This module blends the skills of physical understanding/intuition with some numerical work.  The concepts covered will be for the main part on the thermodynamic cycles characteristic of many existing machinery (or thermal systems) where heat and work transfer (i.e. energy transfer) take place You will develop the valuable skill of working out the efficiency of a given cycle from first principles.  This will help you to appreciate how a thermal system should operate to maximise its efficiency and reduce energy losses, and thus evaluate its economic viability. Such issues are relevant to renewable energy.  You will have the opportunity to experience a number of working cycles both in class and through  formal labs on refrigeration, for which you will also have the opportunity to learn how to write a well-structured scientific report.  The module should make a nice link with topics on energy management and energy storage. 

This module is a typical advanced course on a mechanical engineering degree for second year students so students with prior mechanical engineering (or close) experience should be able to do it.  

Prerequisite module: ENE1008 or equivalent.

This module builds on the material delivered in CSM1257 by looking at more advanced and practical examples. Historically, national and global development has progressed hand in hand with the evolving methods through which finite natural energy resources such as petroleum, natural gas and coal have been harnessed and distributed.

Current trends now favour the exploitation of renewable (non-finite) energy as the prime source. However, the basic science of the energy conversion machinery necessary is broadly unchanged. Using (converting) energy efficiently still remains the central issue;  and this module aims to instill deep quantitative knowledge and understanding about this topic.

Applied thermodynamics is an essential area of study for those hoping to improve the effectiveness with which energy resources (finite and renewable) are used and also an essential tool for evaluating correctly the potential of new ideas for energy production and associated machinery.

An important recent addition to the course is a study of the refrigeration laboratory and the calculation of coefficient of performance, electric motor efficiency, compressor efficiency and many other thermal parameters enable you to apply knowledge gained to other thermodynamic cycles. Throughout the course, there will be presentations and examples on specific renewable energy applications,  which will show the direct link between what you are learning in the module  and the rapid advancements in the renewable energy sector.

There will be a special emphasis  on power cycles performance and design, including those of gas turbines, steam plants, and internal combustion (reciprocating) engines.

Furthermore, the module touches upon important technologies like Combined Heat and Power (CHP) and Geothermal energy systems to ensure you are well equipped with skills that will satisfy employers in conventional generation sector as well as the renewable energy generation sector.
 

Referred and deferred assignments will mirror the original modes of assessment.

Basic reading:

ELE: http://vle.exeter.ac.uk/ 

Web based and Electronic Resources:

E-Recourse / explanatory Videos:

The Second Law of Thermodynamics

[San Francisco, California, USA] : Kanopy Streaming, 2015.

Entropy: The Second Law of Thermodynamics

[San Francisco, California, USA] : Kanopy Streaming, 2015.

Natural convective heat transfer from short inclined cylinders
Oosthuizen, P. H.; New York : Springer, [2013]

Everyday Thermodynamics: Refrigeration

The Great Courses, 2015

Reading list for this module: