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Rotorcraft Flying Menu >General
Aerodynamics > Airfoil
Before beginning the discussion of lift, you
need to be aware of certain aerodynamic terms that describe
an airfoil and the interaction of the airflow around it.
An airfoil is any surface, such as an airplane
wing or a helicopter rotor blade, which provides aerodynamic
force when it interacts with a moving stream of air. Although
there are many different rotor blade airfoil designs, in most
helicopter flight conditions, all airfoils perform in the same
manner.
Engineers of the first helicopters designed
relatively thick airfoils for their structural characteristics.
Because the rotor blades were very long and slender, it was
necessary to incorporate more structural rigidity into them.
This prevented excessive blade droop when the rotor system was
idle, and minimized blade twist-ing while in flight. The airfoils
were also designed to be symmetrical, which means they had the
same cam-ber (curvature) on both the upper and lower surfaces.
Symmetrical blades are very stable, which helps
keep blade twisting and flight control loads to a minimum. [Figure
2-2] This stability is achieved by keeping the center of pressure
virtually unchanged as the angle of attack changes. Center of
pressure is the imaginary point on the chord line where the
resultant of all aero-dynamic forces are considered to be concentrated.
Figure 2-2. The upper and lower curvatures
are the same on a symmetrical airfoil and vary on an asymmetrical
airfoil.
Today, designers use thinner airfoils and obtain
the required rigidity by using composite materials. In addi-tion,
airfoils are asymmetrical in design, meaning the upper and lower
surface do not have the same camber. Normally these airfoils
would not be as stable, but this can be corrected by bending
the trailing edge to produce the same characteristics as symmetrical
airfoils. This is called “reflexing.” Using this
type of rotor blade allows the rotor system to operate at higher
forward speeds.
One of the reasons an asymmetrical rotor blade
is not as stable is that the center of pressure changes with
changes in angle of attack. When the center of pressure lifting
force is behind the pivot point on a rotor blade, it tends to
cause the rotor disc to pitch up. As the angle of attack increases,
the center of pressure moves forward. If it moves ahead of the
pivot point, the pitch of the rotor disc decreases. Since the
angle of attack of the rotor blades is constantly changing during
each cycle of rotation, the blades tend to flap, feather, lead,
and lag to a greater degree.
When referring to an airfoil, the span is the
distance from the rotor hub to the blade tip. Blade twist refers
to a changing chord line from the blade root to the tip.Twisting
a rotor blade causes it to produce a more even amount of lift
along its span. This is necessary because rotational velocity
increases toward the blade tip. The leading edge is the first
part of the airfoil to meet the oncoming air. [Figure 2-3] The
trailing edge is the aft portion where the airflow over the
upper surface joins the airflow under the lower surface. The
chord line is an imaginary straight line drawn from the leading
to the trailing edge. The camber is the curvature of the air-foil’s
upper and lower surfaces. The relative wind is the wind moving
past the airfoil. The direction of this wind is relative to
the attitude, or position, of the airfoil and is always parallel,
equal, and opposite in direction to the flight path of the airfoil.
The angle of attack is the angle between the blade chord line
and the direction of the relative wind.
Figure 2-3. Aerodynamic terms of an
airfoil.
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