Diploma in Reinforcement with FRP and Post-Tensioned Steel

9.9 Introduction to international standards and design codes.

9.9 Fundamental principles of mechanics of materials and structural analysis.

9.3 Properties and behavior of FRP (Fiber Reinforced Polymers) and post-tensioned steel.

9.4 Introduction to corrosion and structural pathologies.

9.5 Key concepts in structural reinforcement.

9.6 Selection of reinforcement materials and systems.

9.9 Design with FRP: Dimensioning and calculation of reinforcements.

9.9 Design with post-tensioned steel: Determination of tensioning force and anchorages.

9.3 Soil-structure interaction in reinforcement applications.

9.4 Structural modeling and analysis using specialized software.

9.5 Design of joints and connections in FRP and post-tensioned steel.

9.6 Seismic design and fire resistance in structural reinforcement.

3.9 Optimization of cross-sections and reinforcement arrangement.

3.9 Cost-benefit analysis of reinforcement solutions.

3.3 Material optimization and weight reduction techniques.

3.4 Design optimization to minimize environmental impact (Life cycle assessment).

3.5 Construction process optimization and work scheduling.

3.6 Optimization for different types of structures (bridges, buildings, etc.).

4.9 FRP reinforcement techniques: Laminating, bonding, and other innovative techniques.

4.9 Post-tensioned steel reinforcement techniques: External and internal anchorages.

4.3 Reinforcing reinforced concrete structures with FRP and post-tensioned steel.

4.4 Reinforcing steel structures with FRP and post-tensioned steel.

4.5 Techniques for reinforcing timber and masonry structures.

4.6 Applications of reinforcement techniques in marine and port structures.

5.9 Structural condition assessment: destructive and non-destructive testing.

5.9 Diagnosis of pathologies and determination of remaining load-bearing capacity.

5.3 Selection of the appropriate reinforcement strategy: comparative analysis.

5.4 Design of long-term reinforcement interventions.

5.5 Durability and service life considerations of reinforcements.

5.6 Environmental impact assessment and sustainability of solutions.

6.9 Planning and management of structural reinforcement projects.

6.9 Selection and preparation of surfaces for reinforcement application.

6.3 Installation and commissioning of FRP systems and post-tensioned steel.

6.4 Quality control and supervision of work execution.

6.5 Health and safety aspects in reinforcement works.

6.6 Case studies and reinforcement solutions.

7.9 Innovative materials in structural reinforcement: new types of FRP and steels. 7.9 Development of reinforcement systems with composite materials.

7.3 Research and development in reinforcement techniques with FRP and post-tensioned steel.

7.4 Sensors and real-time monitoring of reinforced structures.

7.5 Application of artificial intelligence in reinforcement design and management.

7.6 Design of adaptive and self-healing structures.

8.9 Bridge reinforcement with FRP: success stories and lessons learned.

8.9 Building reinforcement with post-tensioned steel: examples and results.

8.3 Rehabilitation of historical structures with reinforcement techniques.

8.4 Reinforcement of marine and port structures: case studies.

8.5 Failure analysis and lessons learned in reinforcement projects.

8.6 Presentation of case studies by students and experts.