Diploma in Vibration Mitigation and Damping Devices
Sobre nuestro Diploma in Vibration Mitigation and Damping Devices
The Diploma in Vibration Mitigation and Damping Devices focuses on the study of mechanical vibrations and their control in systems and structures. The program delves into vibration analysis, the application of damping technologies, and the design of solutions to reduce or eliminate the harmful effects of vibrations. Advanced methods and devices for mitigating vibrations in different contexts are explored, such as mechanical engineering, civil engineering, and the automotive industry.
The diploma offers practical training in the use of vibration analysis tools, including simulation software and measurement techniques. Topics covered include the selection of materials with specific damping properties, the design of dampers, and the implementation of vibration control systems. Participants acquire skills to diagnose vibration problems, develop effective solutions, and optimize system performance, contributing to the safety, efficiency, and durability of structures and equipment.
Target keywords (naturally occurring in the text): mechanical vibrations, damping devices, damping, vibration analysis, mechanical engineering, civil engineering, automotive industry, vibration control, safety, efficiency, durability.
Diploma in Vibration Mitigation and Damping Devices
- Modalidad: Online
- Duración: 8 meses
- Horas: 900 H
- Idioma: ES / EN
- Créditos: 60 ECTS
- Fecha de matrÃcula: 30-04-2026
- Fecha de inicio: 10-06-2026
- Plazas disponibles: 3
1.449 $
Competencias y resultados
Qué aprenderás
1. Mastery of Vibration Mitigation and Damping Devices in Naval Environments
- Identify vibration sources in naval structures, including machinery and systems.
- Understand the principles of structural dynamics and vibration propagation.
- Evaluate the effects of vibration on structural integrity, crew comfort, and equipment performance.
- Apply modeling and simulation techniques to analyze the vibration behavior of naval structures.
- Select and design vibration mitigation solutions, including dampers, isolators, and tuned masses.
- Master the use of damping materials and technologies, such as viscoelastic laminates and coatings.
- Perform vibration measurements and analyses to diagnose problems and evaluate the effectiveness of implemented solutions.
- Analyze flap-lag-torsion, whirl flutter, and fatigue couplings.
- Size laminates in composites, unions and bonded joints with FE.
- Implement damage tolerance and NDT (UT/RT/thermography).
2. Advanced Strategies for Vibration Control and Damping in Naval Design [The text abruptly shifts to a seemingly unrelated topic:] [The text abruptly shifts again ...
- Model and simulate the structural response of naval systems to vibrations, considering excitation sources such as engines, propellers, and waves.
- Apply modal analysis techniques to identify critical vibration modes and resonant frequencies.
- Design passive (viscoelastic dampers, resonators) and active (piezoelectric controllers) damping systems to reduce vibration amplitude.
- Evaluate the dynamic behavior of naval structures under transient and cyclic loads, including fatigue analysis.
- Select and use materials with optimized damping properties for naval applications.
- Use finite element analysis (FEA) software to analyze the vibrational behavior of components and complete structures.
- Understand the effects of corrosion and other environmental factors on the durability of naval structures.
- Apply monitoring and Vibration diagnostics for early fault detection and maintenance optimization.
Interpret and analyze vibration data to identify problems and evaluate the effectiveness of implemented solutions.
Explore the latest trends in vibration control and damping, including the use of smart materials and cutting-edge technologies.
3. Comprehensive user-oriented design and validation (from modeling to manufacturing)
You will learn to integrate the entire product development process, from initial model conception to final validation, applying user-centered methodologies. You will develop skills in parametric design, ergonomics, simulation, sustainable materials, 3D visualization, and manufacturing management, ensuring efficient, safe solutions that meet current industry standards.
4. Evaluation and Improvement of Rotor Performance for Vibration Reduction in Ships
4. Evaluation and Improvement of Rotor Performance for Vibration Reduction in Ships
- Analyze flap-lag-torsion, whirl flutter, and fatigue couplings.
- Dimension laminates in composites, joints, and bonded joints with FE.
- Implement damage tolerance and NDT (UT/RT/thermography).
5. Implementation of Damping Solutions and Rotor Analysis for Naval Vibroacoustic Stability
5. Implementation of Damping Solutions and Rotor Analysis for Naval Vibroacoustic Stability
- Identify and evaluate vibroacoustic instability phenomena in naval systems, including analysis of flap-lag-torsion couplings, whirl flutter, and the effects of fatigue on critical components.
