ICTQual AB Level 6 International Diploma in Marine and Naval Engineering

Upon successful completion of the ICTQual AB Level 6 International Diploma in Marine and Naval Engineering, learners will be able to:

Year 1 – Foundation in Marine and Naval Engineering

Principles of Marine and Naval Engineering

• Understand the fundamentals of marine and naval engineering principles.
• Analyze ship systems, components, and marine machinery.
• Apply engineering concepts to maritime design and operations.
• Develop awareness of industry standards and best practices.
• Demonstrate foundational problem-solving in marine engineering contexts.

Engineering Mathematics

• Apply mathematical techniques to solve engineering problems.
• Use algebra, calculus, and statistics in marine engineering scenarios.
• Model engineering systems for analysis and design.
• Develop numerical and analytical skills for technical decision-making.
• Interpret mathematical results to support engineering solutions.

Fundamentals of Mechanical and Electrical Engineering

• Understand mechanical and electrical systems in maritime applications.
• Analyze energy transfer, power systems, and mechanical components.
• Apply basic engineering principles to ship machinery and equipment.
• Identify electrical circuits and control systems in marine contexts.
• Solve fundamental engineering problems using theoretical and practical knowledge.

Materials Science and Engineering

• Understand the properties and behavior of engineering materials in maritime environments.
• Select appropriate materials for ship structures, machinery, and components.
• Analyze material performance under stress, corrosion, and fatigue.
• Apply material science principles in marine and naval engineering design.
• Evaluate innovative materials for sustainability and performance.

Engineering Drawing and Computer-Aided Design (CAD)

• Create technical drawings for ship structures and marine components.
• Use CAD software to model mechanical and naval systems.
• Interpret engineering schematics and technical documentation.
• Apply geometric and dimensional analysis to design processes.
• Develop practical skills for professional maritime engineering projects.

Introduction to Fluid Mechanics and Hydrodynamics

• Understand fluid behavior and hydrodynamics principles in marine systems.
• Analyze fluid flow in propulsion and ship systems.
• Apply theoretical concepts to maritime vessel design and stability.
• Use fluid mechanics to optimize ship performance.
• Evaluate real-world maritime engineering problems using hydrodynamic principles.

Basics of Marine Propulsion Systems

• Understand types of marine propulsion systems and their operations.
• Analyze performance parameters for engines, turbines, and propellers.
• Evaluate energy efficiency and operational effectiveness.
• Apply propulsion principles to ship design and maintenance.
• Develop foundational skills for advanced marine propulsion studies.

Naval Architecture – Fundamentals

• Understand ship geometry, design, and structural requirements.
• Analyze ship stability, buoyancy, and weight distribution.
• Apply naval architecture principles to practical marine projects.
• Evaluate safety and regulatory compliance for vessel design.
• Develop analytical and modeling skills for ship design.

Marine Structures and Ship Construction

• Understand principles of shipbuilding and structural integrity.
• Analyze load-bearing structures and hull designs.
• Apply construction techniques to ship and offshore structures.
• Evaluate material selection and fabrication methods.
• Develop hands-on skills for marine structural projects.

Health, Safety, and Environmental Practices in Maritime Engineering

• Apply maritime safety standards and best practices.
• Identify hazards and implement risk mitigation strategies.
• Understand environmental regulations in marine operations.
• Develop protocols for emergency response and workplace safety.
• Promote sustainability and ethical engineering practices.

Communication and Technical Report Writing

• Develop professional communication skills for marine engineering contexts.
• Write technical reports, manuals, and project documentation.
• Present complex information clearly and concisely.
• Use visual aids and data effectively in reporting.
• Enhance collaboration and stakeholder communication skills.

Introduction to Project Management in Engineering

• Understand principles of project planning, scheduling, and resource allocation.
• Apply project management techniques to marine and naval projects.
• Analyze project risks, budgets, and timelines.
• Develop leadership and teamwork skills in engineering projects.
• Use project management tools to monitor and evaluate performance.

