Published by Monash University, Australia
Maintained by wwwdev@monash.edu.au
Approved by R Chaffey, Faculty of Engineering
Copyright © Monash University 1997 - All Rights Reserved - Caution
J Ghojel
4 points
* 36 lecture and 12 laboratory hours
*
First semester
* Caulfield
* Prerequisites: MEE3362
Objectives Develop skills and understanding of the approaches and methods used in engineering applications of thermodynamics and heat transfer.
Synopsis Reversible work, availability and irreversibility. Vapour power plant: Carnot, Rankine, reheat and regenerative cycles, effect of variables on plant performance, combined power and process heating plant. Modern thermal power station practice. Compressible flow, one dimensional compressible flow, sonic velocity, Mach number, convergent nozzles, critical pressure ratio, convergent/divergent nozzles. Numerical solution applied to unsteady flow processes. Steady and unsteady state conduction, extended surfaces, numerical solution to two-dimensional conduction problems. Dimensional analysis applied to forced and natural convection. Heat transfer during condensation and evaporation. Heat exchangers: overall heat transfer coefficient, log mean temperature difference, heat exchanger effectiveness, rational design procedure for shell and tube exchangers.
Assessment Examination (3 hours): 70%
* Laboratory
work, a 1-hour test, tutorial: 30%
Prescribed texts
Holman J P Heat transfer SI edn, McGraw-Hill, 1989
Rogers and Mayhew Engineering thermodynamics: Work and heat transfer
Longman, 1992
Van Wylen G J and Sonntag R E Fundamentals of classical thermodynamics
3rd edn, Wiley, 1985
Published by Monash University, Australia
Maintained by wwwdev@monash.edu.au
Approved by R Chaffey, Faculty of Engineering
Copyright © Monash University 1997 - All Rights Reserved -
Caution