- Apply finite element (FE) analysis techniques for the dimensioning and design of composite structures, paying special attention to the correct configuration of joints and bonded joints, ensuring structural integrity under dynamic and environmental loads.
- Integrate damage tolerance methodologies and employ non-destructive testing (NDT) techniques, such as UT (ultrasound), RT (radiography), and thermography, for the early detection of damage and the evaluation of structural integrity and extended service life of naval components.
6. Advanced Modeling and Performance Optimization of Rotors for Marine Vibration Mitigation
You will learn to integrate the entire product development process, from initial model conception to final validation, applying user-centered methodologies. You will develop skills in parametric design, ergonomics, simulation, sustainable materials, 3D visualization, and manufacturing management, ensuring efficient, safe solutions that meet current industry standards.
Para quien va dirigido nuestro:
Diploma in Vibration Mitigation and Damping Devices
- Engineers with degrees in Aerospace Engineering, Mechanical Engineering, Industrial Engineering, Automation Engineering, or related disciplines.
- Professionals working in OEMs of rotorcraft/eVTOL aircraft, maintenance, repair, and overhaul (MRO) companies, consulting firms, or technology centers.
- Specialists in areas such as flight testing, aeronautical certification, avionics, systems control, and flight dynamics seeking to deepen their knowledge.
- Personnel from regulatory bodies/authorities Aeronautical professionals and those with related urban air mobility (UAM)/eVTOL profiles interested in acquiring regulatory compliance skills.
Recommendations: Basic knowledge of aerodynamics, systems control, and structures is suggested. A B2+ or C1 level of English (ES/EN) is required. We offer bridging tracks to address any gaps in prior knowledge.
- Standards-driven curriculum: you will work with CS-27/CS-29, DO-160, DO-178C/DO-254, ARP4754A/ARP4761, ADS-33E-PRF from the first module.
- Accreditable laboratories (EN ISO/IEC 17025) with rotor bench, EMC/Lightning pre-compliance, HIL/SIL, vibrations/acoustics.
- Evidence-oriented TFM: safety case, test plan, compliance dossierand operational limits.
- Mentored by industry: teachers with experience in rotorcraft, tiltrotor, eVTOL/UAM and flight test.
- Flexible modality (hybrid/online), international cohorts and support from SEIUM Career Services.
- Ethics and security: safety-by-design approach, cyber-OT, DIH and compliance as pillars.
1.1 Introduction to Vibrations in Naval Environments: Types and Causes
1.2 Principles of Vibration Mitigation: Key Concepts
1.3 Damping Devices: Types and Applications in the Naval Industry
1.4 Analysis of Vibration Sources in Ships: Engines, Propellers, etc.
1.5 Selection and Application of Damping Materials: Design Criteria
1.6 Design of Vibration Isolation Systems: Techniques and Tools
1.7 Vibration Instrumentation and Measurement: Sensors and Data Analysis
1.8 Case Studies: Application of Damping in Different Types of Ships
1.9 Regulations and Standards in Naval Vibration Mitigation
1.10 Maintenance and Monitoring of Damping Systems
2.2 Fundamentals of Naval Design for Vibration Mitigation
2.2 Selection and Application of Damping Materials in Naval Design
2.3 Modal Analysis and Frequency Response of Naval Structures
2.4 Vibration Isolation Techniques in Ships
2.5 Design of Active and Passive Damping Systems
2.6 Design Optimization Strategies for Vibration Reduction
2.7 Simulation and Modeling Tools for Vibroacoustic Analysis
2.8 Design of Rotors and Propellers for Vibration Minimization
2.9 Integration of Vibration Mitigation Systems into Ship Design
2.20 Case Studies: Application of Advanced Strategies in Naval Design
3.3 Fundamentals of Rotor Analysis in Marine Applications
3.2 Identification and Characterization of Vibration Sources in Naval Propulsion Systems
3.3 Rotor Modeling: Theoretical and Practical Aspects
3.4 Finite Element Analysis (FEA) Applied to Marine Rotors
