Postgraduate Course: Computational Fluid Dynamics (MSc) (PGEE11055)
Course Outline
| School |
School of Engineering |
College |
College of Science and Engineering |
| Course type |
Standard |
Availability |
Not available to visiting students |
| Credit level (Normal year taken) |
SCQF Level 11 (Postgraduate) |
Credits |
20 |
| Home subject area |
Postgrad (School of Engineering) |
Other subject area |
None |
| Course website |
None
|
Taught in Gaelic? |
No |
| Course description |
This course introduces CFD by means of a set of lectures covering the background physics and mathematics, together with practical assignments that use commercial CFD software to solve flow problems. The need for error control and independent validation of results is stressed throughout. Although particular software (Star-CCM+) is used for the assignments, the underlying themes of the module are generic. |
Entry Requirements
| Pre-requisites |
|
Co-requisites |
|
| Prohibited Combinations |
|
Other requirements |
None
|
| Additional Costs |
None |
Course Delivery Information
|
| Delivery period: 2010/11 Semester 1, Not available to visiting students (SS1)
|
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 |
| No Exam Information |
Summary of Intended Learning Outcomes
On completion of the module, students should be able to:
1. Describe how the fields of fluid mechanics, mathematics and computer science have contributed to the development of CFD.
2. Identify the key aspects of fluid mechanics relevant to the setting up of a problem for CFD, and to the interpretation of the results.
3. Describe how various levels of approximation to the equations of motion are appropriate to particular classes of flow problem.
4. Describe the nature of turbulent flows and explain why 'turbulence models' are necessary to many CFD solutions.
5. Distinguish between the important classes of turbulence model.
6. Describe the important classes of numerical discretisation scheme, and explain the relationship between the discretisation process and the underlying fluid physics.
7. Appreciate the significance of error control and validation in CFD.
8. Discuss the sources of error in CFD solutions, and describe steps which can be taken to estimate the magnitude of errors.
9. Set up a two-dimensional flow problem for CFD solution, including geometry, boundary conditions, flow models and solution parameters.
10. Use pre-processor, solver and post-processor software to build a CFD model for two-dimensional problem, and obtain a solution.
11. Estimate the magnitudes of solution errors, and take steps to validate the results. |
Assessment Information
| Assignment (50%) Final Examination (50%) |
Special Arrangements
| None |
Additional Information
| Academic description |
Not entered |
| Syllabus |
Not entered |
| Transferable skills |
Not entered |
| Reading list |
Not entered |
| Study Abroad |
Not entered |
| Study Pattern |
Not entered |
| Keywords |
computational fluid dynamics |
Contacts
| Course organiser |
Dr David Ingram
Tel: (0131 6)51 9022
Email: David.Ingram@ed.ac.uk |
Course secretary |
Mrs Laura Smith
Tel: (0131 6)50 5690
Email: laura.smith@ed.ac.uk |
|
copyright 2011 The University of Edinburgh -
31 January 2011 8:05 am
|
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