Formation ECAM LaSalle Ingénieur spécialité Mécanique et Génie Electrique (ENGINEERING PROGRAM)
| General Data | ||||
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| Academic program | Formation ECAM LaSalle Ingénieur spécialité Mécanique et Génie Electrique (ENGINEERING PROGRAM) | :
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| Type d'EC | Classes (LIIEEng06EAdvHeatTransf) | |||
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Status :
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Period :
Semester 6 |
Education language :
English |
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| Learning Outcomes |
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| Upon completion of the course, the student will be able to 1. Extend the basic knowledge acquired in the introduction to heat transfer course and relate it to more advanced/practical application. 2. Use existing solution to solve transient and multi-dimensional heat conduction problems. 3. Compute heat exchange rates in problems including natural convection and boiling/condensation heat transfer. 4. Perform an analysis of the performance and the sizing of a heat exchanger. 5. Solve problems on radiation exchange between mulitple surfaces, which is a primary quantity of interest in most radiation problem. |
| Content |
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| -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. |
| Pre-requisites / co-requisites |
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| Introduction to Heat Transfer |
| Bibliography |
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| Recommended ressources : Çengel, Y (2007), “Heat and Mass Transfer, A practical approach”, 3rd ed, McGraw Hill Higher Eduction. Incropera, F.P. and DeWitt, D.P. (2011), “Fundamentals of Mass and Heat Transfer”, 7th Ed, John Wiley. |
| Assessment(s) | |||
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| N° | Nature | Coefficient | Observable objectives |
| 1 | Laboratory work: Practical insight through lab benchwork applications (Natural convection over a flat plate/ finned surface, study of a Heat Exchanger, Boiling and condensation - Two phase Heat Exchanger) | 0,25 | 3, 4 |
| 2 | Midterm exam of 1h 30 mins: Multi-dimensional and Transient Conduction Free/Natural Convection | 0,3 | 1, 2 , 3 |
| 3 | Final exam: Free/Natural Convection Boiling and Condensation Heat Exchanger Radiation Exchange between Surfaces | 0,45 | Written exam |