Reinforced Concrete Structures I


This course has the purpose of providing basic information on reinforced concrete structures, focusing namely on the durability of reinforced concrete and on the design approach adopted in the Eurocodes, based on the verification of safety to limit states.In the course, the analysis of structural elements (e.g. ties, beams and columns) is presented using the concept of ultimate and serviceability limit states. Detailing of such elements is also addressed.

Attention is also given to the design and detailing of reinforced concrete structures under seismic and fire actions.


General characterization





Responsible teacher

Valter José da Guia Lúcio


Weekly - 5

Total - Available soon

Teaching language



It is assumed that the students have acquired the concepts taught in Strength of Materials I and II.



- EN1990 – Eurocode Bases of Structural Design.

- EN1991-1 - Eurocode 1 – Actions on structures.

- EN1992-1-1 - Eurocode 2 – Design of concrete structures.

- EN1998-1 - Eurocode 8 – Design of structures for earthquake resistance.

- Presentations of the classes.

Teaching method

Reinforced Concrete Structures I has two lectures classes each week with 2:30h each.

In the lectures classes the subjects are presented and the students solve practical problems with the guidance of the professor.

The evaluation will be done with basis on a final exam, exercises and the problems solved by the students in the classes.


Evaluation method

The evaluation of knowledge has two components: one done by works and classroom participation of the student during the semester and the other by two minitests or final exam.

1. Minitests

Written minitests  NE = (1stMT + 2ndMT)/2, grade = 0 to 20 (≥ 7.5).

2. Exam

Written exam NE, grade = 0 to 20 (≥ 7.5).

3. Works and classroom participation

Problem solving sessions Ac ≥ 7.5      Ac = 0 to 20.

4. Final Grade = 0.8 x NE + 0.2 x Ac

Students with a final grade greater than 16 must do an oral exam.

Subject matter

1.     Introduction to reinforced concrete

2.     Actions

3.     Material properties

4.     Limit state safety approach

5.     Durability

6.     Ultimate limit state of strength to tension and compression

7.     Ultimate limit state of strength to bending

8.     Ultimate limit state of strength to shear

9.     Constructive specifications for beams

10.   Limit state of cracking

11.   Limit state of deformation

12.   Ultimate limit states of strength to bending plus axial force and to asymmetric bending.

13.   Ultimate limit states induced by structural deformation

14.   Constructive specifications for columns

15.   Calculation and detailing of resisting walls

16.  Ultimate limit state of strength to torsion



Programs where the course is taught: