Control Engineering S6 |
6 |
Introduction to Control Theory |
1. Introduction to continuous Linear Time-Invariant (LTI) systems 2. Mathematical models of LTI systems 3. Block diagram and the reduction rules 4. Time-domain analysis of a first order system 5. Time domain analysis of a second order system 6. PID controllers for TLI systems
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Lectures : 14h00 |
Tutorials : 10h00 |
Lab Work : 8h00 |
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Electrical Machine & Drives |
This course covers the basic characteristics of DC and AC motors and describe their principle of operation and control within a power electronic environment. Basics in power electronics, electric machines and control circuits are reviewed and the overall systems is studied. Control techniques for DC drives are underlined and the four-quadrant operation is analysed. Control strategies for AC drives are discussed as well, mainly the scalar control, the field oriented control and the direct torque control. Detailed modelling of the control of induction motors using the FOC method is carried out. |
Lectures : 8h00 |
Tutorials : 6h00 |
Lab Work : 4h00 |
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Energy Engineering Courses S6 |
8 |
Advanced Heat Transfer |
12 hours (lecture), 12 hours (tutorial), 12 hours (Practical Work) - Steady Heat conduction : heat transfer in common configuration, conduction shape factors. - Transient conduction : lumped system analysis, Biot number, transient heat conduction in large plane walls, long cylinders, and spheres with spatial effects, transient heat conduction in semi-infinite solids. - Numerical methods in heat conduction : finite difference formulation of differential equations, two-dimensional steady heat conduction. - Natural convection : physical mechanisms, equation of motion and the grashof number, natural convection over surfaces, natural convection inside enclosures, combined natural and forced convection. - Boiling and condensation : boiling heat transfer, pool Boiling, flow boiling, condensation heat transfer, film condensation, dropwise condensation - Heat exchangers : heat exchanger types, overall heat transfer coefficient, the log mean temperature difference, the effectiveness-NTU method, heat exchanger design and performance calculations. - Radiation heat transfer : the view factor, view factor relations, black surfaces, diffuse and gray surfaces, radiation shields and the radiation effect.
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Lectures : 12h00 |
Tutorials : 12h00 |
Lab Work : 12h00 |
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Heating, Ventilation and Air Conditioning HVAC |
The purpose of this course is to deeply understand Heat, Ventilation and Air Conditioning technologies and their importance in the building and industry sectors (buildings energy consumption, thermal comfort, ...) and to manage to size and optimize and HVAC system. The course addresses also the future of the HVAC&R industry (EU F-Gas regulation, use of new refrigerant fluids, improvement of energy efficiencies, etc.). course content (10h of lectures + 10h of tutorials ) • Introduction to HVAC (Importance of HVAC processes in our current society, cold production, cold chain management, energy consumption, environmental consequences) and classic mechanical refrigeration • Different Refrigeration technologies, and their performance (specificities and comparison) • Heat pumps specificities and performance (different heating technologies) • Humid air: Psychrometrics and thermodynamics of moist air. • Air Handling Units for air conditioning (components and technology evolution) Labs: (12h) Study of a volumetric compressor of a refrigerating machine Study of a refrigeration machine with a water secondary circuit Study of an Air Handling Unit with a recycling option |
Lectures : 10h00 |
Tutorials : 10h00 |
Lab Work : 12h00 |
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Hydraulics |
- Minor (/ local) and major (/ friction) head losses formulations for viscous flows - Presentation of head losses adding (/ coupling) laws: series coupling and parallel coupling head losses – Presentation of Electrical analogy and drawing of network characteristic curve - Study of hydraulic networks and sizing of pumping systems and hydroelectric energy setups. Implementations of Generalized Bernoulli equation – Duty/operation point concept: selection of a pumping system adapted to a required flow rate in an existing hydraulic network - Pump curve, Affinity laws, parallel and series operation - Modification of the operating point - NPSH and cavitation (available and required NPSH) - Basics of Fluid power: generation, distribution, deployment, and regulation systems
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Lectures : 8h00 |
Tutorials : 12h00 |
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System Engineering S6 |
3 |
Quality |
Introduction to Quality, its history and evolution. Learn about quality management with the main tools related to it. Analysis and understanding of the ISO 9001 standard, its purpose, context and stakes. Audit: Preparing and conducting an Audit. QRQC : Operational method of quality management and problem solving. Discovery and appropriation of A3 and Kanban communication tools. Experience plan: Initiation to the PEX tool, mathematical approach and method.
