How Guns Work or the Physics of an Explosive Propellant
A gun is a weapon that uses the force of an explosive propellant to project a missile.
Guns or firearms are classified by the diameter of the barrel opening. This is known as
the calibre of the gun. Anything with a calibre up to and including .60 calibre(0.6
inches) is known as a firearm.
The precise origin of the gun is unknown, although they were in use by the early 14th
century and were common place in Europe by mid-century. These early guns were nothing
more than large calibre cylinders of wrought iron or cast bronze, closed at one end and
loaded by placing gunpowder and projectile in the muzzle, or open end.
Nowadays firearms are a little more sophisticated.
However, the physics behind all guns remain the same. Weapons such as cannons, shotguns
and rifles, work on the basic idea of conservation of momentum and the change in energy
from potential to kinetic.
When the trigger is pulled the hammer hits the firing pin. The firing pin then hits the
primer which causes the powder to burn hence producing lots of gases. This causes the
volume behind the bullet to fill with extremely high pressure gas. The gas pushes on
every surface it encounters, including the bullet in front of it and the base of the gun
barrel behind it. The increase in pressure caused by the gases causes the bullet to be
forced into the barrel hence causing the bullet to come out the muzzle at very high
speeds. Once the bullet is fired, it remains in motion from its momentum. The momentum
will carry the bullet until it strikes an object or gravity pulls the bullet towards the
earth.
Firearms change potential chemical energy into kinetic energy in the actual firing of the
gun. Many people do not realise that the force imparted by accelerating the bullet is
not the only force acting on the gun, or the shooter. Grains of burned gun powder are
sent out the muzzle at high velocity. When the trigger is pulled, the hammer strikes a
small charge at the end of the shell, the ammunition. This charge ignites black gun
powder packed behind the lead ball bearings. When the black gun powder burns, it
produces gas that rapidly expands with the burning of more black gun powder. High
pressure gases exert forces on the back of the bullet and on the gun. The only way for
the gas to escape is to push the bullet out of its way through the end of the barrel.
This is how a bullet is fired from a gun.
Conservation of momentum is the law that is held true when the gun is fired and a "kick"
is felt. When a bullet is fired from a gun, total momentum before is zero since nothing
is moving. After firing the bullet there is a momentum in the forward direction. The
gun must therefore have the same magnitude of momentum but in the opposite direction so
that they cancel each other out leaving the total momentum still equal to zero. For this
reason the gun must have a recoil velocity after the bullet is fired(i.e. the gun 'jumps'
backwards and a 'kick' is felt) .
As the bullet is propelled through the barrel, it gains momentum. In order for the
entire system of the gun and the ammunition to have equal momentum, the gun must gain
momentum in the opposite direction from the bullet. Momentum is a vector quantity,
having both a direction and a direction. The faster an object is moving or the more mass
it has, the more momentum it has in the direction of its motion(momentum = mass
velocity). Because momentum is a conserved quantity, it cannot be created or
destroyed(momentum before = momentum after). It can only be transferred between objects.
Momentum is conserved because of Newton's third law of motion.
When one object exerts a force on a second object for a certain amount of time, the
second object exerts an equal but oppositely directed force on the first object for
exactly the same amount of time. The momentum lost by the first object is exactly equal
to the momentum gained by the second object. Momentum is transferred from the first
object to the second object. In this case, if a gun exerts a force on a bullet when
firing it forward then the bullet will exert an equal force in the opposite direction on
the gun causing it to move backwards or recoil. Although the action and reaction forces
are equal in size the effect on the gun and the bullet are not the same since the mass of
the gun is far greater than the mass of the bullet. The acceleration of the bullet while
moving along the gun barrel would be much greater than the acceleration of the
gun(acceleration = force mass).
The conservation of momentum is also demonstrated when the bullet hits an object. The
object that it strikes absorbs the kinetic energy, energy from motion and momentum. If
the force of momentum from the bullet is great enough to overcome the mass of the object,
the target will be moved along the same vector as the bullet.
To increase the accuracy of the flight of the bullet, a technique called rifling can be
used. Rifling is where the barrel of the gun and or the bullet is creased with spiral
grooves that allow air to pass through. When the bullet is fired, the air passes through
these curved grooves and spins the bullet. This spinning action allows the bullet to cut
through the air more efficiently and fly on a more true course, thus stabilising its
trajectory.
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