Core Courses
The core curriculum of the program spans six semesters and focuses on building strong foundations in mathematics, physics, and engineering principles, then gradually specializes in energy systems.
- In Semesters 1 and 2, students study fundamental subjects such as Mathematics, Physics, and Thermodynamics, as well as Structure of Matter. These courses are designed to level studentsβ knowledge and introduce them to the basic concepts in mechanics, chemistry, and energy.
- In Semester 3, the focus shifts to applied topics including Fluid Mechanics, Rational Mechanics, Waves and Vibrations, and advanced Mathematics. These prepare students for understanding physical systems related to energy flow and dynamics.
- Semester 4 introduces Thermodynamics 2, Mechanical Manufacturing, Numerical Methods, Strength of Materials, and Mathematics 4, which deepen students' technical knowledge and analytical skills.
- In Semester 5, students explore specialized energy subjects like Fluid Mechanics 2, Heat Transfer 1, Turbomachines 1, and Energy Conversion. These courses connect theoretical knowledge with practical applications in energy systems.
- Finally, Semester 6 covers advanced topics such as Turbomachines 2, Internal Combustion Engines, Refrigeration and Heat Pumps, and Heat Transfer 2, equipping students to handle real-world problems in various energy-related industries.
Advanced Topics
π Semester 5 β Advanced Topics
- Fluid Mechanics 2
- Explores complex fluid behavior including viscous flows and flow in pipes β essential for designing energy systems like pipelines and HVAC networks.
- Heat Transfer 1
- Introduces the three modes of heat transfer: conduction, convection, and radiation, with applications in thermal system design.
- Turbomachines 1
- Covers the working principles and performance of pumps, compressors, and turbines, which are core components in power plants and aircraft engines.
- Energy Conversion
- Focuses on transforming energy from one form to another β such as mechanical to electrical β with emphasis on power plant cycles and efficiency.
- Measurement and Instrumentation
- Teaches how to measure physical quantities (temperature, pressure, flow) and introduces instruments used in energy systems monitoring.
π Semester 6 β Advanced Topics
- Turbomachines 2
- Builds on Semester 5 to analyze advanced flow behavior, performance curves, and design aspects of rotating machines.
- Internal Combustion Engines
- Studies spark-ignition and compression-ignition engines, focusing on thermodynamic cycles, emissions, and engine performance.
- Refrigeration and Heat Pumps
- Explores thermodynamic cycles for cooling systems, air conditioners, and heat pumps, crucial in both industry and domestic applications.
- Heat Transfer 2
- Advances the concepts from the first course with a focus on heat exchangers, thermal modeling, and real-world applications.
- Renewable Energies
- Provides an overview of solar, wind, geothermal, and bioenergy systems, including their integration and environmental impact.
- Cryogenics
- Studies the production and application of very low temperatures, especially relevant in liquefaction of gases and space technology.
- Final Year Project (Projet de Fin de Cycle)
- A capstone project that requires students to solve a practical or theoretical energy engineering problem, often in collaboration with industry or research labs.
These advanced topics ensure that graduates are well-prepared to work in energy production, thermal systems, renewable technologies, and mechanical industries, or to pursue a Masterβs degree.