- Compressible flows.
- Isentropic flows (subsonic and supersonic) in ducts with varying cross-section, shocks.
- Hydrodynamic stability (Rayleigh, Orr-Sommerfeld) and transition.
- Turbulence (in general, in pipes/channels, in boundary layers).
- Closure models.
- Practical evaluation of friction and heat transfer coefficients.
- Singular head losses.
- Natural convection.
- Boussinesq approximation.
- Phase changes (condensation, ebullition, solidification, fusion).
- Heat exchangers.
- Thermal radiation (physical principles; surface radiation; radiation in gases).
At the end of this learning unit, the student is able to : | |
1 | In consideration of the reference table AA of the program "Masters degree in Mechanical Engineering", this course contributes to the development, to the acquisition and to the evaluation of the following experiences of learning:
This course follows the course " Fluid mechanics and transfers I ", with which it covers the basic contents in both disciplines. The courses I et II form an ensemble, and their objectives are commun : integration of fluid mechanics and transfers; physical observation and phenomenological approach; rigorous mathematical developments (conservation equations, models); important place reserved to the proper coverage of turbulence. The organisation of the courses I and II is done in such a way that the foundations are covered in course I and the more specific matters are covered in course II (e.g., compressible flows, turbulence, radiation, pratical applications, etc.). |
The contribution of this Teaching Unit to the development and command of the skills and learning outcomes of the programme(s) can be accessed at the end of this sheet, in the section entitled “Programmes/courses offering this Teaching Unit”.
Compressible flows : Bernoulli's equation for isentropic flows; relation between incompressible flow and compressible flow at low Mach number. Isentropic flows in duct with varying cross-section, subsonic and supersonic (converging, diverging, nozzle); maximum mass flow rate. normal shock and jump relations (Hugoniot). Operating modes of a convergent-divergent nozzle. Adiabatic flow in duct with constant cross-section and with wall friction (Fanno).
2D incompressible and irrotational flows (5 hrs)
Fundamental monopole singularities: circulation singularity, mass flow rate singularity. Multipole singularities. Obtaining flows using the complex potential f(z) and examples of simple flows. Flow with and without circulation past a circular cylinder. Conformal transformation, flow past an airfoil (using the Joukowski transformation) et Kutta-Joukowski condition for the circulation, lift and Blasius theorem.
Evaporation (2 hrs)
Mass transfer in boundary layers for a highly diluted binary mixture, and correlations. Evaporation of a liquid. Heat and mass transfer correlation in forced convection, in laminar and turbulent flows.
Heat exchangers (5 hrs)
Main configurations of exchangers, incidence of the fluid circulation directions (co-flow, counter-flow and cross-flow). Convective and conductive thermal resistance. Determination of the global heat transfer coefficient. Evaluation of the exchange area. LMTD method. Efficiency of an exchanger. Dimensionless solutions epsilon-NTU (efficiency - number of transfer units).
Boiling and consensation (2 hrs)
Boiling: the different boiling modes, nucleation, Nukiyama curve; ebullition in forced convection. Condensation: film condensation, Nusselt theory.
Radiative heat transfer (5 hrs)
Basic physical laws. Surface properties (emissivity and absorbtivity, directional vs hemispherical, spectral vs total). Exchange between black surfaces. View factors. Exchange between real surfaces (special cas of gray diffuse surfaces). Electric analogy of the equivalent resistance network.
Exercices : sessions with a teaching assistant, homeworks, and at least one laboratory
The exercises are either direct appplications of the theory (with an objective to familiarize the student to pratical computation methods, and to familiarize them to typical orders of magnitude), or they will rely on the creativity of the student to use the concepts learned in the class to tackle new problems or methodologies not explicitely studied during the lectures.
- G. Winckelmans, "Compressible flows", lecture notes
- G. Winckelmans, "Incompressible and irrotational flows", lecture notes
- M. Duponcheel, Slides on heat exchangers, Boiling and condensation, and Radiative heat transfer
- T. Bergman, A. Lavine, F. Incropera, D. Dewitt, Fundamentals of Heat and Mass Transfer, 7th Edition, Wiley, 2011 (recommended)
- Notes et/ou transparents des titulaires.
- G.K. Batchelor, "An introduction to fluid dynamics", Cambridge University Press 1967 (reprinted paperback 1994).
- F. M. White, "Viscous fluid flow" second edition, Series in Mechanical Engineering, McGraw-Hill, Inc., 1991.
- P. A. Thompson, "Compressible-fluid dynamics", advanced engineering series, Maple Press, 1984.
- H. Lamb, "Hydrodynamics", sixth edition, Cambridge University Press 1932, Dover Publications (paperback).
- L. Rosenhead, "Laminar boundary layers", Oxford University Press 1963, Dover Publications (paperback).
- P. G. Drazin and W. H. Reid, "Hydrodynamic stability", Cambridge University Press 1985.
- M. Van Dyke, "An album of fluid motion", The Parabolic Press, 1982.
- A. Bejan, "Heat transfer", Wiley, 1993.
- R.B. Bird, W.E. Stewart., E.N. Lighfoot , "Transport phenomena", Wiley int. ed., 1960.
- Schlichting, "Boundary-layer theory", Mc Graw-Hill, NY, 1986.
- L. Prandtl and O.G. Tietjens, "Fundamentals of hydro- and aero-mechanics", Dover, NY, 1957.
- J. Happel and H. Brenner, "Low Reynolds number hydrodynamics", Noordhoff int. publ., Leyden, 1973.
- D.J. Tritton, "Physical fluid dynamics", Clarendon Press, 1988.
- T. Bergman, A. Lavine, F. Incropera, D. Dewitt, Fundamentals of Heat and Mass Transfer, 7th Edition, Wiley, 2011(conseillé)
- M. N. O'zisik, Heat Transfer, a Basic Approach, McGraw-Hill, 1985
- Y. Cengel, Heat Transfer, a Practical Approach, 2nd Edition, McGraw-Hill, 2003
- N. Todreas & M. Kazimi, Nuclear Systems, Volume 1, Thermal Hydraulics Fundamentals, 2nd Edition, CRC Press, 2011
- M. F. Modest, Radiative Heat Transfer, 2nd Edition, Academic Press, 2003
- G. Winckelmans, "Compressible flows", lecture notes
- G. Winckelmans, "Incompressible and irrotational flows", lecture notes
- M. Duponcheel, Slides on heat exchangers, Boiling and condensation, and Radiative heat transfer
- T. Bergman, A. Lavine, F. Incropera, D. Dewitt, Fundamentals of Heat and Mass Transfer, 7th Edition, Wiley, 2011 (recommended)