CONSTRUCTION TECHNIQUES
- Overview
- Assessment methods
- Learning objectives
- Contents
- Full programme
- Bibliography
- Teaching methods
- Contacts/Info
The basics of Mechanics of Materials are assumed to be well known.
The course is intended to be assessed after a positive grade (equal to or higher of 18/30) in the oral examination, which covers all the subjects of the course. In order to access the oral examination, the students need to positively sustain a written examination inherent the solution of plane frame structures subjected to static loads and restraint settlements with the stiffness method. A positive judgement from letter A to letter C, being A the maximum, will be attributed to the written exam. This judgement will have orientative influence on the oral examination result.
It is also necessary to deliver at the oral examination the following homework developed independently by the student:
- serviceability and ultimate limit state checks of a reinforced concrete structural element.
The students allowed to attend the exams should be registered regularly at the on-line platform and should provide the university card before starting the exam. In case of refusal of the final score, the student should communicate it within 5 days after the publication of the vote in the ESSE3 platform.
AIM OF THE COURSE
The aim of the course is to provide the students with the following skills: (a) resolution of statically determined and undetermined beams, (b) resolution of planar frames with the stiffness method, (c) notions on the semiprobabilistic method of limit states, (d) load analysis, (e) design techniques of reinforced concrete structures in service, (f) design techniques of reinforced concrete structures at failure, (g) structural detailing of reinforced concrete elements.
LEARNING OUCOMES
• Cognitive skills
- to acquire the fundamentals information needed to address the modelling of design actions on a structure
- to govern the techniques of structural analysis to obtain actions and deformations on a structure
- to possess the necessary information to critically face a design or check process of a reinforced concrete structure
• Learning abilities
- ability to read, understand and criticize a scientific text about the behaviour of reinforced concrete structures (also in English)
- ability to read, understand and comment technical documents in support of design or check of reinforced concrete structures
• Practical and subject specific skills
- ability to propose a problem-solving approach
- ability to identify the main issues necessary for the development of technical documentation in support of reports of design or check of structures
• Communication skills
- ability to identify, extract and synthesize relevant information
- demonstrate effective communication skills by practicing, reading, writing and speaking clearly
- demonstrate the ability to communicate with industry experts.
STRUCTURAL ANALYSIS (22 h)
Statically determined beams and methods of the Mohr corollary and elastic line. Statically undetermined beams and flexibility method. Planar frames and stiffness method.
NOTIONS OF STRUCTURAL DESIGN (4 h)
Semiprobabilistic method of Limit States. Loads. Load combinations.
REINFORCED CONCRETE STRUCTURES (22 h)
Typologies and physycal-chemical composition of concretes and reinforcements. Creep, shrinkage, bond and anchorage. Technical reinforcement details. Axial action and cracking mechanism. Simple, composed, and deviated flexure and moment-curvature diagrams. Shear and torsion. Deformation and stress checks. Foundation elements and strut&tie design methodology. Techniques and technologies of pre-stressing. Limit points and Guyon spindle. Flexural checks of pre-stressed elements.
STRUCTURAL ANALYSIS (22 h)
Statically determined beams and methods of the Mohr corollary and elastic line. Statically undetermined beams and flexibility method. Planar frames and stiffness method.
NOTIONS OF STRUCTURAL DESIGN (4 h)
Semiprobabilistic method of Limit States. Loads. Load combinations.
REINFORCED CONCRETE STRUCTURES (22 h)
Typologies and physycal-chemical composition of concretes and reinforcements. Creep, shrinkage, bond and anchorage. Technical reinforcement details. Axial action and cracking mechanism. Simple, composed, and deviated flexure and moment-curvature diagrams. Shear and torsion. Deformation and stress checks. Foundation elements and strut&tie design methodology. Techniques and technologies of pre-stressing. Limit points and Guyon spindle. Flexural checks of pre-stressed elements.
Slides of lectures: download from e-learning website (note: only part of the lectures will be given with presentation of slides. The rest of the lectures will be given at the blackboard).
Specific scientific/technical papers suggested by the lecturer.
Main suggested books:
Toniolo G. (1990) “Calcolo strutturale. I telai”, Zanichelli.
Toniolo G., di Prisco, M. (2010) “Cemento armato. Calcolo agli stati limite”, Zanichelli (2 volumi).
For further reading:
Santarella L. (2010) “Prontuario del cemento armato”, Hoepli.
Giuliani G. (2008) “Costruzioni in calcestruzzo armato”, Hoepli.
Cestelli Guidi C. (1986) “Cemento armato precompresso”, Hoepli.
Technical standards:
NTC 2018
Eurocodes
Additional specific minor standards suggested along with the course
The course is based on frontal theoretical lessons. Different teaching methods included remote lectures on streaming may be proposed for exceptional cases.
Students can meet with the professor in his office by previous phone or email appointment.