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Lectures : 8h00 |
Tutorials : 10h00 |
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Vibrations |
The presentation of the relations between the physical properties of a mechanical system and its vibratory behavior is carried out in the form of lectures on the following points:
1 - Vibration of a system with one degree of freedom: Conservative System: Free Movement - Clean Pulsation - Kinetic Energy and Deformation Energy. Non-conservative system: Viscous damping model - Frequency response - Resonance.
2 - Vibrations of discrete systems with n degrees of freedom: Modes of vibration - Calculation of modal characteristics - Decoupling of equations of motion - Proportional damping model - Modal superposition - Frequency response - Experimental modal analysis.
3 - Vibration reduction methodology: Vibration isolation - Modification of a natural frequency - Increase of the damping - Use of a dynamic dampener granted
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Lectures : 12h00 |
Tutorials : 8h00 |
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Industrial and Supply Chain Management Courses S6 |
8 |
Introduction to the Industrial & Supply Chain Project Management |
- Project management introduction : Organization of a project team, Project and planning management software - Ergonomy, Health and Security at work - Creativity and Problem Solving Methodology - To know the main global performance indicators (Overall Equipment Effectiveness, ...) - The Fresh Connection: serious game in a web-based simulation - Inventory Management: Define and manage the economic quantity, the safety stock and the stock classification - Approach of Inventory Management - Knowledge in Financial Management in industries |
Lectures : 8h00 |
Tutorials : 16h00 |
Project : 16h00 |
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Introduction to Product/Process Link & Related Design |
• To study process flows before implementation of a manufacturing plant • Workstation analysis, determination and optimization of times • Design, methods and tools for industrialization • Exploring the challenges facing Total Productive Maintenance • Analysis & specifications of product • Being able to define standard documents • To understand the types and levels of maintenance • Establish a simple version of the maintenance plan • Flow simulation with FLEXSIM |
Lectures : 12h00 |
Tutorials : 24h00 |
Project : 16h00 |
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Mathematics for Engineering S6 |
6 |
Mathematics for Engineers 6 |
Introduction to statistics and probability - Graphical Tools to represent data Meaningful Values Probability Theory Common Discrete and Continuous Probability Distributions Convergence Theorems Sampling Estimations and Confidence intervals Statistical Tests Comparison of Normal Distributions Normality Assumption checking Homogeneity of a population: ANOVA Chi-Square test Correlation and linear regression
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Lectures : 16h00 |
Tutorials : 16h00 |
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Object-Oriented Programming |
Basics of Java Introduction to Object Oriented Programming Classes and Methods Inheritance Standard Library of Java |
Lectures : 6h00 |
Tutorials : 12h00 |
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Mechanical Design Engineering Courses S6 |
8 |
Advanced Heat Transfer (Mechanical Pathway) |
12 hours (lecture), 12 hours (tutorial) - Steady Heat conduction : heat transfer in common configuration, conduction shape factors. - Transient conduction : lumped system analysis, Biot number, transient heat conduction in large plane walls, long cylinders, and spheres with spatial effects, transient heat conduction in semi-infinite solids. - Numerical methods in heat conduction : finite difference formulation of differential equations, two-dimensional steady heat conduction. - Natural convection : physical mechanisms, equation of motion and the grashof number, natural convection over surfaces, natural convection inside enclosures, combined natural and forced convection. - Boiling and condensation : boiling heat transfer, pool Boiling, flow boiling, condensation heat transfer, film condensation, dropwise condensation - Heat exchangers : heat exchanger types, overall heat transfer coefficient, the log mean temperature difference, the effectiveness-NTU method, heat exchanger design and performance calculations. - Radiation heat transfer : the view factor, view factor relations, black surfaces, diffuse and gray surfaces, radiation shields and the radiation effect.
