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Establishment
Teaching content
Energetics
Training officer(s)
M.LAHOUBI
Stakeholder(s)
M.LAHOUBI
Présentation
Prerequisite
Knowledge acquired during the preparatory classes
- Knowledge of operators and basics of vector analysis
- Perfect knowledge of the double and triple integrals, partial differential equations, differential and matrix calculation, units
- Knowledge of operators and basics of vector analysis
- Perfect knowledge of the double and triple integrals, partial differential equations, differential and matrix calculation, units
Goal
The goal of this course is to provide students with the knowledge required to understand the main concepts of Energetic Science.
Presentation
- Fluid properties (density, pressure, temperature, fluid flow, surface tension, viscosity …)
- Kinematics of fluids
- Fluid statics
- Static equations in Fluid mechanics, Pascal’s law, pressure measurement, force calculation on an immersed wall or bodies
- Dynamics of non-viscous fluids
- Equations of dynamics of non-viscous fluids, Bernoulli’s law, energy equation
- Practical application of Bernoulli’s law (speed measurement, tank discharge)
- Linear momentum equation (exposition and application to stress calculation against obstacles)
- Introduction to dynamics of real fluids
- Reynolds numbers : introduction to the concept of turbulence
- Laminar flow, Turbulent flow while proceeding in a particular direction, introduction to head losses
- Measurement in fluid mechanics (pressure, flow, speed …)
- Introduction to aerodynamics
- Kinematics of fluids
- Fluid statics
- Static equations in Fluid mechanics, Pascal’s law, pressure measurement, force calculation on an immersed wall or bodies
- Dynamics of non-viscous fluids
- Equations of dynamics of non-viscous fluids, Bernoulli’s law, energy equation
- Practical application of Bernoulli’s law (speed measurement, tank discharge)
- Linear momentum equation (exposition and application to stress calculation against obstacles)
- Introduction to dynamics of real fluids
- Reynolds numbers : introduction to the concept of turbulence
- Laminar flow, Turbulent flow while proceeding in a particular direction, introduction to head losses
- Measurement in fluid mechanics (pressure, flow, speed …)
- Introduction to aerodynamics
Modalités
Forms of instruction
- Courses
- Discovery Practical work : to be held prior to the beginning of the fluid mechanics module, this practical work sessions will be the opportunity for students to discover the tools and vocabulary used in fluid mechanic
Organization
| Type | Amount of time | Comment | |
|---|---|---|---|
| Face to face | |||
| Lecture | 24,00 | ||
| Lab | 4,00 | ||
| Independent study | |||
| Estimated personal study time | 8,00 | ||
| Overall student workload | 36,00 | ||
Evaluation
- Written test
Ressources
Bibliography
Mécanique expérimentale des fluides. Statique et dynamique des fluides non visqueux - R. Comolet
tome 1. Paris : Masson, 2002
Fluid Mechanics - F.M. WhiteNew York : McGraw-Hill Education, 2004
Fluid mechanics - J.F. Douglas, J.M.K. Gasiorek, J.A. Swaffield5e éd. Londres : Prentice Hall, 2005
Introduction to Fluid Mechanics - R.W. FoxNew York : John Wiley & Sons, 1998