Mechanical Manufacturing and Production Engineering

Core Courses

Semester 1:

Continuum Mechanics: Deepening the fundamentals of continuum mechanics, including 3D modeling of elastic solid media.

Materials: Study of the properties of metallic materials, polymers, ceramics, and composites, and their applications in manufacturing.

Metal Cutting 1: Analysis of metal cutting phenomena, tool geometry, cutting forces, and power requirements.

Forming Processes: Techniques of forming by deformation, casting, forging, and stamping.

Machine Tools: Design and operation of machine tools used for part machining.

Industrial Robotics: Modeling, kinematics, and programming of industrial robots.

Metrology: Measurement and inspection techniques used in manufacturing to ensure product quality.

Practical Work in Mechanical Manufacturing: Hands-on training on machine tools and part fabrication with precision constraints.

Technical English and Terminology: Learning the technical vocabulary necessary to understand and write scientific and engineering documents in English.

Semester 2:

Finite Element Method (FEM): Application of FEM to solve mechanical problems in manufacturing.

Metal Cutting 2: Advanced study of machining, focusing on cutting tools and complex processes.

Machine Tool Components: In-depth study of the essential components of machine tools, their design, kinematics, and dynamics.

CNC Programming: Learning how to program CNC machines for the production of complex parts.

FEM Practical Work: Applying learned concepts using simulation software to solve engineering problems.

CAD/CAM Practical Work: Use of Computer-Aided Design and Manufacturing tools to design and simulate parts before fabrication.

Production Management: Methods for managing industrial processes to optimize production, logistics, and resources.

Optimization: Introduction to optimization methods (linear, non-linear, stochastic) for improving industrial processes.

Ethics and Standards Compliance: Awareness of industrial standards and ethical practices in the professional environment.

Semester 3:

Methods Office: Learning the methodologies used to define and optimize manufacturing processes in an industrial context.

Machining of Complex Surfaces: Analysis and machining techniques for producing complex surfaces on precision components.

High-Speed Machining: Study of rapid machining techniques, using high-speed machines to improve efficiency and accuracy.

Dynamics of Rotating Machines: Study of the dynamics of rotating machinery, including vibration effects and machine behavior under load.

Fracture and Fatigue Mechanics: Study of material failure under cyclic loading and fatigue behavior.

Practical Work – Methods Office: Practical applications of process planning and optimization in an industrial setting.

Advanced High-Speed Machining: Deepening of advanced techniques for machining complex parts using high-speed equipment.

Advanced Topics

The program covers advanced topics in the field of manufacturing and production engineering:

High-Speed Machining (HSM): Learning advanced techniques for rapid and precision machining.

Advanced Industrial Robotics: Use of collaborative robots (cobots) and robot programming for complex production applications.

Optimization of Industrial Processes: Continuous improvement of manufacturing processes to maximize efficiency and reduce costs.

Dynamics of Machines and Vibration Analysis: Study of vibrations in industrial machines and their impact on production quality.

Fracture and Fatigue Mechanics: Study of the resistance of materials subjected to repeated loading and its effect on component lifespan.

Final-Year Projects and Internships: Practical application of the knowledge and skills acquired throughout the program.