What is Aeronautics?
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What is Air?
Air
is a physical substance which
has weight. It has molecules which are constantly moving. Air pressure is created
by the molecules moving around. Moving air has a force that will lift kites
and balloons up and down. Air is a mixture of different gases; oxygen, carbon
dioxide and nitrogen. All things that fly need air. Air has power to push and
pull on the birds, balloons, kites and planes.
In 1640, Evagelista Torricelli discovered
that air has
weight.
When experimenting
with measuring mercury, he discovered that air put pressure on the mercury.
Francesco Lana used
this discovery to begin to plan for an airship in the late 1600s. He drew an
airship on paper that used the idea that air has weight. The ship was a hollow
sphere which would have the air taken out of it. Once the air was removed, the
sphere would have less weight and would be able to float up into the air. Each
of four spheres would be attached to a boat-like structure and then the whole
machine would float. The actual design was never tried.
Hot air expands and spreads out and it becomes lighter than cool
air. When a balloon is full of hot air it rises up because the hot air expands
inside the balloon. When the hot air cools and is let out of the balloon the
balloon comes back down.
How Wings Lift the Plane
Airplane wings are shaped to make air move faster
over the top of the wing. When air moves faster, the pressure of the air decreases.
So the pressure on the top of the wing is less than the pressure on the bottom of the wing.
The difference in pressure creates a force on the wing that
lifts
the wing up into the air.
Here is a simple
computer simulation
that you can use to explore how wings make lift.
Laws of Motion
Sir Isaac Newton proposed three laws of motion in 1665. These
Laws of Motion
help to explain how a planes flies.
1. If an object is not moving, it will not start moving by itself. If an
object is moving, it will not stop or change direction unless something pushes
it.
2. Objects will move farther and faster when they are pushed harder.
3. When an object is pushed in one direction, there is always a resistance
of the same size in the opposite direction.
Forces of Flight
Controlling the Flight of a Plane
How does a plane fly? Let's pretend that our arms are wings.
If we place one wing down and one wing up we can use the roll
to
change the direction
of the plane. We are helping to turn the plane
by yawing toward one side. If we raise our nose, like
a pilot can
raise the nose
of the plane, we are raising the pitch
of the plane. All these dimensions together combine to control the flight
of the plane. A pilot of a plane has special controls that can be used to fly
the plane. There are levers and buttons that the pilot can push to change the
yaw, pitch and roll of the plane.
To
roll
the plane to the right or left, the ailerons are raised on one
wing and lowered on the other. The wing with the lowered aileron rises while
the wing with the raised aileron drops.
Pitch
makes a plane descend or climb. The pilot adjusts
the elevators on the tail to make a plane descend or climb. Lowering the elevators
caused the airplane's nose to drop, sending the plane into a down. Raising the
elevators causes the airplane to climb.
Yaw
is the turning of a plane. When the rudder is turned
to one side, the airplane moves left or right. The airplane's nose is pointed
in the same direction as the direction of the rudder. The rudder and the ailerons
are used together to make a turn
How does a Pilot Control the Plane?
Click on the Radar Display, the Direction Finder, the
Altitude Indicator and the Throttle Console parts of the
cockpit for a more detailed view.
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To control a plane a pilot uses several instruments...
The pilot controls the engine power
using the throttle. Pushing the throttle increases
power, and pulling it decreases power.
The
ailerons
raise and
lower the wings. The pilot controls the roll of the
plane by raising one aileron or the other with a control wheel. Turning the
control wheel clockwise raises the right aileron and lowers the left aileron,
which rolls the aircraft to the right.
l
Picture of plane in roll
The
rudder
works to
control the yaw of the plane. The pilot moves rudder left and right, with left
and right pedals. Pressing the right rudder pedal moves the rudder to the right.
This yaws the aircraft to the right. Used together,
the rudder and the ailerons are used to turn the plane.
Picture of plane Yaw
The
elevators
which are
on the tail section are used to control the pitch of
the plane. A pilot uses a control wheel to raise
and lower the elevators, by moving it forward to back ward. Lowering the elevators
makes the plane nose go down and allows the plane to go down. By raising the
elevators the pilot can make the plane go up.
Picture of Plane Pitch
The pilot of the plane pushes the top of the rudder pedals to use the brakes.
The brakes are used when the plane is on the ground to slow down the plane and
get ready for stopping it. The top of the left rudder controls the left brake
and the top of the right pedal controls the right brake.
If you look at these motions together you can see that each type of motion
helps control the direction and level of the plane when it is flying.
Sound Barrier
Sound is made up of molecules of air that move. They push together and gather
together to form
sound waves
. Sound
waves travel at the speed of about 750 mph at sea level. When a plane travels
the
speed of sound
the air waves gather together
and compress the air in front of the plane to keep it from moving forward. This
compression causes a
shockwave
to form in front of
the plane.
In order to travel faster than the speed of sound the plane needs to be able
to break through the shock wave. When the airplane moves through the waves,
it is makes the sound waves spread out and this creates a loud noise or sonic
boom . The sonic boom is caused by a sudden change in the air pressure.
When the plane travels faster than sound it is traveling at supersonic speed.
A plane traveling at the speed of sound is traveling at
Mach 1
or about 760 MPH. Mach 2 is twice the speed of sound.
Regimes of Flight
Sometimes called speeds of flight,
each regime is a different level of flight speed.
Seaplane
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General Aviation
(100-350
MPH).
Most of the early planes were only able to fly at
this speed level. Early engines were not as powerful as they are today.
However, this regime is still used today by smaller planes. Examples
of this regime are the small crop dusters used by farmers for their
fields, two and four seater passenger planes, and seaplanes that can
land on water.
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Boeing 747
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Subsonic
(350-750 MPH).
This category contains most of the
commercial jets that are used today to move passengers and cargo. The
speed is just below the speed of sound. Engines today are lighter and
more powerful and can travel quickly with large loads of people or goods.
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Concorde
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Supersonic
(760-3500 MPH - Mach 1
- Mach 5).
760 MPH is the speed of sound. It is also called MACH 1. These planes
can fly up to 5 times the speed of sound. Planes in this regime have
specially designed high performance engines. They are also designed
with lightweight materials to provide less drag. The Concorde is an
example of this regime of flight.
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Space Shuttle
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Hypersonic
(3500-7000 MPH - Mach 5
to Mach 10).
Rockets travel at speeds 5 to 10 times the speed of sound as they
go into orbit. An example of a hypersonic vehicle is the X-15, which
is rocket powered. The space shuttle is also an example of this regime.
New materials and very powerful engines were developed to handle this
rate of speed.
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What is Aeronautics?
| Dynamics of Flight | Airplanes
| Engines | History
of Flight | What is UEET?
Vocabulary | Fun
and Games | Educational Links | Lesson
Plans | Site Index | Home
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