Course detail
Computing calculation of concrete structures
FAST-CL54Acad. year: 2014/2015
Software for solution of framed and flat structures. Training programme data for solution of engineering problems. Individual work of a student on computer under the lecturer’s leading.
Modelling structures individually formulated. Modelling framed and flat concrete structures. Formulation of input data and evaluation of the results using computer or graphic method. Dimensioning cross-sections on computer.
Time-dependent analysis of concrete structures. Modelling geometric and physical non-linearity.
Language of instruction
Czech
Number of ECTS credits
5
Mode of study
Not applicable.
Guarantor
Department
Institute of Concrete and Masonry Structures (BZK)
Learning outcomes of the course unit
A student gains these knowledge and skills:
Virtue to utilise computing systems for concrete structures design.
Virtue for desinging individual structural reinforced concrete or prestressed member.
Virtue for modeling and to dimensioning flat and framed structures using computing technology.
Virtue to apply time-dependent analysis in design of structures.
Virtue to apply geometric and physical non-linearity in design of structures.
Virtue to utilise computing systems for concrete structures design.
Virtue for desinging individual structural reinforced concrete or prestressed member.
Virtue for modeling and to dimensioning flat and framed structures using computing technology.
Virtue to apply time-dependent analysis in design of structures.
Virtue to apply geometric and physical non-linearity in design of structures.
Prerequisites
stresses, software for structural design, structural models, dimensioning of concrete members and structures
Co-requisites
do not required
Planned learning activities and teaching methods
Teaching methods depend on the type of course unit as specified in the article 7 of BUT Rules for Studies and Examinations. Education runs in the forms of lectures and trainings. Character of the lectures is based on definition of basic principles, problems and methodology. In the trainings the main subject matters are trained on individually defined projects (examples).
Assesment methods and criteria linked to learning outcomes
To gain the credit, the students should elaborate individually defined design and calculate specified task. The students are obliged to consult the design continuously in the given terms and submit it to the fixed date. The presences in training lessons are checked. An exam consists both of the written part, in which the task is elaborated, and the theoretical part. To pass the exam successfully, both parts should be accomplished.
Course curriculum
1. Modelling of framed concrete structures. Preparation of model geometry. Cross-sectional changes: change of central line. Rigidity. Modelling of loads. Supporting elements of plane and spatial model.
2. Calculation. Post-processing. Visualisation and evaluation of calculation results.
3. Computational dimensioning of framed concrete structures.
4. Application of time-dependent analysis for framed structures.
5. Modelling of geometric and physical non-linearity of framed structures.
6. Modelling of flat concrete structures. Slab rigidity. Effects of reinforcement. Loads.
7. Modelling of flat concrete structures on subsoil. Computational dimensioning of concrete slab structures.
8. Modelling of geometric and physical non-linearity of slab structures.
2. Calculation. Post-processing. Visualisation and evaluation of calculation results.
3. Computational dimensioning of framed concrete structures.
4. Application of time-dependent analysis for framed structures.
5. Modelling of geometric and physical non-linearity of framed structures.
6. Modelling of flat concrete structures. Slab rigidity. Effects of reinforcement. Loads.
7. Modelling of flat concrete structures on subsoil. Computational dimensioning of concrete slab structures.
8. Modelling of geometric and physical non-linearity of slab structures.
Work placements
Not applicable.
Aims
To learn to utilise selected software for design of concrete structures.
To model and to dimension flat and framed structures using computing technology.
To apply a time analysis and geometric and physical non-linearity in design.
To model and to dimension flat and framed structures using computing technology.
To apply a time analysis and geometric and physical non-linearity in design.
Specification of controlled education, way of implementation and compensation for absences
Extent and forms are specified by guarantor’s regulation updated for every academic year.
Recommended optional programme components
Not applicable.
Prerequisites and corequisites
Not applicable.
Basic literature
KOLÁŘ, Vladimír, NĚMEC, Ivan a KANICKÝ, Viktor: FEM - Principy a praxe metody konečných prvků. Praha: Computer Press, 1997. ISBN 8072260219. (CS)
ONDRÁČEK, Emanuel a JANÍČEK, Přemysl: Výpočtové modely v technické praxi. Praha: SNTL, 1990. ISBN 80-03-00458-6. (CS)
ZIENKIEWICZ, O. a TAYLOR, R.: The finite element method for solid and structural mechanics. Elsevier Butterworth-Heinemann, 2005. ISBN 978-0-7506-6321-2. (EN)
ONDRÁČEK, Emanuel a JANÍČEK, Přemysl: Výpočtové modely v technické praxi. Praha: SNTL, 1990. ISBN 80-03-00458-6. (CS)
ZIENKIEWICZ, O. a TAYLOR, R.: The finite element method for solid and structural mechanics. Elsevier Butterworth-Heinemann, 2005. ISBN 978-0-7506-6321-2. (EN)
Recommended reading
Kolektiv autorů: Scia Engineer 2012 Manuals. Nemetschek Scia, 2012. [http://nemetschek-scia.com/cs/support/downloads] (EN)
Classification of course in study plans
Type of course unit
Lecture
26 hod., optionally
Teacher / Lecturer
Syllabus
1. Modelling of framed concrete structures. Preparation of model geometry. Cross-sectional changes: change of central line. Rigidity. Modelling of loads. Supporting elements of plane and spatial model.
2. Calculation. Post-processing. Visualisation and evaluation of calculation results.
3. Computational dimensioning of framed concrete structures.
4. Application of time-dependent analysis for framed structures.
5. Modelling of geometric and physical non-linearity of framed structures.
6. Modelling of flat concrete structures. Slab rigidity. Effects of reinforcement. Loads.
7. Modelling of flat concrete structures on subsoil. Computational dimensioning of concrete slab structures.
8. Modelling of geometric and physical non-linearity of slab structures.
2. Calculation. Post-processing. Visualisation and evaluation of calculation results.
3. Computational dimensioning of framed concrete structures.
4. Application of time-dependent analysis for framed structures.
5. Modelling of geometric and physical non-linearity of framed structures.
6. Modelling of flat concrete structures. Slab rigidity. Effects of reinforcement. Loads.
7. Modelling of flat concrete structures on subsoil. Computational dimensioning of concrete slab structures.
8. Modelling of geometric and physical non-linearity of slab structures.
Exercise
26 hod., compulsory
Teacher / Lecturer
Syllabus
1. Pre-prestressed roof truss: bar model, cross-section, enlarging cross-section, design of prestressing force with the help of equivalent load.
2. Application of modulus of pre-prestressed cable.
3. Progressive construction – time-dependent analyse TDA, short-terms and long-terms losses of prestressing.
4. Slab structure: Slab model with different types of supports, modelling of ribs and bars on the eccentricity.
5. Check of calculation, combination, dimensioning, determination of minimum reinforcement area.
6. Calculation of non-linear deflection influenced by the cracks, reinforcement and creep.
7. Reinforcing: Utilisation of programme RECOC.
8. Project submission. Credit.
2. Application of modulus of pre-prestressed cable.
3. Progressive construction – time-dependent analyse TDA, short-terms and long-terms losses of prestressing.
4. Slab structure: Slab model with different types of supports, modelling of ribs and bars on the eccentricity.
5. Check of calculation, combination, dimensioning, determination of minimum reinforcement area.
6. Calculation of non-linear deflection influenced by the cracks, reinforcement and creep.
7. Reinforcing: Utilisation of programme RECOC.
8. Project submission. Credit.