Course detail
Members of concrete structures
FAST-BL01Acad. year: 2014/2015
Fundamental principles of concrete members. Structural characteristic of concrete and influencing factors. Concrete reinforcement and its bond with concrete.
Basic principles of design. Design condition of structural materials and the structure itself. Concrete structures durability.
Desing of reinforced concrete members stressed by of bending moment and shear force - ultimate and serviceability limit states, structural principles.
Simple concrete members – beams, ribs, running beams, one way reinforced slabs, girders, lintels, cantilever structures, columns and stairs.
Design of reinforced concrete members stressed by combination of axial force and bending moments. Principles of dimensioning for different stresses (torsion, local stress, etc).
Dimensioning of members both from plain and low reinforced concrete.
Language of instruction
Czech
Number of ECTS credits
5
Mode of study
Not applicable.
Department
Institute of Concrete and Masonry Structures (BZK)
Learning outcomes of the course unit
A student gains these knowledge and skills:
Knowledge of the behaviour of concrete members differently stressed.
Knowledge of the principles of reinforced concrete cross-section dimensioning for general stresses.
Virtue for designing reinforced concrete members.
Virtue for designing simple reinforced concrete structures.
Ability of preparing relevant technical drawings for reinforcing RC members.
Knowledge of the behaviour of concrete members differently stressed.
Knowledge of the principles of reinforced concrete cross-section dimensioning for general stresses.
Virtue for designing reinforced concrete members.
Virtue for designing simple reinforced concrete structures.
Ability of preparing relevant technical drawings for reinforcing RC members.
Prerequisites
technical mathematics, technical physics, structural mechanics, theory of elasticity, loads, basic principles of structures design
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. Principle, behaviour and sorting of concrete members. Influence of concrete components on properties of concrete. Structural properties of concrete (strength, elasticity, deformability) – influencing factors.
2. Types of concrete and reinforcement – their interaction. Theory of concrete structures calculation – load, requirements, action conditions, durability. Ultimate limit states – principle of calculation.
3. Bended members. Dimensioning of sections stressed by bending moment – general and simple method.
4. Dimensioning of sections stressed by bending moment – rectangular sections, special sections, common sections, sections stressed by bending moment in incline plane.
5.- 6. Dimensioning of sections stressed by shearing force.
7. Arrangement of reinforcement in a girder – structural principles. Reinforcement of bended structural members.
8. Principles of design and reinforcing of simple structural concrete members – plate girders, beams, girders, lintels and cantilever structures.
9. Principles of design and reinforcing – stairs.
10. Dimensioning of sections stressed by bending moment and normal force (principle of solution, interactive diagram, impact of slenderness, compresssioned members).
11. Dimensioning of sections stressed by combination of axial force and bending moments (tensioned members, transversal deflection with axial force, serviceability, principles of columns reinforcing).
12. Principles of sections dimensioning for different stresses (torsion, local stress, etc). Dimensioning of members from plain and low reinforced concrete.
13. Design of members stressed by bending moment according to limit state of serviceability. Volume changes of concrete (creep, shrinkage, temperature changes).
2. Types of concrete and reinforcement – their interaction. Theory of concrete structures calculation – load, requirements, action conditions, durability. Ultimate limit states – principle of calculation.
3. Bended members. Dimensioning of sections stressed by bending moment – general and simple method.
4. Dimensioning of sections stressed by bending moment – rectangular sections, special sections, common sections, sections stressed by bending moment in incline plane.
5.- 6. Dimensioning of sections stressed by shearing force.
7. Arrangement of reinforcement in a girder – structural principles. Reinforcement of bended structural members.
8. Principles of design and reinforcing of simple structural concrete members – plate girders, beams, girders, lintels and cantilever structures.
9. Principles of design and reinforcing – stairs.
10. Dimensioning of sections stressed by bending moment and normal force (principle of solution, interactive diagram, impact of slenderness, compresssioned members).
11. Dimensioning of sections stressed by combination of axial force and bending moments (tensioned members, transversal deflection with axial force, serviceability, principles of columns reinforcing).
12. Principles of sections dimensioning for different stresses (torsion, local stress, etc). Dimensioning of members from plain and low reinforced concrete.
13. Design of members stressed by bending moment according to limit state of serviceability. Volume changes of concrete (creep, shrinkage, temperature changes).
Work placements
Not applicable.
Aims
To teach the students to the principles of reinforced concrete cross-section dimensioning at the principal stresses.
To gain ability for design of reinforced concrete members and simple structures together with preparing relevant technical drawings.
To gain ability for design of reinforced concrete members and simple structures together with preparing relevant technical drawings.
