| Course Unit Code | 030-0107/01 |
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| Number of ECTS Credits Allocated | 4 ECTS credits |
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| Type of Course Unit * | Choice-compulsory type B |
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| Level of Course Unit * | Second Cycle |
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| Year of Study * | First Year |
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| Semester when the Course Unit is delivered | Summer Semester |
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| Mode of Delivery | Face-to-face |
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| Language of Instruction | Czech |
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| Prerequisites and Co-Requisites | Course succeeds to compulsory courses of previous semester |
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| Name of Lecturer(s) | Personal ID | Name |
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| MYN03 | Ing. Miroslav Mynarz, Ph.D. |
| Summary |
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| The course is focuses on assessment of reinforced concrete, steel and timber structures according to Eurocodes with orientation on the ultimate limit state and to introduce students with professional software for design structures. |
| Learning Outcomes of the Course Unit |
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| The course focuses on the evaluation of building structures according to Eurocodes standards on the ultimate limit state. The purpose of this course is to introduce students with the problems of loading, design and dimensioning of load-bearing structures. Students learn the principles of the theory and design a comprehensive and consistent information about problems of design of reinforced concrete, steel and timber structures. In this course the student also has the opportunity to acquire basic skills at work with professional software applications used in computer modeling of building structures. |
| Course Contents |
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1. Loads and environmental influences on buildings. Load application idealization standards. Load characteristic values. Loads deads,
variable (utility). Modeling of static load effects. Combination of effects
static load. Local Load Effects (Particular) and Global (on the structure as a whole).
2. Load variable (wind, snow), accidental- informative. Effect modeling
static load. Dynamic loads - principles (informative).
3. The nature, use and history of concrete, the basics of reliability theory and limit states. Physical and mechanical properties of concrete, working diagrams
the interaction of concrete and reinforcement.
4. Dimensioning of bent elements. Plate, beam.
5. Structural principles of reinforcement of bent and mostly pressed elements.
6. Interaction diagram. Elements stressed by eccentric pressure with small and large eccentricity, buckling effect.
7. Advantages and disadvantages of steel structures. Application of steel structures in construction. Physical and mechanical properties of steels. Technological properties steel. Types of steels in construction. Assortment of rod and surface elements. Fundamentals of Design and Theory of Reliability of Steel Structures.
8. Classification of steel structures. tensioned and pressed steel elements
structures. Buckling theory.
9. Design and evaluation of slender sections. Bending elements.
10. Joints of steel structures - weld, screw, friction.
11. Advantages and disadvantages of timber structures. Application of timber structures in construction. Physical and mechanical properties of wood and materials based on wood.
12. Tensioned and pressed elements of timber structures.
13. Bending elements and bending combination with axial thrust or pressure.
14. Consultation and completion of semester project. |
| Recommended or Required Reading |
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| Required Reading: |
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Handbook 1 - Basis of structural design. Leonardo da Vinci Pilot Project CZ/02/B/F/PP-134007, Prague, 2004.
Handbook 3 – Actions effects for buildings. Leonardo da Vinci Pilot Project CZ/02/B/F/PP-134007, Prague, 2005.
Martin, L. H., Purkiss, J.A. Concrete Design to EN 1992, Elsevier, 2006.
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Studnička, J., Holický, M.: Ocelové konstrukce 20 - Zatížení staveb, ČVUT
Praha, 1998
Procházka, J., Bradáč, J. a kol.: Betonové konstrukce - Příklady navrhování
podle Eurocode 2, Procon Praha, 1997
Bradáč, J.: Betonové konstrukce 1. část: Dimenzování prvků betonových
konstrukcí, VŠB Ostrava, 1997
Studnička, J., Macháček J.: Ocelové konstrukce 20, ČVUT Praha, 2002
Wald, F.: Prvky ocelových konstrukcí - příklady podle Eurokódů, ČVUT Praha, 2000
Studnička, J., Medřický, V.: Ocelové a dřevěné konstrukce 10, ČVUT Praha, 2001
Kuklík, P., Kuklíková, A.: Dřevěné konstrukce 1, ČVUT Praha, 1999
Handbook 1 - Basis of structural design. Leonardo da Vinci Pilot Project CZ/02/B/F/PP-134007, Prague, 2004.
Handbook 3 – Actions effects for buildings. Leonardo da Vinci Pilot Project CZ/02/B/F/PP-134007, Prague, 2005.
Martin, L. H., Purkiss, J.A. Concrete Design to EN 1992, Elsevier, 2006. |
| Recommended Reading: |
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Ambrose, J. E.: Simplified Design of Masonry Structures. John Wiley & Sons, Inc., 1991
Silva, L.S. et al.: Design of steel structures, 2010 ISBN (ECCS) 978-92-9147-098-3, ISBN (Ernst & Sohn) 978-3-433-02973-2.
|
Tichý, M.: Zatížení stavebních konstrukcí, SNTL Praha, 1987
Procházka, J., Krátký, J.: Navrhování betonových konstrukcí podle Eurocode 2,
Studnička, J.: Ocelové konstrukce I, ČVUT Praha, 1998ČVUT Praha, 1995
Kuklík, P., Kuklíková, A.: Dřevěné konstrukce 10 - příklady navrhování, ČVUT
Praha, 2000 |
| Planned learning activities and teaching methods |
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| Lectures, Tutorials |
| Assesment methods and criteria |
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| Task Title | Task Type | Maximum Number of Points
(Act. for Subtasks) | Minimum Number of Points for Task Passing |
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| Credit and Examination | Credit and Examination | 100 (100) | 51 |
| Credit | Credit | 40 | 15 |
| Examination | Examination | 60 | 11 |