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
E Hu
6 points
* 52 lecture hours and 26 tutorial and
laboratory hours
* Full-year subject
* Gippsland
* Prerequisites:
GEG3733
Objectives The student is expected to develop a deeper understanding of the concept of `energy quality' and the combustion process. The student is expected to understand the mechanism of heat transfer (especially convection and radiation).
Synopsis First semester Heat transfer. Review of steady conduction. Unsteady conduction heat transfer. Convection: introduction, forced convection, nature convection, boiling and condensation processes. Radiation: nature of radiation processes, solar radiation, radiation exchange between surfaces. Heat exchanger design: effectiveness versus NTU method. Second semester Combustion: chemical reaction and mass balance in the combustion, energy balance, theoretical and actual flame temperature calculation. Availability and exergy: concepts; availability balance for closed system, flow availability; second law efficiency. Other energy conversion technologies: solar energy application - basic angles between sun and earth, solar water heater, solar thermal refrigeration. Principle of fuel cell.
Assessment Examinations: 60%
* Assignment and
experimental report: 40%
Prescribed texts
Holman J P Heat transfer 5th edn, McGraw-Hill
Moran M J and Shapiro H N Fundamentals of engineering thermodynamics
Wiley, 1993
Recommended texts
Bejan A Heat transfer Wiley, 1993
Grag H P Treatise on solar energy Wiley, 1982
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