Upload
prasanthkarthi
View
28
Download
0
Tags:
Embed Size (px)
Citation preview
Chapter 11: Flow over bodies; Lift and DragEric G. PatersonDepartment of Mechanical and Nuclear Engineering The Pennsylvania State University
Spring 2005
Note to InstructorsThese slides were developed1, during the spring semester 2005, as a teaching aid for the undergraduate Fluid Mechanics course (ME33: Fluid Flow) in the Department of Mechanical and Nuclear Engineering at Penn State University. This course had two sections, one taught by myself and one taught by Prof. John Cimbala. While we gave common homework and exams, we independently developed lecture notes. This was also the first semester that Fluid Mechanics: Fundamentals and Applications was used at PSU. My section had 93 students and was held in a classroom with a computer, projector, and blackboard. While slides have been developed for each chapter of Fluid Mechanics: Fundamentals and Applications, I used a combination of blackboard and electronic presentation. In the student evaluations of my course, there were both positive and negative comments on the use of electronic presentation. Therefore, these slides should only be integrated into your lectures with careful consideration of your teaching style and course objectives. Eric Paterson Penn State, University Park August 20051 These
slides were originally prepared using the LaTeX typesetting system (http://www.tug.org/) and the beamer class (http://latex-beamer.sourceforge.net/), but were translated to PowerPoint for wider dissemination by McGraw-Hill.
ME33 : Fluid Flow
2
Chapter 11: Flow over bodies; lift and drag
ObjectivesHave an intuitive understanding of the various physical phenomena such as drag, friction and pressure drag, drag reduction, and lift. Calculate the drag force associated with flow over common geometries. Understand the effects of flow regime on the drag coefficients associated with flow over cylinders and spheres Understand the fundamentals of flow over airfoils, and calculate the drag and lift forces acting on airfoils.ME33 : Fluid Flow 3 Chapter 11: Flow over bodies; lift and drag
Motivation
ME33 : Fluid Flow
4
Chapter 11: Flow over bodies; lift and drag
Motivation
ME33 : Fluid Flow
5
Chapter 11: Flow over bodies; lift and drag
External FlowBodies and vehicles in motion, or with flow over them, experience fluid-dynamic forces and moments. Examples include: aircraft, automobiles, buildings, ships, submarines, turbomachines. These problems are often classified as External Flows. Fuel economy, speed, acceleration, maneuverability, stability, and control are directly related to the aerodynamic/hydrodynamic forces and moments. General 6DOF motion of vehicles is described by 6 equations for the linear (surge, heave, sway) and angular (roll, pitch, yaw) momentum.
ME33 : Fluid Flow
6
Chapter 11: Flow over bodies; lift and drag
Fluid Dynamic Forces and Moments
Ships in waves present one of the most difficult 6DOF problems.
Airplane in level steady flight: drag = thrust and lift = weight.
ME33 : Fluid Flow
7
Chapter 11: Flow over bodies; lift and drag
Drag and LiftFluid dynamic forces are due to pressure and viscous forces acting on the body surface. Drag: component parallel to flow direction. Lift: component normal to flow direction.
ME33 : Fluid Flow
8
Chapter 11: Flow over bodies; lift and drag
Drag and LiftLift and drag forces can be found by integrating pressure and wall-shear stress.
ME33 : Fluid Flow
9
Chapter 11: Flow over bodies; lift and drag
Drag and LiftIn addition to geometry, lift FL and drag FD forces are a function of density V and velocity V. Dimensional analysis gives 2 dimensionless parameters: lift and drag coefficients.
Area A can be frontal area (drag applications), planform area (wing aerodynamics), or wettedsurface area (ship hydrodynamics).
ME33 : Fluid Flow
10
Chapter 11: Flow over bodies; lift and drag
Example: Automobile DragScion XB Porsche 911
CD = 1.0, A = 25 ft2, CDA = 25ft2
CD = 0.28, A = 10 ft2, CDA = 2.8ft2
Drag force FD=1/2VV2(CDA) will be ~ 10 times larger for Scion XB Source is large CD and large projected area Power consumption P = FDV =1/2VV3(CDA) for both scales with V3!ME33 : Fluid Flow 11 Chapter 11: Flow over bodies; lift and drag
Drag and LiftFor applications such as tapered wings, CL and CD may be a function of span location. For these applications, a local CL,x and CD,x are introduced and the total lift and drag is determined by integration over the span L
ME33 : Fluid Flow
12
Chapter 11: Flow over bodies; lift and drag
Lofting a Tapered Wing
ME33 : Fluid Flow
13
Chapter 11: Flow over bodies; lift and drag
Friction and Pressure DragFluid dynamic forces are comprised of pressure and friction effects. Often useful to decompose,FD = FD,friction + FD,pressure CD = CD,friction + CD,pressurePressure drag
Friction drag
This forms the basis of ship model testing where it is assumed thatCD,pressure = f(Fr) CD,friction = f(Re)
Friction & pressure dragME33 : Fluid Flow 14 Chapter 11: Flow over bodies; lift and drag
StreamliningStreamlining reduces drag by reducing FD,pressure, at the cost of increasing wetted surface area and FD,friction. Goal is to eliminate flow separation and minimize total drag FD Also improves structural acoustics since separation and vortex shedding can excite structural modes.ME33 : Fluid Flow 15 Chapter 11: Flow over bodies; lift and drag
Streamlining
ME33 : Fluid Flow
16
Chapter 11: Flow over bodies; lift and drag
Streamlining via Active Flow ControlPneumatic controls for blowing air from slots: reduces drag, improves fuel economy for heavy trucks (Dr. Robert Englar, Georgia Tech Research Institute).ME33 : Fluid Flow 17 Chapter 11: Flow over bodies; lift and drag
CD of Common GeometriesFor many geometries, total drag CD is constant for Re > 104 CD can be very dependent upon orientation of body. As a crude approximation, superposition can be used to add CD from various components of a system to obtain overall drag. However, there is no mathematical reason (e.g., linear PDE's) for the success of doing this.
