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Lecturer(s)
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Macho Martin, Ing. Ph.D.
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Bureš Vladislav, Ing. Ph.D.
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Course content
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Lectures: 1. Steel structures - halls 2. Steel Structures - large span halls 3. Steel structures - multi-storey buildings 4. Steel structures - tall buildings 5. Steel structures - steel and steel-concrete bridges, footbridges 6. Steel structures - industrial and architectural structures 7. Timber structures - introduction, history of timber structures, properties of timber, timber and timber-based products 8. Timber structures - design principles of timber structures, limit states, basic stresses (tension, compression, bending, shear) 9. Timber structures - joints in timber structures, protection against deterioration and fire 10. Timber structures - planar and solid timber structures, multi-storey buildings, halls 11. Timber structures - history, trusses, ceilings, reinforcement 12. timber structures - bridges, footbridges and architectural structures. Practical session: The first half of the semester is devoted to the simplified design of load-bearing structure of steel hall. Students will make load analysis, simplified design of the roof shell and thin-walled truss. This is followed by the creation of a simplified numerical model of the hall cross bracing in a computer program and the design and assessment of the members of the truss girder and column. The task is completed by preparing basic drawings of the proposed structure. In the second half of the semester, students are introduced in more detail to the design and assessment procedures for basic timber structural elements. As part of the homework, students experience the design and assessment of a timber floor beam and the design and assessment of a timber column. Structural elements are assessed for ultimate and serviceability limit state.
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Learning activities and teaching methods
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Monological explanation (lecture, presentation,briefing), Dialogue metods(conversation,discussion,brainstorming)
- Class attendance
- 42 hours per semester
- Preparation for exam
- 42 hours per semester
- Preparation for credit
- 10 hours per semester
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Learning outcomes
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The course deals with the complex design of steel multi-storey building skeletons and steel single-storey halls. Special features in the design of tall buildings, including the effects of earthquakes. Roofing of large span halls, large span structures - stadiums, hangars etc., prestressed cable structures, pneumatic structures, shells. Steel and steel-concrete bridges and footbridges, bridge and footbridge loads and design specifics. Principles of design of masts, towers, process structures, tanks and reservoirs. Examples of completed steel structures. Complementary structures, in particular facades, glazing and thermal insulation of the envelope. The second part of the course focuses on timber structures. The history of the use of timber and an overview of the use of timber structures in construction. Properties of wood and wood-based materials. Reliability of the design of timber structures, limit state design, applicable standards. Design of sections for individual stresses and their combinations. Connections and joints of timber structures. Protection of timber structures against fire and biological corrosion. Basic load-bearing systems, multi-storey buildings and halls. Design of timber structures for the effects of fire. Timber trusses, their historical development, design of trusses and their modification. Timber bridges, footbridges, towers and architectural structures. Examples of completed timber buildings.
The students will deepen their knowledge of steel structures, especially in the field of storey buildings and hall buildings. The student will also gain an overview of the properties, advantages and possibilities of using wood for building structures. The student will also learn the principles of design of timber structures and be able to carry out basic design of timber structural elements.
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Prerequisites
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Initial knowledge: the basics of structural analysis in the scope of the curriculum for the 2nd year
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Assessment methods and criteria
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Oral exam, Written exam
Initial knowledge: the basics of structural analysis in the scope of the curriculum for the 2nd year Credit: - participation in lectures and exercises at least 75% - elaboration of the given examples Examination: an examination concerning the curriculum covered in the lectures
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Recommended literature
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Eliášová, M., Sokol, Z. Ocelové konstrukce 1. Příklady. ČVUT, Praha, 2014.
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Faltus, F. Prvky ocelových konstrukcí, Ocelové konstrukce pozemních staveb, Mosty trámové a obloukové, Mosty visuté a zavěšené. SNTL Praha, 1963.
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Kohout, J., Tobek, A. Tesařství. Grada Publishing Praha, 1966.
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Kolektiv autorů ČVUT. Zásady navrhování podle Eurokódu 3. ČVUT Praha, 1994.
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Kuklík, P. Příručka 1 (HANDBOOK 1). Dřevěné konstrukce. 2008.
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Kuklík, P. Příručka 2 (HANDBOOK 2). Navrhování dřevěných konstrukcí podle Eurokódu 5. 2008.
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Kuklík, P., Studnička, J. Dřevěné a kovové konstrukce. Informatorium Praha, 2006.
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Macho, M. Podklady ke cvičení z předmětu Kovové a dřevěné konstrukce 2.
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Macho, M. Přednášky k předmětu Kovové a dřevěné konstrukce 2.
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Rotter, T., Studnička, J. Ocelové konstrukce 30. Ocelové mosty. ČVUT, Praha, 2001.
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Skrbek, A. Dřevěné konstrukce krovů velkých rozpětí. B. Pyšvejc Praha, 1948.
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Sokol, Z., Wald, F. Ocelové konstrukce. Tabulky. ČVUT, Praha, 2016.
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Studnička, J., Holický, M., Marková, J. Ocelové konstrukce 2. Zatížení. ČVUT, Praha, 2015.
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Studnička, J. Navrhování nosných konstrukcí. Ocelové konstrukce. ČVUT, Praha, 2017.
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Studnička, J. Ocelobetonové spřažené konstrukce. ČVUT, Praha, 2009.
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Studnička, J. Ocelové konstrukce. Normy. ČVUT, Praha, 2016.
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Štefko, J., Reinprecht, L. Dřevěné stavby. JAGA Bratislava, 2004.
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