3.5 Advanced Optimization Techniques for Vibration Reduction
3.6 Computational Flow Analysis (CFD) Simulation and Analysis in Rotor Design
3.7 Evaluation of the Impact of Design on Rotor Fatigue and Durability
3.8 Vibration Mitigation Strategies Based on Rotor Design
3.9 Case Studies: Vibration Analysis and Reduction in Different Types of Vessels
3.30 Implementation and Validation of Solutions: A Practical Approach
3.4
4.4 Evaluation of the Vibrational Response of Rotors in Naval Environments
4.2 Analysis of Vibration Modes and Critical Frequencies in Naval Rotors
4.3 Selection and Application of Materials for Vibration Mitigation in Rotors
4.4 Design of Rotors Optimized for Vibration Reduction
4.5 Rotor Balancing Techniques and Imbalance Elimination
4.6 Numerical Modeling and Simulation of Vibrations in Rotors
4.7 Case Studies: Failure Analysis and Solutions in Rotor Systems
4.8 Bench Testing and Vibration Measurements in Marine Rotors
4.9 Preventive Maintenance Strategies for Rotor Systems
4.40 Implementation of Damping Solutions in Naval Propulsion Systems
4.5
5.5 Introduction to Damping Solutions in Naval Environments
5.5 Types of Damping Materials and Devices Applied to Ships
5.3 Vibration Analysis and Mitigation Strategies
5.4 Implementation of Damping Solutions for Vibroacoustic Stability
5.5 Rotor Design: Vibroacoustic Considerations
5.6 Vibration Mode Analysis in Naval Structures
5.7 Evaluation of the Effectiveness of Damping Solutions
5.8 Modeling and Simulation of Naval Vibroacoustic Systems
5.9 Integration of Damping Solutions into Naval Design
5.50 Case Studies: Application of Damping Solutions to Specific Ships
5.6
6.6 Introduction to Marine Rotor Modeling and its Importance in Vibration Mitigation
6.2 Fundamentals of Rotor Theory and its Application in Naval Environments
6.3 Computational Rotor Modeling: Software and Tools
6.4 Finite Element Analysis (FEA) Applied to Marine Rotors
6.5 Rotor Design Optimization for Vibration Reduction
6.6 Hydrodynamic Considerations in Rotor Design
6.7 Evaluation of Rotor Life and Performance
6.8 Vibration Mode Analysis and its Impact on Naval Structures
6.9 Case Studies: Practical Examples of Rotor Optimization
6.60 Conclusions and Future Trends in Marine Rotor Modeling
7.7 Introduction to Damping Solutions in Naval Applications
7.2 Principles of Vibroacoustic Stability in Ships
7.3 Implementation of Damping Materials: Selection and Application
7.4 Vibration Analysis: Identification of Sources and Modes
7.7 Design of Damping Systems: Dampers and Devices
7.6 Rotor Analysis: Impact on Vibration and Noise
7.7 Integration of Damping Solutions and Rotors: Synergies
7.8 Case Studies: Real-World Applications and Results
7.9 Regulations and Standards in Naval Vibroacoustic Stability
7.70 The Future of Damping Solutions in the Naval Industry
7.8
8.8 Introduction to Vibrations in Naval Environments
8.8 Types of Vibrations in Ships and Their Causes
8.3 Principles of Vibration Mitigation
8.4 Fundamentals of Damping Devices and Their Applications
8.5 Selection of Materials and Damping Techniques in the Naval Industry
8.6 Case Studies: Damping Applications in Ships
8.7 Regulations and Standards in Naval Vibration Mitigation
8.8 Maintenance and Evaluation of Damping Systems
8.8 Naval Design and Vibration Control: An Overview
8.8 Vibration Isolation and Damping Strategies
8.3 Advanced Damping Techniques: Materials and Applications
8.4 Design of Anti-Vibration Systems: Theory and Practice
8.5 Optimization of Equipment Layout for Vibration Reduction
8.6 Modal Analysis and Simulation in Naval Design
8.7 Integration of Anti-Vibration Solutions in the Design Phase
8.8 Case Studies: Implementation of Anti-Vibration Strategies
3.8 Fundamentals of Vibration Analysis Rotors: Theory and Methods
3.8 Rotor Modeling and Simulation in Marine Applications
3.3 Identifying Vibration Sources in Rotors
3.4 Optimization Techniques for Reducing Vibration in Rotors
3.5 Designing and Selecting Rotors to Minimize Vibration
3.6 Analyzing the Vibration Response of Rotors
3.7 Rotor Analysis Tools and Software
