Number of hours
- Lectures 9.0
- Projects -
- Tutorials -
- Internship -
- Laboratory works -
- Written tests 1.0
ECTS
ECTS 8.0
Goal(s)
Learning outcomes :
- To know the phenomena of transfers coupled with chemical reactions; gas-liquid, fluid-solid reactions.
- To know the phenomena of material transfers coupled with enthalpy transfers (air coolers and dryers)
- To understand how to establish equations of transfer problems and introduction to mathematical and numerical resolution tools
Gerard MORTHA
Content(s)
Mass tranfer course, level 2.
Fundamentals of mass transfer coupled to heat transfer and to chemical reactions ; liquid-gas ; liquid-solid. Models development and introduction to the mathematical tools for their resolution.
Gas-liquid mass transfer coupled to a chemical reaction
Mass transfer models for heterogeous fluid-solids reactions
Coupled heat and mass transfer: introduction to cooling systems and evaporation systems
Building models and their mathematical resolution (based on integration of differential equations)
Introduction to transport phenomena, course at Pagora (1st year cursus)
Mass transfer, level 1, course at Pagora (1st year cursus)
Fundamentals of physics and chemistry, 1st and 2nd year university level
Gas-liquid material transfers with chemical reaction.
Convective transfer: theory of boundary layer contraction, Hatta number, efficiency factor.
Diffusion in the presence of a chemical reaction: modelling.
Fluid-solid matter transfers: introduction to heterogeneous particulate kinetics, mathematical shaping.
Heat transfers - coupled material with phase change: atmospheric coolers.
Modeling in material transfer. Problem statement and mathematical formatting. Integration of differential equations: Cauchy problem; explicit and implicit schemes. Laplace partial differential equations: finite difference method.
Written exam. 1h
note = note du DS
The course exists in the following branches:
- Curriculum - Pagora Engineer - Student - Semester 6
Course ID : 3FME1042
Course language(s):
You can find this course among all other courses.
BIRD R.B., STEWART W.E., LIGHTFOOT E.N. Transport phenomena. New York : John Wiley& Sons, 1962.
MIDDLEMAN S. An introduction to mass and heat transfer. Principles of analysis and design. New York : John Wiley&Sons, 1998, 691 pages (ISBN 0-471-11176-7).
BRODKEY R. S., HERSHEY H.C. Transport phenomena: a unified approach. New York : McGraw Hill-College, 1988, 847 pages (ISBN 9780070079632).
DEEN W.M. Analysis of transport phenomena. Oxford University Press, NY, 1998, 624 pages (ISBN 978-0-19-508494-8).
DOUGLAS J.M. Conceptual design of chemical processes. McGaw-Hill, N.Y, 1988, Lavoisier, Paris, 602 pages.
CRANK J. The mathematics of diffusion. 2e éd. Oxford : Clarendon press, : Oxford University Press, 1979, 424 pages (ISBN 978098534112).
GREEN D. Perry's chemical engineer's handbook. 7e éd. New York : Mc Graw-Hill Ed., 1997.
COEURET F., STORCK A. Eléments de génie électrochimique. Paris : TEC/DOC Lavoisier, 1984 (ISBN 2-85206-243-7).
LEVENSPIEL O. Chemical reaction engineering. 2e éd. New York : John Wiley&Sons, 1972.
VILLERMAUX J. Génie de la réaction chimique. 2e éd. Paris : Lavoisier,1993, 448 pages.
SCHMIDT L.D. The engineering of chemical reactions. Oxford University Press, N.Y., 1998.
FOGLER H. S. Elements of chemical reaction engineering. 3e éd. Prentice Hall, 1999.