Postgraduate Course: Thermodynamics for power plant engineering with CO2 capture (PGEE10007)
Course Outline
School |
School of Engineering |
College |
College of Science and Engineering |
Course type |
Standard |
Availability |
Available to all students |
Credit level (Normal year taken) |
SCQF Level 10 (Postgraduate) |
Credits |
10 |
Home subject area |
Postgrad (School of Engineering) |
Other subject area |
Geosciences |
Course website |
None |
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Course description |
The course presents thermodynamics as a real world subject. Basic principles and conservation equations, together with constitutive laws, are applied to a variety of systems and devices including heat exchangers, nozzles, power cycles, air conditioning systems and cooling towers and linked to their application in a range of power plants, including with integration with proposed CO2 capture systems. |
Entry Requirements
Pre-requisites |
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Co-requisites |
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Prohibited Combinations |
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Other requirements |
None
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Additional Costs |
None |
Course Delivery Information
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Delivery period: 2010/11 Semester 1, Not available to visiting students (SS1)
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WebCT enabled: Yes |
Quota: None |
Location |
Activity |
Description |
Weeks |
Monday |
Tuesday |
Wednesday |
Thursday |
Friday |
No Classes have been defined for this Course |
First Class |
First class information not currently available |
Summary of Intended Learning Outcomes
1. Apply the First Law to simple closed and steady flow systems using appropriate property data from tables, charts and equations.
2. Use one-dimensional compressible flow theory to determine the gas velocities and flow rates in choked and unchoked nozzles.
3. Use the simple theory of mixtures of ideal gasses and vapours to calculate the performance of plant such as air conditioning systems and cooling towers.
4. Use the First Law to analyse the performance of simple power plants.
5. Give a qualitative explanation of some of the implications of the Second Law for these plants.
6. Carry out simple heat transfer calculations involving conduction, convection and radiation.
7. Use standard computer packages to calculate Gibbs function minimisation and apply the results for simple analysis of chemical equilibrium problems involving coal gasifiers or autothermal reformers and associated equipment in power plant applications. |
Assessment Information
Exam 80%
Coursework 20% |
Please see Visiting Student Prospectus website for Visiting Student Assessment information |
Special Arrangements
Not entered |
Contacts
Course organiser |
Prof Jonathan Gibbins
Tel: (0131 6)50 4867
Email: jon.gibbins@ed.ac.uk |
Course secretary |
Mrs Kim Orsi
Tel: (0131 6)50 5687
Email: Kim.Orsi@ed.ac.uk |
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copyright 2010 The University of Edinburgh -
1 September 2010 6:24 am
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