3.8 Case Study: Rotor Optimization for Vibration Reduction
4.8 Rotor Performance Evaluation: Methodologies
4.8 Rotor Vibration Testing and Measurement
4.3 Rotor Failure Analysis and Troubleshooting
4.4 Rotor Design Improvements for Vibration Reduction
4.5 Modifying and Adapting Existing Rotors
4.6 Optimizing the Hydrodynamic and Mechanical Performance of Rotors
4.7 Implementing Predictive Maintenance Strategies
4.8 Case Study: Rotor Evaluation and Improvement
5.8 Integrating Damping Solutions and Rotor Analysis
5.8 Impact of Damping Systems on Vibroacoustic Stability
5.3 Analysis of the Interaction Between Rotors and Damping Systems
5.4 Design of Ship-Specific Damping Systems
5.5 Application of Simulation Software for Vibroacoustic Analysis
5.6 Evaluation of Noise and Vibration in Naval Environments
5.7 Regulations and Standards in Vibroacoustic Stability
5.8 Case Studies: Implementation of Integrated Solutions
6.8 Advanced Rotor Modeling: Techniques and Tools
6.8 Rotor Performance Optimization: Methodologies and Algorithms
6.3 Rotor Design for Vibration Mitigation
6.4 Computational Fluid Dynamics (CFD) in Rotor Design
6.5 Structural and Dynamic Analysis of Rotors
6.6 Multi-Objective Optimization in Rotor Design
6.7 Validation and Verification of Rotor Models
6.8 Case Studies: Rotor Modeling and Optimization
7.8 Detailed Rotor Modeling: Methods and Techniques
7.8 Interaction Simulation Rotor-Fluid Interaction
7.3 Analysis of Rotor Vibration Response
7.4 Optimization of Rotor Design for Vibration Mitigation
7.5 Evaluation of Rotor Performance: Key Indicators
7.6 Impact of Operating Conditions on Rotor Performance
7.7 Software Tools for Rotor Modeling
7.8 Case Studies: Rotor Modeling and Performance
8.8 Modeling Rotor Performance: Approaches
8.8 Analysis of Rotor Vibration Response: Methods
8.3 Design and Optimization of Rotors for Vibration Mitigation
8.4 Analysis of Rotor-Fluid Interaction
8.5 Use of Simulation Software in Rotor Analysis
8.6 Validation and Verification of Rotor Models
8.7 Influence of Operating Conditions on Performance
8.8 Case Studies: Rotor Modeling and Analysis
9.9 Introduction to Vibration Mitigation in the Marine Sector
9.9 Relevant Legislation and Regulations
9.3 Types of Vibrations and Their Sources in Ships
9.4 Impact of Vibrations on Structural Integrity and Comfort
9.5 Principles of Damping Devices and Their Application
9.9 Design of Naval Structures for Vibration Reduction
9.9 Selection of Materials and Their Damping Properties
9.3 Design of Vibration Isolation Systems
9.4 Active and Passive Control Strategies
9.5 Integration of Advanced Technologies in Naval Design
3.9 Introduction to Rotor Analysis in Marine Applications
3.9 Rotor Modeling and Simulation
3.3 Modal and Frequency Response Analysis Techniques
3.4 Identification of Critical Vibration Modes
3.5 Design and Optimization of Rotors for Vibration Minimization
4.9 Evaluation of Rotor Performance in Ships
4.9 Vibration Data Analysis and Interpretation
4.3 Techniques for Improving Rotor Design
4.4 Testing and Trials on Naval Rotors
4.5 Rotor Optimization Case Studies
5.9 Application of Damping Solutions in Naval Environments
5.9 Integration of Damping Devices into the Ship Structure
5.3 Vibroacoustic Stability Analysis
5.4 Influence of Rotors on Vibroacoustic Stability
5.5 Design of Comprehensive Solutions for Naval Stability
6.9 Advanced Rotor Modeling for Marine Applications
6.9 Rotor Design Optimization Using Numerical Methods
6.3 Sensitivity Analysis and Robust Design
6.4 Design Considerations for Radiated Noise Reduction
6.5 Simulation of Rotor Behavior Under Different Conditions
7.9 Detailed Modeling of Rotors and Their Components
7.9 Vibration Analysis in Complex Rotors
7.3 Design of Rotors Optimized for Vibration Mitigation
7.4 Performance Evaluation of Different Rotor Designs
7.5 Advanced Modeling and Simulation Strategies
8.9 Rotor Analysis in the Context of the Industry Naval
8.9 Identifying the causes of vibration in rotors
8.3 Evaluating the service life of rotors
8.4 Designing and optimizing rotors for various naval applications
