Discovery I (LJ) V8-3.9L (1994)
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BAR MAGNET
HORSESHOE MAGNET
The phenomenon of magnetism greatly expands the usefulness of electricity. Without magnetism, we could not have motors, generators, relays and
solenoids, transformers and coils. Like electricity, we do not know exactly what magnetism is, but we do know how it reacts, what it does, and therefore
how we can put it to use.
All magnets have a magnetic field, which is evidenced by lines of force, or magnetic flux, around the magnet. The strength of the magnetic field varies. It
is strongest close to the magnet and gets progressively weaker away from it.
The area or extent of the magnetic field can be determined by means of a compass, which also shows the direction of the lines of force. Note: the lines of
force leave the north pole of the magnets and re enter at the south pole; that the lines of force exerted by the horseshoe magnet are more concentrated
between the two poles of the magnet.
TWO COMMON TYPES OF MAGNETS
Permanent: Permanent magnets are made from materials such as hardened steel that will become magnetic when subjected to an outside magnetizing
force and that will remain magnetic even after the outside force is removed.
Temporary: Temporary magnets are made from materials such as soft iron that will remain magnetic only as long as an outside magnetizing force is
present. When the magnetizing force is removed, the material returns to its nonmagnetic state.
NOTE: Electron flow creates a proportional magnetic flux around the conductor. Inductive electrical test pickups measure this magnetic flux that is
proportional to current flow and convert this signal to an electrical reading.
ELECTROMAGNETS
Most temporary magnetic fields are produced by electricity flow. Whenever current flows through a conductor, magnetic lines of force develop around
the conductor. This field forms a circular pattern; it can be visualized as a magnetic cylinder extending the full length of the wire. The strength of this
field (the concentration of the lines of force) depends upon the amount of current flowing through the conductor. The greater the current flow, the
stronger the field. This is the field produced by electromagnetism.
As mentioned, the magnetic field surrounds the conductor, which is carrying an electrical current. If this conductor is formed into a loop, the lines of
force on the outside of the loops spread out into space; lines on the inside of the loop are confined and crowded together. This increases the density of
lines of force in that area, and a much greater magnetic effect is produced with the same amount of current flowing.
