Unit name | Aerodynamics 3 |
---|---|
Unit code | AENG31101 |
Credit points | 10 |
Level of study | H/6 |
Teaching block(s) |
Teaching Block 1 (weeks 1 - 12) |
Unit director | Dr. Rendall |
Open unit status | Not open |
Pre-requisites | |
Co-requisites |
None |
School/department | School of Engineering Mathematics and Technology |
Faculty | Faculty of Engineering |
Aerodynamics 3 introduces common methods for the practical analysis of aerofoils in both inviscid and viscous flows. The course may be grouped into the following subject areas: i) Conformal mapping and the Joukowski transformation. Demonstrates the transformation between real and complex planes that allows determination of pressures and forces on aerofoils in incompressible, inviscid flows through an inverse method. ii) Laminar boundary layers. Introduces the concept and physics of boundary layers, and integral methods for calculating their influence on the drag/lift of aerofoils. iii) Transition and Turbulent Boundary layers. The concepts of turbulence, how this effects boundary layers, and simple methods for computing their effects. iv) Practical tools. Panel and vortex lattice methods, their formulation, implementation, uses and limitations.
On successful completion of the unit the student will:
have an understanding of conventional analytical and semi-analytical methods used for the design and analysis of aerofoils in inviscid and viscous flows, and also the areas of applicability and limitations of such methods; be able to apply such methods to aerofoil design, and have some direct experience of the effect of shape on lift and drag; understand the concept of the boundary layer, and have a basic appreciation of the effects of viscosity on aerodynamic characteristics, including the generation of friction and form drag and the onset and impact of flow separation; understand widely-used industrial analysis methods for 3D analysis, specifically panel and vortex lattice techniques.
Lectures, laboratory work
25% assignment using MATLAB/specialist aerodynamic software 75% 2-hour examination in January.
As recommended by course director