Year 2 – Intermediate Studies in Marine and Naval Engineering

Marine Hydrodynamics and Stability

• Analyze ship stability, buoyancy, and trim under various loading conditions.
• Apply hydrodynamics principles to vessel design and performance.
• Evaluate forces acting on marine structures in dynamic conditions.
• Utilize computational methods to assess stability and resistance.
• Develop practical problem-solving skills in naval architecture.

Marine Propulsion and Power Systems

• Understand advanced marine propulsion methods and power generation.
• Analyze efficiency, performance, and operational characteristics of engines.
• Evaluate alternative propulsion technologies for sustainability.
• Apply power system knowledge to real-world ship operations.
• Develop skills in optimizing energy use and marine performance.

Structural Analysis and Ship Design

• Apply structural engineering principles to ship hulls and marine systems.
• Analyze stress, strain, and load distribution in marine structures.
• Design components to meet safety, durability, and operational standards.
• Use modeling tools for ship structural evaluation.
• Develop critical thinking for structural problem-solving in marine projects.

Offshore and Coastal Engineering – Fundamentals

• Understand engineering principles for offshore structures and coastal projects.
• Analyze wave, current, and tidal forces impacting structures.
• Apply design methods for offshore platforms and coastal defenses.
• Evaluate environmental impact and sustainability in coastal engineering.
• Develop practical skills in planning and construction of offshore projects.

Marine Electrical and Control Systems

• Understand shipboard electrical systems, instrumentation, and automation.
• Analyze electrical distribution, control, and monitoring systems.
• Apply electrical engineering concepts to marine vessels.
• Develop troubleshooting and maintenance skills for onboard systems.
• Ensure compliance with safety and regulatory standards in marine electrical systems.

Materials and Corrosion in Marine Environments

• Evaluate material selection for durability and corrosion resistance.
• Understand chemical and mechanical factors affecting marine materials.
• Apply corrosion prevention and maintenance strategies.
• Analyze failure modes in marine components.
• Promote sustainable and long-lasting engineering solutions.

Marine Maintenance and Reliability Engineering

• Implement maintenance planning for ships and naval systems.
• Analyze reliability, failure rates, and performance metrics.
• Apply predictive and preventive maintenance techniques.
• Develop strategies to enhance operational efficiency and reduce downtime.
• Evaluate maintenance protocols to comply with industry standards.

Computational Methods in Naval Architecture

• Apply numerical methods for ship design and analysis.
• Utilize simulation software to model hydrodynamics and structural performance.
• Analyze results to optimize vessel stability and performance.
• Develop skills in computational tools for marine engineering projects.
• Integrate computational methods into practical naval design applications.

Sustainable Maritime Engineering and Green Technologies

• Understand sustainability principles in marine and naval engineering.
• Evaluate green technologies for ships and offshore structures.
• Apply energy-efficient and environmentally-friendly engineering practices.
• Develop strategies for reducing emissions and environmental impact.
• Promote long-term sustainability in maritime operations.

Applied Research Methods in Marine Engineering

• Conduct research and data analysis in marine engineering contexts.
• Develop critical thinking and problem-solving skills.
• Apply research findings to practical engineering challenges.
• Prepare professional technical reports and presentations.
• Integrate research methodologies into innovation and design projects.

Port and Harbour Engineering – Basics

• Understand planning, design, and operations of ports and harbours.
• Analyze marine infrastructure and navigation requirements.
• Apply civil and structural engineering principles to port facilities.
• Develop solutions for safe and efficient maritime operations.
• Evaluate environmental and regulatory compliance in port engineering.

Project Planning and Marine Operations Management

• Plan, schedule, and manage maritime projects effectively.
• Apply resource allocation and risk management techniques.
• Develop operational strategies for marine engineering projects.
• Enhance leadership and team coordination skills.
• Monitor and evaluate project performance to meet objectives.

Year 3 – Advanced Studies in Marine and Naval Engineering

Advanced Ship Design and Modelling

• Design advanced ship structures using modeling and simulation tools.
• Optimize hull design, stability, and performance metrics.
• Apply advanced naval architecture principles to complex vessels.
• Develop critical problem-solving and innovation skills in ship design.
• Evaluate design solutions against industry standards and safety regulations.