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Lectures : 12h00 |
Tutorials : 12h00 |
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Heating, Ventilation and Air Conditioning HVAC (Mechanical Pathway) |
The purpose of this course is to deeply understand Heat, Ventilation and Air Conditioning technologies and their importance in the building and industry sectors (buildings energy consumption, thermal comfort, ...) and to manage to size and optimize and HVAC system. The course addresses also the future of the HVAC&R industry (EU F-Gas regulation, use of new refrigerant fluids, improvement of energy efficiencies, etc.). course content (10h of lectures + 10h of tutorials ) • Introduction to HVAC (Importance of HVAC processes in our current society, cold production, cold chain management, energy consumption, environmental consequences) and classic mechanical refrigeration • Different Refrigeration technologies, and their performance (specificities and comparison) • Heat pumps specificities and performance (different heating technologies) • Humid air: Psychrometrics and thermodynamics of moist air. • Air Handling Units for air conditioning (components and technology evolution) Labs: (12h) Study of a volumetric compressor of a refrigerating machine Study of a refrigeration machine with a water secondary circuit Study of an Air Handling Unit with a recycling option
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Lectures : 10h00 |
Tutorials : 10h00 |
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Hydraulics (Mechanical Pathway) |
- Minor (/ local) and major (/ friction) head losses formulations for viscous flows - Presentation of head losses adding (/ coupling) laws: series coupling and parallel coupling head losses – Presentation of Electrical analogy and drawing of network characteristic curve - Study of hydraulic networks and sizing of pumping systems and hydroelectric energy setups. Implementations of Generalized Bernoulli equation – Duty/operation point concept: selection of a pumping system adapted to a required flow rate in an existing hydraulic network - Pump curve, Affinity laws, parallel and series operation - Modification of the operating point - NPSH and cavitation (available and required NPSH) - Basics of Fluid power: generation, distribution, deployment, and regulation systems
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Lectures : 8h00 |
Tutorials : 12h00 |
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Materials 3 |
1. Introduction to Phase Transformation • Processes and Types of Phase Transformation • Types of Nucleation • Phase Transformation Rate 2. Part 1: Heat Treatment • Equilibrium and Non-equilibrium States • Eutectoid, Hypereutectoid and Hypoeutectoid Points • Martensite Transformation 3. Part 2: Heat Treatment • Mechanical Properties of Martensite • Tempering of Steel Alloys • Continuous Cooling Transformation Diagrams 4. Structural Hardening of Aluminum • Equilibrium Diagram of Aluminum Alloys • Heat Treatments of Aluminum Alloys 5. Corrosion • Redox Reactions • Types of Corrosion • Methods for Corrosion Prevention
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Lectures : 10h00 |
Tutorials : 10h00 |
Lab Work : 12h00 |
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Multidisciplinary Project S6 |
10 |
Ecodesign Project Part 2 - Environment |
The project contains 3 expected content types: courses & tutorials, project sessions (labs), and personal work. For each semester, this projects represents ~40h of work on-site + 20h-30h of personal work. The total workload for each semester is estimated to 60- 70h/student.
Content of semester 6: 1. Courses & tutorials: Ecodesign approaches and strategies. - Courses topics: Ecodesign regulations & strategies, Materials & environment, Design for Sustainable behaviour, Thermal insulation & downsizing, Ecodesign of packaging, design for End-of-life, Innovation for ecodesign. - Tutorials: CES EduPack (choice of materials), Simapro, CREO (CAD modelling) 2. Project sessions (labs) supervised by the teacher: Developing 3 levels of ecodesigned solutions - Solutions developments: calculations, CAD modelling, LCA modelling of the 3 levels 3. Personal work: information search, interpretation of LCA results. |
Lectures : 5h00 |
Tutorials : 3h00 |
Project : 8h00 |
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Ecodesign Project Part 2 - Technical |
The project contains 3 expected content types: courses & tutorials, project sessions (labs), and personal work. For each semester, this projects represents ~40h of work on-site + 20h-30h of personal work. The total workload for each semester is estimated to 60- 70h/student.