ME33 : Fluid Flow
18
Chapter 11: Flow over bodies; lift and drag
CD of Common Geometries
ME33 : Fluid Flow
19
Chapter 11: Flow over bodies; lift and drag
CD of Common Geometries
ME33 : Fluid Flow
20
Chapter 11: Flow over bodies; lift and drag
CD of Common Geometries
ME33 : Fluid Flow
21
Chapter 11: Flow over bodies; lift and drag
Flat Plate Drag
Drag on flat plate is solely due to friction created by laminar, transitional, and turbulent boundary layers.ME33 : Fluid Flow 22 Chapter 11: Flow over bodies; lift and drag
Flat Plate DragLocal friction coefficientLaminar: Turbulent:
Average friction coefficient
Laminar: Turbulent:
For some cases, plate is long enough for turbulent flow, but not long enough to neglect laminar portion
ME33 : Fluid Flow
23
Chapter 11: Flow over bodies; lift and drag
Effect of RoughnessSimilar to Moody Chart for pipe flow Laminar flow unaffected by roughness Turbulent flow significantly affected: Cf can increase by 7x for a given Re
ME33 : Fluid Flow
24
Chapter 11: Flow over bodies; lift and drag
Cylinder and Sphere Drag
ME33 : Fluid Flow
25
Chapter 11: Flow over bodies; lift and drag
Cylinder and Sphere DragFlow is strong function of Re. Wake narrows for turbulent flow since TBL (turbulent boundary layer) is more resistant to separation due to adverse pressure gradient. Usep,lam 80 Usep,lam 140
ME33 : Fluid Flow
26
Chapter 11: Flow over bodies; lift and drag
Effect of Surface Roughness
ME33 : Fluid Flow
27
Chapter 11: Flow over bodies; lift and drag
LiftLift is the net force (due to pressure and viscous forces) perpendicular to flow direction. Lift coefficient
A=bc is the planform areaME33 : Fluid Flow 28 Chapter 11: Flow over bodies; lift and drag
Computing LiftPotential-flow approximation gives accurate CL for angles of attack below stall: boundary layer can be neglected. Thin-foil theory: superposition of uniform stream and vortices on mean camber line. Java-applet panel codes available online: http://www.aa.nps.navy.mil/~jones/online _tools/panel2/ Kutta condition required at trailing edge: fixes stagnation pt at TE.
ME33 : Fluid Flow
29
Chapter 11: Flow over bodies; lift and drag
Effect of Angle of AttackThin-foil theory shows that CL2TE for E < Estall Therefore, lift increases linearly with E Objective for most applications is to achieve maximum CL/CD ratio. CD determined from windtunnel or CFD (BLE or NSE). CL/CD increases (up to order 100) until stall.ME33 : Fluid Flow 30 Chapter 11: Flow over bodies; lift and drag
Effect of Foil ShapeThickness and camber influences pressure distribution (and load distribution) and location of flow separation. Foil database compiled by Selig (UIUC) http://www.aae.uiuc.e du/m-selig/ads.html
ME33 : Fluid Flow
31
Chapter 11: Flow over bodies; lift and drag
Effect of Foil Shape Figures from NPS airfoil java applet. Color contours of pressure field Streamlines through velocity field Plot of surface pressure Camber and thickness shown to have large impact on flow field.
ME33 : Fluid Flow
32
Chapter 11: Flow over bodies; lift and drag
End Effects of Wing TipsTip vortex created by leakage of flow from highpressure side to lowpressure side of wing. Tip vortices from heavy aircraft persist far downstream and pose danger to light aircraft. Also sets takeoff and landing separation at busy airports.
ME33 : Fluid Flow
33
Chapter 11: Flow over bodies; lift and drag
End Effects of Wing TipsTip effects can be reduced by attaching endplates or winglets. Trade-off between reducing induced drag and increasing friction drag. Wing-tip feathers on some birds serve the same function.ME33 : Fluid Flow 34 Chapter 11: Flow over bodies; lift and drag
Lift Generated by Spinning
Superposition of Uniform stream + Doublet + VortexME33 : Fluid Flow 35 Chapter 11: Flow over bodies; lift and drag
Lift Generated by SpinningCL strongly depends on rate of rotation. The effect of rate of rotation on CD is small. Baseball, golf, soccer, tennis players utilize spin. Lift generated by rotation is called The Magnus Effect.
ME33 : Fluid Flow
36
Chapter 11: Flow over bodies; lift and drag