WINGS AND LIFT – HOW PLANES FLY
For a plane or bird to fly, its wings must produce enough lift to equal its weight. Most
wings used in flight are a special shape – called aerofoils (or airfoils). This shape is
needed to help generate lift.
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Daniel Bernoulli
The principle of lift in flight is often attributed to Daniel Bernoulli (1700–1782), a Swiss
mathematician.
Portrait by Johann Rudolf Huber.
The angle of attack – Newton’s third law
Newton’s third law of motion states that, for every action, there is an equal and
opposite reaction. Based on this law, wings are forced upwards because they are
tilted, pushing air downwards so the wings get pushed upwards. This is the angle
of attack or the angle at which the wing meets the airflow.
As air flows over the surface of a wing, it sticks slightly to the surface it is flowing
past and follows the shape. If the wing is angled correctly, the air is deflected
downwards.
The action of the wing on the air is to force the air downwards while the reaction
is the air pushing the wing upwards. A wing’s trailing edge must be sharp, and it
must be aimed diagonally downwards to create lift. Both the upper and lower
surfaces of the wing act to deflect the air.
The amount of lift depends on the speed of the air around the wing and
the density of the air. To produce more lift, the object must speed up and/or
increase the angle of attack of the wing (by pushing the aircraft’s tail
downwards).
Speeding up means the wings force more air downwards so lift is increased.
Increasing the angle of attack means the air flowing over the top is turned
downwards even more and the air meeting the lower surface is also deflected
downwards more, increasing lift.
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There is a limit to how large the angle of attack may be. If it is too great, the flow
of air over the top of the wing will no longer be smooth and the lift suddenly
decreases.
Birds and planes change their angle of attack as they slow to land. Their angle of
attack is increased to ensure their lift continues to support their weight as they
slow down. Wings and tails need to be movable so that their shapes can be
changed to control their flight.
The Bernoulli principle
To understand this principle, we need to understand air pressure. Air is
composed of several invisible gases that have mass. This mass is made up
of molecules, moving in rapid random motion, and exerts a force called
air pressure. We are unaware of this pressure because it is evenly pressing all
around us. If the air pressure is not even, the greater pressure pushes an object
in the direction of the weaker (or lower) pressure.
In 1738, Bernoulli found that, when a gas (like air) moves, it exerts less pressure.
According to Bernoulli’s principle, the faster air moves, the less air pressure it
exerts (this is not the same as the force exerted by a wind), because the
molecules in the air become more spread out.
Normally, air moves along smoothly in streams, but airflow is disturbed when a
wing moves through it, and the air divides and flows around the wing. The top
surface of the wing is curved (aerofoil shape). The air moving across the top of
the wing goes faster than the air travelling under the bottom. Because it’s moving
faster, the air on top of the wing has less air pressure on the wing than the air
below the wing. In other words, air below the wing pushes on the wing more
than air above the wing.
When the air splits to go around the wing, the air that is forced over the wing travels
farther and the distance between the air molecules increases, making the air above the
wing less dense, or lower pressure. The pressure difference between higher pressure air
below the wing and lower pressure air above the wing causes lift.
This difference in pressure combines with the lift from the angle of attack to give
even more lift.
It used to be claimed that the air travelling over the top of the wing took the same
time to reach the back of the wing as the air travelling along the bottom. This has
been shown to be incorrect, but it has been shown that the speed of the air over
the top is faster than the speed of the air under the bottom.
The shape of the aerofoil is different for different aircraft. It is designed to give
the best trade-off between lift and drag for each aircraft. On many aeroplanes,
the bottom of the wing will curve downwards slightly instead of being flat. On
other aircraft, such as gliders, it will curve upwards. On a stunt plane, which is
just as likely to fly upside down as it is to fly the right way up, the curve on the
bottom of the wing will be the same as it is on the top.