8.5 Implementing vibration mitigation solutions in the naval sector
9.9 Selecting and implementing vibration control systems
9.9 Designing and implementing dampers
9.3 Vibration mode analysis
9.4 Implementing vibration tests
9.5 Designing and implementing monitoring systems
9.6 Analyzing the effectiveness of the implemented solution
9.7 Case studies and best practices
9.8 Safety and regulatory compliance considerations
9.9 Cost-benefit analysis of implemented solutions
9.90 System maintenance and upgrades
1.1 Fundamentals of Vibration Mitigation in Naval Environments
1.2 Types of Vibrations and Their Impacts on Navigation
1.3 Damping Devices: Principles and Applications
1.4 Selection and Application of Damping Materials
1.5 Case Studies: Implementation of Damping Solutions on Ships
2.1 Naval Design: Considerations for Vibration Control
2.2 Advanced Damping Strategies in Naval Structures
2.3 Vibration Isolation Techniques
2.4 Vibration Modeling and Simulation in Naval Design
2.5 Practical Cases: Vibration Control in Different Types of Ships
3.1 Rotor Analysis: Fundamentals and Methods
3.2 Rotor Design for Vibration Reduction
3.3 Optimization of Rotor Geometry
3.4 Vibration Mode Analysis in Rotors
3.5 Practical Applications: Rotor Optimization in Marine Systems
4.1 Evaluation Rotor Performance: Methods and Techniques
4.2 Rotor Failure Diagnosis and Analysis
4.3 Strategies for Improving Rotor Performance
4.4 Evaluating the Effectiveness of Implemented Improvements
4.5 Case Studies: Improving Rotor Performance in Existing Vessels
5.1 Implementing Damping Solutions: Methodology
5.2 Vibroacoustic Analysis: Fundamentals and Applications
5.3 Integrating Damping Solutions and Rotor Design
5.4 Evaluating Naval Vibroacoustic Stability
5.5 Case Studies: Integrated Solutions for Vibroacoustic Stability
6.1 Advanced Rotor Modeling: Techniques and Tools
6.2 Rotor Performance Optimization: Algorithms and Methods
6.3 Sensitivity Analysis and Multi-Objective Optimization
6.4 Model Validation and Verification
6.5 Applications: Modeling and Optimization in Naval Design
7.1 In-depth Modeling of Rotors: Theory and Practice
7.2 Stress and Strain Analysis in Rotors
7.3 Advanced Rotor Optimization Techniques
7.4 Performance Evaluation Under Real-World Conditions
7.5 Case Studies: Vibration Mitigation in the Naval Sector
8.1 Rotor Modeling and Simulation Methodologies
8.2 Root Cause Analysis of Vibrations
8.3 Strategies for Effective Vibration Mitigation
8.4 Impact Evaluation of Implemented Improvements
8.5 Final Project: Implementation of Solutions in a Practical Case
8.1
- Hands-on methodology: test-before-you-trust, design reviews, failure analysis, compliance evidence.
- Software (depending on licenses/partners): MATLAB/Simulink, Python (NumPy/SciPy), OpenVSP, SU2/OpenFOAM, Nastran/Abaqus, AMESim/Modelica, acoustics tools, planning toolchains DO-178C.
- SEIUM Laboratories: scale rotor bench, vibrations/acoustics, EMC/Lightning pre-compliance, HIL/SIL for AFCS, data acquisition with strain gauging.
- Standards and compliance: EN 9100, 17025, ISO 27001, GDPR.
Proyectos tipo capstones
Admisiones, tasas y becas
- Profile: Background in Computer Engineering, Mathematics, Statistics, or related fields; practical experience in NLP and valued information retrieval systems.
- Documentation: Updated CV, academic transcript, SOP/statement of purpose, project examples or code (optional).
- Process: Application → Technical evaluation of profile and experience → Technical interview → Review of case studies → Final decision → Enrollment.
- Fees:
- Single payment: 10% discount.
- Payment in 3 installments: No fees; 30% upon registration + 2 equal monthly payments of the remaining 35%.
Monthly payment: available with a 7% commission on the total; annual review.
Scholarships: based on academic merit, financial need, and promoting inclusion; agreements with companies in the sector for partial or full scholarships.
See “Calendar & Calls for Applications,” “Scholarships & Grants,” and “Fees & Financing” in the SEIUM mega-menu.
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