Advanced Propulsion and Power Plant Systems

• Analyze advanced propulsion technologies and power plant systems.
• Evaluate efficiency, environmental impact, and operational reliability.
• Apply design and operational principles for high-performance marine systems.
• Develop troubleshooting and optimization strategies for propulsion units.
• Integrate propulsion knowledge into sustainable maritime solutions.

Offshore Structures and Subsea Engineering

• Design and analyze offshore platforms, subsea pipelines, and structures.
• Evaluate environmental loads and structural integrity in harsh marine conditions.
• Apply engineering principles for installation, maintenance, and safety.
• Develop innovative solutions for deep-sea and offshore operations.
• Ensure compliance with international offshore engineering standards.

Advanced Hydrodynamics and Computational Fluid Dynamics (CFD)

• Apply CFD techniques for analyzing fluid flow around vessels and structures.
• Optimize ship hulls and offshore systems for performance and efficiency.
• Conduct simulations to predict real-world hydrodynamic behavior.
• Integrate CFD results into practical design and operational decisions.
• Develop advanced analytical and modeling skills in marine engineering.

Naval Defence Systems and Military Applications

• Understand design and operation of naval defense vessels and systems.
• Analyze weapon systems, communication, and electronic warfare technologies.
• Apply engineering principles for military-grade maritime applications.
• Evaluate strategic, safety, and operational requirements in naval defense.
• Develop problem-solving skills for complex defense engineering challenges.

Smart Marine Technologies and Industry 4.0

• Integrate IoT, automation, and smart technologies in marine systems.
• Optimize ship operations through digital monitoring and predictive analytics.
• Apply Industry 4.0 principles to enhance safety and efficiency.
• Evaluate emerging technologies for modern maritime applications.
• Develop innovation skills for intelligent ship and port systems.

Robotics and Autonomous Systems in Maritime Engineering

• Understand autonomous marine vehicles and robotic systems.
• Design and implement automated monitoring and control solutions.
• Analyze performance and safety of autonomous marine operations.
• Apply robotics for inspection, maintenance, and offshore operations.
• Develop skills in cutting-edge autonomous maritime technologies.

Cyber-Physical Systems and IoT in Marine Engineering

• Integrate cyber-physical systems into ship and offshore operations.
• Use IoT for monitoring, data collection, and predictive maintenance.
• Ensure cybersecurity and operational safety in marine systems.
• Develop innovative solutions for connected maritime operations.
• Apply smart technology to enhance efficiency and reliability.

Professional Ethics and Sustainability in Marine & Naval Engineering

• Apply ethical principles in marine engineering practices.
• Evaluate sustainability and environmental impact of engineering projects.
• Promote responsible decision-making in design and operations.
• Ensure compliance with international maritime codes and standards.
• Develop leadership skills with a focus on ethical engineering.

Innovation and Entrepreneurship in Marine Technology

• Identify opportunities for innovation in maritime engineering.
• Develop business and entrepreneurial skills for marine technology ventures.
• Apply research and design thinking to create viable solutions.
• Understand market needs and commercial applications of marine innovations.
• Develop strategies to implement sustainable marine business solutions.

Infrastructure and Facility Planning for Maritime Systems

• Plan, design, and manage port, shipyard, and offshore infrastructure.
• Evaluate layout, logistics, and operational efficiency of maritime facilities.
• Apply project management principles to complex infrastructure projects.
• Ensure compliance with safety, environmental, and regulatory standards.
• Develop strategic planning and problem-solving skills for maritime systems.

Final Year Major Project (Capstone Project)

• Integrate theoretical and practical knowledge into a comprehensive project.
• Conduct research, design, and implementation of a marine engineering solution.
• Demonstrate project management, technical, and analytical skills.
• Prepare professional documentation and presentations of project outcomes.
• Showcase readiness for professional practice and industry challenges.