A Master in Electromechanical Engineering is a multidisciplinary graduate program that blends principles from both electrical engineering and mechanical engineering, providing students with the skills to design, develop, and manage complex systems that involve both mechanical and electrical components. This program equips students with advanced knowledge in areas such as robotics, automation, energy systems, control systems, and machine design, preparing them to solve a wide range of engineering challenges in industries that require integrated systems.
| PROGRAMME |
SEMESTRE |
DURATION |
CREDIT |
PARTNER INSTITUTION |
ACCREDITATION |
| ELECTROMECHANICAL
ENGINEERING |
4 SEMESTERS |
2 YEARS |
120 |
UNIVERSITY OF BUEA |
|
CORE OBJECTIVES
1. Advanced Engineering Design and Analysis
- – CAD and CAE: Mastery of computer-aided design (CAD) and computer-aided engineering (CAE) tools for simulating mechanical systems.
- – Mechanical System Design: Applying principles of statics, dynamics, thermodynamics, and fluid mechanics to design mechanical components such as engines, robots, and HVAC systems.
- – Material Selection: Understanding the mechanical properties of materials to choose the right materials for specific applications.
2. Control Systems and Automation
- – Control Theory: Study of feedback systems, controllers, and stability analysis for mechanical systems such as robotics, automotive systems, and manufacturing equipment.
- – Automation and Robotics: Understanding of mechatronics, sensors, actuators, and their application in automated systems and robots.
- – Dynamic Systems: Modeling and control of dynamic mechanical systems in real-time for applications in manufacturing and automation.
3. Mechanical System Simulation and Optimization
- – Simulation Tools: Using tools like MATLAB, Simulink, and ANSYS for simulating mechanical systems and performing optimization tasks.
- – Design Optimization: Applying optimization techniques to improve the design of mechanical systems, considering parameters like weight, strength, and energy efficiency.
- – Multi-Disciplinary Design Optimization: Integrating various disciplines such as fluid dynamics, thermodynamics, and structural mechanics to achieve optimal mechanical system performance.
4. Research and Development
- – Industry-Specific Research: Engage in research projects related to specific industries such as automotive, aerospace, or renewable energy.
- – Innovation in Engineering: Pioneering new technologies and solutions in areas such as robotics, energy storage, and advanced materials.
- – Capstone Project: A final research project where students solve real-world engineering problems, demonstrating their ability to integrate knowledge from various areas of mechanical engineering.