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
MOSLEY, Bill, BUNGEY, John a HULSE, Ray: Reinforced Concrete Design to Eurocode 2. New York: Palgrave Macmillan, 2012. ISBN 978-0-230-30285-3. (EN)
NILSON, Arthur, DARWIN, David a DOLAN, Charles: Design of Concrete Structures. New York: McGraf-Hill, 2009. ISBN 978-0073293493. (EN)
WIGHT, James G. a MacGREGOR, James G.: Reinforced Concrete: Mechanics and Design. New Jersey: Pearson-Prentice Hall, 2011. ISBN 978-0132176521. (EN)
NILSON, Arthur, DARWIN, David a DOLAN, Charles: Design of Concrete Structures. New York: McGraf-Hill, 2009. ISBN 978-0073293493. (EN)
WIGHT, James G. a MacGREGOR, James G.: Reinforced Concrete: Mechanics and Design. New Jersey: Pearson-Prentice Hall, 2011. ISBN 978-0132176521. (EN)
Recommended reading
BILČÍK, Juraj, FILLO, Ľudovít, BENKO, Vladimír a HALVONÍK, Jaroslav: Betónové konštrukcie. Navrhovanie podľa EN 1992-1-1.. Bratislava: STU, 2008. ISBN 978-80-227-2940-6. (SK)
PROCHÁZKA, Jaroslav, ŠTĚPÁNEK, Petr, KRÁTKÝ, Jiří, KOHOUTKOVÁ, Alena a VAŠKOVÁ, Jitka: Navrhování betonových konstrukcí 1. Prvky z prostého a železového betonu. Praha: ČBS Servis, 2009. ISBN 978-80-903807-5-2. (CS)
PROCHÁZKA, Jiří a ŠTEMBERK, Petr: Concrete Structures 1. Praha: ČVUT, 2007. ISBN 978-80-01-03607-5. (EN)
TERZIJSKI, Ivailo, ŠTĚPÁNEK, Petr, ČÍRTEK, Ladislav, ZMEK, Bohuslav a PANÁČEK, Josef: Prvky betonových konstrukcí. Modul CM1 až CM5 (studijní opora v elektronické podobě). Brno: VUT, 2005. (CS)
ZICH, Miloš a kol.: Příklady posouzení betonových prvků dle Eurokódů. Praha: Verlag Dashöfer, 2010. ISBN 978-80-86897-38-7. (CS)
PROCHÁZKA, Jaroslav, ŠTĚPÁNEK, Petr, KRÁTKÝ, Jiří, KOHOUTKOVÁ, Alena a VAŠKOVÁ, Jitka: Navrhování betonových konstrukcí 1. Prvky z prostého a železového betonu. Praha: ČBS Servis, 2009. ISBN 978-80-903807-5-2. (CS)
PROCHÁZKA, Jiří a ŠTEMBERK, Petr: Concrete Structures 1. Praha: ČVUT, 2007. ISBN 978-80-01-03607-5. (EN)
TERZIJSKI, Ivailo, ŠTĚPÁNEK, Petr, ČÍRTEK, Ladislav, ZMEK, Bohuslav a PANÁČEK, Josef: Prvky betonových konstrukcí. Modul CM1 až CM5 (studijní opora v elektronické podobě). Brno: VUT, 2005. (CS)
ZICH, Miloš a kol.: Příklady posouzení betonových prvků dle Eurokódů. Praha: Verlag Dashöfer, 2010. ISBN 978-80-86897-38-7. (CS)
Classification of course in study plans
- Programme B-K-C-SI Bachelor's
branch VS , 2 year of study, summer semester, compulsory
- Programme B-P-C-MI Bachelor's
branch MI , 2 year of study, summer semester, compulsory
- Programme B-P-C-SI Bachelor's
branch VS , 2 year of study, summer semester, compulsory
- Programme B-P-E-SI Bachelor's
branch VS , 2 year of study, summer semester, compulsory
Type of course unit
Lecture
26 hod., optionally
Teacher / Lecturer
Syllabus
1. Principle, behaviour and sorting of concrete members. Influence of concrete components on properties of concrete. Structural properties of concrete (strength, elasticity, deformability) – influencing factors.
2. Types of concrete and reinforcement – their interaction. Theory of concrete structures calculation – load, requirements, action conditions, durability. Ultimate limit states – principle of calculation.
3. Bended members. Dimensioning of sections stressed by bending moment – general and simple method.
4. Dimensioning of sections stressed by bending moment – rectangular sections, special sections, common sections, sections stressed by bending moment in incline plane.
5.- 6. Dimensioning of sections stressed by shearing force.
