Electromechanical Engineering is an interdisciplinary field that combines mechanical engineering and electrical and electronic engineering. This specialization aims to design, develop and maintain systems and devices that rely on the interaction between electrical and mechanical components. This specialization is essential in a wide range of industries including manufacturing, energy, automotive, aerospace, and robotics. Here’s a comprehensive look at the main aspects of the electromechanical engineering major:

Electrical and electronic basics:

• Study the basic principles of electrical circuits and electronic components such as resistors, capacitors, and coils.
• Understand how to design and analyze electronic circuits and electrical systems.

Mechanical basics:

• Study mechanics of materials, thermodynamics, and fluid mechanics.
• Understand the design and analysis of mechanical systems including machines and engines.

Automated control and control systems:

• Study of control theory and design of automatic control systems.
• Applications of control systems in industrial processes and robotics.

Instrumentation and sensor:

• Study of technologies and sensors used in electromechanical systems.
• Develop skills in using sensors to improve the accuracy and performance of systems.

Modeling and simulation:

• Using software and mathematical models to simulate electromechanical systems.
• Analyze data from simulations to improve the design and manufacturing of systems.

Computer Aided Design (CAD) and Computer Aided Manufacturing (CAM):

• Learn how to use CAD tools to design electromechanical components.
• Applying CAM techniques in manufacturing processes to improve efficiency and quality.

Power systems and engines:

• Study the design and operation of power systems such as electric, hydraulic and pneumatic motors.
• Understand how to improve energy efficiency in electromechanical systems.

Robotics and automation:

• Design and development of robots and automatic systems that combine electrical and mechanical components.
• Study applications of robotics in manufacturing, medicine, and logistics.

Micromechanics and Micro instrumentation:

• Study the design and manufacture of precision components and devices used in medical and electronic applications.
• Understand micro manufacturing techniques and their applications.

Advanced electromechanical systems:

• Study of modern technologies such as 3D printing, Internet of Things (IoT), and artificial intelligence in developing electromechanical systems.
• Apply these techniques to improve performance and expand the capabilities of electromechanical systems.

Professional ethics and practices:

• Understand ethical and professional issues in electromechanical engineering.
• Adherence to engineering standards and laws to ensure the safety and quality of projects.

Practical training and applied projects:

• Obtain practical experience through training in engineering companies and projects.
• Apply theoretical knowledge in real business environments to develop practical and effective solutions.

Research and development:

• Participate in research and development projects to improve electromechanical technologies and systems.
• Publishing research and participating in scientific conferences to share results and innovations.

The Electromechanical Engineering major provides broad opportunities to work in multiple fields such as manufacturing, energy, transportation, aerospace, healthcare, and robotics. This major contributes to the development of technology and improvement of electromechanical systems, enhancing efficiency and innovation in a variety of industries.