Electromagnetism
PARTS AND MATERIALS
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6-volt battery
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Magnetic compass
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Small permanent magnet
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Spool of 28-gauge magnet wire
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Large bolt, nail, or steel rod
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Electrical tape
Magnet wire is a term for thin-gauge
copper wire with enamel insulation instead of rubber or
plastic insulation. Its small size and very thin insulation
allow for many "turns" to be wound in a compact coil. You
will need enough magnet wire to wrap hundreds of turns
around the bolt, nail, or other rod-shaped steel form.
Be sure to select a bolt, nail, or rod that
is magnetic. Stainless steel, for example, is
non-magnetic and will not function for the purpose of an
electromagnet coil! The ideal material for this experiment
is soft iron, but any commonly available steel will
suffice.
CROSS-REFERENCES
Lessons In Electric Circuits, Volume
1, chapter 14: "Magnetism and Electromagnetism"
LEARNING OBJECTIVES
SCHEMATIC DIAGRAM
ILLUSTRATION
INSTRUCTIONS
Wrap a single layer of electrical tape
around the steel bar (or bolt, or mail) to protect the wire
from abrasion. Proceed to wrap several hundred turns of wire
around the steel bar, making the coil as even as possible.
It is okay to overlap wire, and it is okay to wrap in the
same style that a fishing reel wraps line around the spool.
The only rule you must follow is that all turns must
be wrapped around the bar in the same direction (no
reversing from clockwise to counter-clockwise!). I find that
a drill press works as a great tool for coil winding: clamp
the rod in the drill's chuck as if it were a drill bit, then
turn the drill motor on at a slow speed and let it do the
wrapping! This allows you to feed wire onto the rod in a
very steady, even manner.
After you've wrapped several hundred turns
of wire around the rod, wrap a layer or two of electrical
tape over the wire coil to secure the wire in place. Scrape
the enamel insulation off the ends of the coil wires for
connection to jumper leads, then connect the coil to a
battery.
When electric current goes through the coil,
it will produce a strong magnetic field: one "pole" at each
end of the rod. This phenomenon is known as
electromagnetism. The magnetic compass is used to
identify the "North" and "South" poles of the electromagnet.
With the electromagnet energized (connected
to the battery), place a permanent magnet near one pole and
note whether there is an attractive or repulsive force.
Reverse the orientation of the permanent magnet and note the
difference in force.
Electromagnetism has many applications,
including relays, electric motors, solenoids, doorbells,
buzzers, computer printer mechanisms, and magnetic media
"write" heads (tape recorders, disk drives).
You might notice a significant spark
whenever the battery is disconnected from the electromagnet
coil: much greater than the spark produced if the battery is
simply short-circuited. This spark is the result of a
high-voltage surge created whenever current is suddenly
interrupted through the coil. The effect is known as
inductive "kickback" and is capable of delivering a
small but harmless electric shock! To avoid receiving this
shock, do not place your body across the break in the
circuit when de-energizing! Use one hand at a time when
un-powering the coil and you'll be perfectly safe. This
phenomenon will be explored in greater detail in the next
chapter (DC Circuits). |