7. Arrangement of reinforcement in a girder – structural principles. Reinforcement of bended structural members.
8. Principles of design and reinforcing of simple structural concrete members – plate girders, beams, girders, lintels and cantilever structures.
9. Principles of design and reinforcing – stairs.
10. Dimensioning of sections stressed by bending moment and normal force (principle of solution, interactive diagram, impact of slenderness, compresssioned members).
11. Dimensioning of sections stressed by combination of axial force and bending moments (tensioned members, transversal deflection with axial force, serviceability, principles of columns reinforcing).
12. Principles of sections dimensioning for different stresses (torsion, local stress, etc). Dimensioning of members from plain and low reinforced concrete.
13. Design of members stressed by bending moment according to limit state of serviceability. Volume changes of concrete (creep, shrinkage, temperature changes).
2. Types of concrete and reinforcement – their interaction. Theory of concrete structures calculation – load, requirements, action conditions, durability. Ultimate limit states – principle of calculation.
3. Bended members. Dimensioning of sections stressed by bending moment – general and simple method.
4. Dimensioning of sections stressed by bending moment – rectangular sections, special sections, common sections, sections stressed by bending moment in incline plane.
5.- 6. Dimensioning of sections stressed by shearing force.
7. Arrangement of reinforcement in a girder – structural principles. Reinforcement of bended structural members.
8. Principles of design and reinforcing of simple structural concrete members – plate girders, beams, girders, lintels and cantilever structures.
9. Principles of design and reinforcing – stairs.
10. Dimensioning of sections stressed by bending moment and normal force (principle of solution, interactive diagram, impact of slenderness, compresssioned members).
11. Dimensioning of sections stressed by combination of axial force and bending moments (tensioned members, transversal deflection with axial force, serviceability, principles of columns reinforcing).
12. Principles of sections dimensioning for different stresses (torsion, local stress, etc). Dimensioning of members from plain and low reinforced concrete.
13. Design of members stressed by bending moment according to limit state of serviceability. Volume changes of concrete (creep, shrinkage, temperature changes).
Exercise
26 hod., compulsory
Teacher / Lecturer
Syllabus
1. Load and its calculation, combination and effects. Idealisation of basic structural members. Design of cast-in-place reinforced concrete structure – project: Defined task, preliminary design of dimensions, analyse of structural solution and static system, scheme of shape of structure.
2. Basic materials of reinforced concrete, interaction of concrete and reinforcement, durability of concrete members.
3. Bended members, design and assessment of the slabs: single supported floor slab – load, action of forces, dimensioning for bend and shear, transverse reinforcement, anchorage of reinforcement, modification of reinforcement in the areas of partial fixation, scheme of reinforcement.
4. Design and assessment of slabs: continuous floor slab – load, action of forces (redistribution of forces), dimensioning for bend, scheme of reinforcement.
5. Design and assessment of flat floor beam - load, action of forces, dimensioning for bend (T-section, comparison with rectangular cross-section).
6. Framed member of general cross-section stressed by bend – general method, application on cantilever beam (example).
7. Correction.
8. Slab floor girder – dimensioning for shear, axial shear, curtailment of reinforcement.
9. Design and assessment of a lintel - load, action of forces, dimensioning for bend, shear, direct and indirect bedding of girder, scheme of reinforcement.
10. Reinforcement of rings. Drawings of reinforcement of calculated members.
11. Vertical framed concrete structures: RC column stressed by eccentric pressure – load, action of forces, verification of load-bearing capacity via interactive diagram (example).
12. Correction.
13. Project submission. Credit.
2. Basic materials of reinforced concrete, interaction of concrete and reinforcement, durability of concrete members.
3. Bended members, design and assessment of the slabs: single supported floor slab – load, action of forces, dimensioning for bend and shear, transverse reinforcement, anchorage of reinforcement, modification of reinforcement in the areas of partial fixation, scheme of reinforcement.
4. Design and assessment of slabs: continuous floor slab – load, action of forces (redistribution of forces), dimensioning for bend, scheme of reinforcement.
5. Design and assessment of flat floor beam - load, action of forces, dimensioning for bend (T-section, comparison with rectangular cross-section).
6. Framed member of general cross-section stressed by bend – general method, application on cantilever beam (example).
7. Correction.
8. Slab floor girder – dimensioning for shear, axial shear, curtailment of reinforcement.
9. Design and assessment of a lintel - load, action of forces, dimensioning for bend, shear, direct and indirect bedding of girder, scheme of reinforcement.
10. Reinforcement of rings. Drawings of reinforcement of calculated members.
11. Vertical framed concrete structures: RC column stressed by eccentric pressure – load, action of forces, verification of load-bearing capacity via interactive diagram (example).
12. Correction.
13. Project submission. Credit.