Undergraduate - UnitMAE4965 - Advanced aerodynamics and turbulence

This unit entry is for students who completed this unit in 2014 only. For students planning to study the unit, please refer to the unit indexes in the the current edition of the Handbook. If you have any queries contact the managing faculty for your course or area of study.

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6 points, SCA Band 2, 0.125 EFTSL

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Level	Undergraduate
Faculty	Faculty of Engineering
Organisational Unit	Department of Mechanical and Aerospace Engineering
Offered	Clayton Second semester 2014 (Day)
Coordinator(s)	Professor Julio Soria

Synopsis

This unit introduces differential and integral forms of governing equations in tensor notation, reviews inviscid and viscous aerodynamic flows and analyses the derivation of thin shear layer equations. Solution methods for boundary layer equations for the prediction of drag, lift and boundary layer separation on airfoil surfaces follows. Flow instability and transition from laminar to turbulent flow is examined and boundary layer stability analysis is introduced. Turbulence physics and turbulent shear flows and the analysis of turbulent shear flows are covered together with an introduction to statistical analysis in turbulence and aerodynamic flow control.

Outcomes

Understand the tensorial development of the governing conservation equations for aerodynamics problems
Understand the physics of inviscid and viscous aerodynamics
Understand the derivation of the equations governing boundary layer flow and shear flows in general
To be able to solve the boundary layer equations for generic geometries using both differential analysis and integral analysis to predict drag, lift and boundary layer separation on airfoil surfaces
Understand the physics of flow instability and laminar-turbulent transition
Understand the analysis of Tollmien-Schlichting instability and transition in boundary layer flow and recognize factors controlling laminar-turbulent boundary layer transition
Understand statistical analysis of turbulence and the general properties of turbulent shear flows
Understand the structure of turbulent boundary layer flow and to be able to derive and interpret the equations governing the mean flow, kinetic energy and Reynolds stresses of a turbulent boundary layer
Understand the quantitative description of turbulent boundary layer flow and to be able to calculate turbulent boundary layer drag and predict adverse pressure gradient separation on airfoils
To recognise and interpret boundary layer control methodologies on airfoils to minimize drag and avoid boundary layer separation and loss of lift.