Content of semester 6: 1. Courses & tutorials: Ecodesign approaches and strategies. - Courses topics: Ecodesign regulations & strategies, Materials & environment, Design for Sustainable behaviour, Thermal insulation & downsizing, Ecodesign of packaging, design for End-of-life, Innovation for ecodesign. - Tutorials: CES EduPack (choice of materials), Simapro, CREO (CAD modelling) 2. Project sessions (labs) supervised by the teacher: Developing 3 levels of ecodesigned solutions - Solutions developments: calculations, CAD modelling, LCA modelling of the 3 levels 3. Personal work: information search, interpretation of LCA results. |
Lectures : 3h00 |
Tutorials : 1h00 |
Project : 8h00 |
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Professional and Personal Development S6 |
4 |
Advanced English Skills 6 |
The Advanced English Skills modules aim to have students develop their language skills across a wide range of topics, often consolidating material from other modules. Proect management Team work Working with deadlines Managing gateways Running effective meetings - creating an agenda, time management, report etc.
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Cultural Awareness 2 (Art - Literature - Music - Cinema) |
This module gives students the opportunity to choose a field in the social sciences in which they are interested. An individual syllabus is established for each course. Therefore, the learning outcomes differ between subjects. |
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French as a Foreign Language |
6 hour lessons every week : 4h face-to-face +2h guided autonomy Expanded vocabulary Introduction of grammar points Improvement of phonological control
A1 Can establish basic social contact by using the simplest everyday polite forms of: greetings and farewells; introductions; saying please, thank you, sorry etc.
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Optional Foreign Language |
1.5 hour lessons every week. Expanded vocabulary Revision of grammar points Improvement of phonological control
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Principles of Marketing |
This course is designed to provide with students with an introduction to the marketing system. They will be exposed to the major concepts of marketing known as the marketing mix or 4 P's (product, place, price, and promotion). The course presumes no prior understanding of marketing, provides a complete overview of the marketing process, and touches on a variety of topics. Students will gain a sound understanding of the core concepts in marketing and its role in business and consumers' lives. |
Lectures : 6h00 |
Tutorials : 12h00 |
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Robotics & IT Courses S6 |
8 |
Introduction to Robotics |
-Introduction to robotic systems and controllers -Robots in their contexts -Mechanical structures: serial and parallel robots, mobile robots -Forward, Inverse and Differential Kinematics for Robot Arm -Differential Drive robots -Motion planning for mobile robot (Dijkstra, A*) -Practical introduction to robot programming (mBot, poppy)
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Lectures : 10h00 |
Tutorials : 12h00 |
Lab Work : 8h00 |
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Sensing & Perception |
-Inertial sensors, GPS and odometry / sonar sensing / vision, bio-inspired sensors, force sensors -Transformation of information into electric properties and its implication -Signal conditioning -ADC: sampling, quantization, windowing -MCU: Application of data acquisition, data analysis, data processing -Introduction to image processing
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Lectures : 8h00 |
Tutorials : 4h00 |
Lab Work : 12h00 |
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Signal Processing + Wireless Communications |
-Signals: general properties and transformations (convolution…) -Spectral analysis (DFT, FFT…) -Sampling -Signals and systems (stability, causality…) -Filters (FIR, IIR) -Random signals (autocorrelation, intercorrelation…) -Time-frequency analysis -Image processing
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Lectures : 12h00 |
Tutorials : 12h00 |
Lab Work : 8h00 |
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Students Life Commitment |
3 |
Students Life Commitment Sem 6 |
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Students Life Involvement |
2 |
Students Life Involvement Sem 6 |
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