings showing survey (control) points in reinforced concrete construction. - Bending design for simple reinforced concrete components Structural Design I: - Advanced knowledge about and dealing with internal forces of simple static systems - Students will be familiar with the concept of deformations and their importance in simple static systems. - They will receive an introduction into the calculation of statically indeterminate systems. - They will be familiar with computer programs for solving simple problems. Wood Engineering and Construction I: - Students will acquire knowledge about the specific behaviour of wood as a material. - They will learn to work with stability and usability checks. - They will be able to design and construct simple timber structures. - They will be able to design and dimension timber joints. - They will be able to gather and apply subject-related content independently.
[updated 28.09.2020]
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Module content:
Concrete I: _ Building materials and their characteristics (concrete and steel), durability _ Actions, safety and verification concept _ Specifications for the static system, drawing showing survey (control) points, design internal forces _ Bending design of rectangular cross sections Structural Design I: _ Unit deformations, derivation of the bending line, working theorem, principle of virtual forces, deformation calculations on statically determinate systems, calculation of statically indeterminate systems _ Continuous beams according to tables and the theorem of three moments, _ Trusses _ analytical and graphic solutions Wood Engineering and Construction I: _ Introduction: Timber as a material and its specific characteristics _ Basic principles and design: Actions and combinations, stresses and capacity to withstand stresses, stability checks and usability checks _ Simple timber structures: bending beams, tension rods, compression rods _ Wood joining technology: Verification for all common timber connectors, construction and connections
[updated 28.09.2020]
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Teaching methods/Media:
Betonbau I / Baustatik I: Lehrformat: SLK-Konzept _ Selbstlernkompetenz im Grundstudium
[updated 28.09.2020]
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Recommended or required reading:
Concrete I: _ Djouahra, G.: Massivbau I; lecture notes, _ Wommelsdorff, O.: Stahlbetonbau: Bemessung und Konstruktion, Teil 1, Werner Verlag _ Goris, A.: Stahlbetonbau-Praxis nach Eurocode 2, Band 1, Bauwerk Beuth Verlag Structural Design I: _ Schneider: Bautabellen für Ingenieure, Werner-Verlag _ Wagner/Erlhof: Praktische Baustatik 3 _ Schneider, Schmidt-Gönner: Baustatik-Zahlenbeispiel Wood Engineering and Construction I: _ Lecture notes (passed out at the beginning of the semester) _ Colling, F.: Holzbau, Grundlagen, Bemessungshilfen _ Steck, G., Nebgen, N.: Holzbau kompakt
[updated 28.09.2020]
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