Transcript AE315 Lsn15

Aero Engineering 315
Lesson 15
3-D (Finite) Wings Part I
Airfoil Lab Review
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Due Thursday (lesson 17)
Use spreadsheet template (posted on k:
drive)
Closely follow lab handout directions
Review Excel tutorial if needed
Compare to published data for NACA 0012
provided in supplemental hand out
6
 Re = 3.0 x 10
Key Formula:
 Px = Pref – [roil x 32.2 x (hx –href )/12]
Airfoil Lab Spreadsheet
Lessons 15 and 16 Objectives
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Define and calculate aspect ratio
Explain wing tip effects on lift and drag
Describe design techniques to reduce induced
drag
State which planform shape minimizes
induced drag
Describe span efficiency factor
Calculate the 3-D lift curve slope and lift
coefficient
Calculate induced and total drag coefficients
3-D Wing Geometry
2
b
Aspect Ratio (AR): AR
S
High AR
Low AR
Typical Values
Fighters:
2-5
Transports: 6-10
Gliders:
10-15
Wing Twist
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Wing twist is applied to create a delay in stall for
outboard portions of wings
Two types of twist:
1. Geometric twist – wing is physically twisted to
change the angle-of-attack at the tip
Angle of Twist
2.
Aerodynamic twist – not a physical twist, but a
different airfoil at the tip (usually one with a
higher astall – i.e. thinner or less camber at tip)
NACA 6713 at wingtip
Remember the A-10?
NACA 6716 at wing root
0.14
y/c
0.09
0.04
-0.01
-0.06
0
0.1
0.2
0.3
0.4
0.5
x/c
0.6
0.7
0.8
0.9
1
So what’s up with a “real wing”?
Wingtip Vortices
Wingtip Vortices
Downwash
TOP SURFACE
(relative low pressure)
Front
View
(relative high pressure)
BOTTOM SURFACE
upper surface flow (inboard)
lower surface flow (outboard)
Top
View
The pressure imbalance at the wingtip sets up a spanwise
component of flow, strongest at the tips, weakest in the center.
A Cessna Citation was flown above a cloud bank at approximately 165
knots. The trailing vortices descended over the fog layer due to
downwash, and were made visible by the distortion at the interface.
Tip effects and lift curve
and
Caused by:
Airfoil
cl
CL
cla
CLa
Wing
• Pressure loss at tip
• Pressure simply “leaks”
to top of the wing
• Downwash
• Local flow is diverted
down by vortices
a
Notice the slope is decreased for the wing, but the
zero lift angle of attack is unchanged—these 3-D effects are directly
a result of lift (i.e. pressure differential) being created on the wing
Downwash
Spanwise flow comes off each wingtip and
creates a trailing vortex. These vortices, in
turn, deflect the local flow over the wing
downward. This deflection is called
“downwash.” One result is reduced lift!
Downwash
Effective flow direction over wing
e
V
e is the downwash angle
aeff  a - e
Induced drag — big picture
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Wingtip vortex is an unavoidable
consequence of wingtips and results in
reduced lift & increased drag
Induced drag is greatest when the
pressure difference between upper and
lower surfaces is greatest
 High angles of attack
 Takeoff and landing
Induced drag will be zero when there is
no pressure difference (i.e. at zero lift)
Next Lesson (16)…
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Prior to class
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Complete reading (4.1 – 4.2)
In Class
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Calculate 3-D lift and drag
Span efficiency factor
Design strategies to minimize induced
drag