An excellent way for students to gain a feel for
is to fly a
because of forces acting on the
of the kite.
Though kites come in many
shapes and sizes, the
forces which act on the kite are
the same for all kites.
You can compare these forces to the
forces that act on an airliner in
flight and you will find that, with the exception of thrust,
they are exactly the same.
The similarity in forces allowed the
to test their theories of flight by flying their
kites from 1900 to 1902.
On this slide we show the equations which would describe the
lift of a flying kite. The graphic shows a side view of the
flying kite with the aerodynamic lift
shown by the blue
The wind is blowing parallel to the ground
and the lift direction is
perpendicular to the wind.
Since the forces on a kite are the same as the forces on an airplane,
we can use the mathematical equations developed to predict airplane
performance to predict the aerodynamic performance of a kite.
In particular, the
lift equation shown on the upper right side of the
figure has been developed for aircraft.
The lift L is equal to a lift coefficient Cl times the
projected surface area A times the air density r times one
half the square of the wind velocity V.
L = Cl * A * r * .5 * V^2
The lift depends on two properties of the air; the density and velocity.
the density depends on your location on the earth. The higher the
the lower the density.
value for air density r at sea level conditions is given as
r = 1.229 kg/m^3 or .00237 slug/ft^3.
The variation of lift with altitude is described on a separate
The air velocity is the
speed between the kite and the air. When the kite is held fixed
the relative air velocity is the wind speed.
If the line breaks, or if you let out line, the velocity is
something less than the wind speed; if you pull on the control line the
velocity is the wind speed plus the speed of your pull.
The lift changes with the
square of the velocity.
The aerodynamic lift of your kite depends directly on the surface
area of the kite.
You first learn how to compute the
for a geometric shape while you
are in middle school. The surface area depends on the particular
design of your kite.
The lift depends on the
lift coefficient, Cl, which depend on geometric
properties of the kite and the angle between the kite surfaces and the wind.
Lift coefficients are usually determined experimentally for aircraft,
but the aerodynamic surfaces for most kites are simple, thin, flat
plates. So we can use some experimental values of the lift
coefficients for flat plates to get a first order idea of our kite performance.
For a thin flat plate at a low
angle of attack ,
the lift coefficient Clo is equal to 2.0 times pi (3.14159)
times the angle a expressed in radians (180 degrees equals pi radians):
Clo = 2 * pi * a
We use Clo for the lift coefficient because there is another aerodynamic effect present
on most kites. If we think of a
kite as an aircraft wing, and use the
terminology associated with aircraft wings,
most kites have a low wing span (length from side to side)
relative to the surface area. Most kites therefore have a low aspect ratio AR
which is defined to be span s squared divided by the area A.
AR = s^2 / A
Near the tips of a wing the flow spills from the underside to the top side
because of the difference in pressure. This creates a
which changes the effective angle of attack of the flow over
a portion of the wing. For low aspect ratio wings, the portion of the wing
affected by the downwash is greater than for high aspect ratio wings.
Since most kites have a low aspect ratio AR, we have to include the effect of
downwash on the lift coefficient.
The equation for the correction is given at the bottom right of the slide:
Cl = Clo / (1 + Clo / (pi * AR) )
With these equations you can make a first prediction of the lift of your
kite. You can use the
KiteModeler program to further study how kites work
and to design your own kites.
Forces on a Kite
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