Diploma in Structural Diagnosis and In Situ Testing

9.9 Fundamentals of Naval Structural Diagnostics: Key concepts and terminology.

9.9 Importance of In-Situ Testing: Advantages and applications in naval structures.

9.3 Types of In-Situ Testing: Visual inspection, load testing, and thickness measurement.

9.4 Data Collection and Analysis: Interpretation of results and reporting of findings.

9.5 Introduction to legislation and regulations: Compliance in the naval sector.

9.9 Advanced Ultrasound: Phased Array and TOFD techniques for defect detection.

9.9 Digital Radiography: Principles, applications, and image analysis in naval structures.

9.3 Infrared Thermography: Detection of thermal anomalies and integrity assessment.

9.4 Vibration Analysis: Machinery monitoring and detection of incipient failures. 9.5 Corrosion Assessment Techniques: Corrosion Rate Measurement and Cathodic Protection

3.9 Principles of Non-Destructive Testing (NDT): Advantages and Limitations
3.9 Ultrasound-Based NDT: Applications and Specific Techniques
3.3 Magnetic Particle Inspection: Detection of Surface and Subsurface Discontinuities
3.4 Liquid Penetrant Testing: Detection of Surface Defects in Materials
3.5 Evaluation of Results: Acceptance and Rejection Criteria, Evaluation Reports

4.9 Planning and Preparation for In-Situ Testing: Selection of Techniques and Equipment
4.9 Evaluation Methodologies: Visual Inspection, Tensile Testing, and Deformation Analysis
4.3 In-Situ Data Analysis: Software and Structural Simulation Tools
4.4 Evaluation of Structural Integrity: Evaluation Criteria and Recommendations 4.5 Preparation of technical reports: Documentation of findings and conclusions.

5.9 Types of structural damage: Corrosion, fatigue, and overloading.

5.9 Corrosion assessment: Measurement and analysis techniques.

5.3 Fatigue analysis: Modeling and simulation of structural behavior.

5.4 Integrity analysis: Evaluation of residual load-bearing capacity.

5.5 Case studies: Failure analysis and corrective measures.

6.9 Failure analysis: Methodology, steps, and tools.

6.9 Root cause identification: Cause-and-effect analysis and Ishikawa diagram.

6.3 Failure modes and effects analysis (FMEA): Application to naval structures.

6.4 Failure evaluation: Acceptance and rejection criteria.

6.5 Design and evaluation of solutions: Repair and prevention of failures.

7.9 Advanced sensors: Monitoring and remote sensing technologies. 7.9 Artificial intelligence and machine learning: Application in structural diagnostics.

7.3 Drones and robotics: Inspection in hard-to-reach areas.

7.4 3D modeling and augmented reality: Data visualization and analysis.

7.5 Data integration: Platforms and information management systems.

8.9 Comprehensive evaluation methodology: Planning and scope.

8.9 Risk assessment: Identification and analysis of risks in naval structures.

8.3 Life cycle analysis: Design, construction, operation, and maintenance.

8.4 Cost-benefit analysis: Profitability of proposed solutions.

8.5 Reporting and recommendations: Effective communication of results.