Polyphase motor design
Perhaps the most important benefit of
polyphase AC power over single-phase is the design and
operation of AC motors. As we studied in the first chapter
of this book, some types of AC motors are virtually
identical in construction to their alternator (generator)
counterparts, consisting of stationary wire windings and a
rotating magnet assembly. (Other AC motor designs are not
quite this simple, but we will leave those details to
another lesson).
If the rotating magnet is able to keep up
with the frequency of the alternating current energizing the
electromagnet windings (coils), it will continue to be
pulled around clockwise. However, clockwise is not the only
valid direction for this motor's shaft to spin. It could
just as easily be powered in a counter-clockwise direction
by the same AC voltage waveform:
Notice that with the exact same sequence of
polarity cycles (voltage, current, and magnetic poles
produced by the coils), the magnetic rotor can spin in
either direction. This is a common trait of all single-phase
AC "induction" and "synchronous" motors: they have no normal
or "correct" direction of rotation. The natural question
should arise at this point: how can the motor get started in
the intended direction if it can run either way just as
well? The answer is that these motors need a little help
getting started. Once helped to spin in a particular
direction. they will continue to spin that way as long as AC
power is maintained to the windings.
Where that "help" comes from for a
single-phase AC motor to get going in one direction can
vary. Usually, it comes from an additional set of windings
positioned differently from the main set, and energized with
an AC voltage that is out of phase with the main power:
These supplementary coils are typically
connected in series with a capacitor to introduce a phase
shift in current between the two sets of windings:
That phase shift creates magnetic fields
from coils 2a and 2b that are equally out of step with the
fields from coils 1a and 1b. The result is a set of magnetic
fields with a definite phase rotation. It is this phase
rotation that pulls the rotating magnet around in a definite
direction.
Polyphase AC motors require no such trickery
to spin in a definite direction. Because their supply
voltage waveforms already have a definite rotation sequence,
so do the respective magnetic fields generated by the
motor's stationary windings. In fact, the combination of all
three phase winding sets working together creates what is
often called a rotating magnetic field. It was this
concept of a rotating magnetic field that inspired Nikola
Tesla to design the world's first polyphase electrical
systems (simply to make simpler, more efficient motors). The
line current and safety advantages of polyphase power over
single phase power were discovered later.
What can be a confusing concept is made much
clearer through analogy. Have you ever seen a row of
blinking light bulbs such as the kind used in Christmas
decorations? Some strings appear to "move" in a definite
direction as the bulbs alternately glow and darken in
sequence. Other strings just blink on and off with no
apparent motion. What makes the difference between the two
types of bulb strings? Answer: phase shift!
Examine a string of lights where every other
bulb is lit at any given time:
When all of the "1" bulbs are lit, the "2"
bulbs are dark, and visa-versa. With this blinking sequence,
there is no definite "motion" to the bulbs' light. Your eyes
could follow a "motion" from left to right just as easily as
from right to left. Technically, the "1" and "2" bulb
blinking sequences are 180o out of phase (exactly
opposite each other). This is analogous to the single-phase
AC motor, which can run just as easily in either direction,
but which cannot start on its own because its magnetic field
alternation lacks a definite "rotation."
Now let's examine a string of lights where
there are three sets of bulbs to be sequenced instead of
just two, and these three sets are equally out of phase with
each other:
If the lighting sequence is 1-2-3 (the
sequence shown), the bulbs will appear to "move" from left
to right. Now imagine this blinking string of bulbs arranged
into a circle:
Now the lights appear to be "moving" in a
clockwise direction because they are arranged around a
circle instead of a straight line. It should come as no
surprise that the appearance of motion will reverse if the
phase sequence of the bulbs is reversed.
The blinking pattern will either appear to
move clockwise or counter-clockwise depending on the phase
sequence. This is analogous to a three-phase AC motor with
three sets of windings energized by voltage sources of three
different phase shifts:
With phase shifts of less than 180o
we get true rotation of the magnetic field. With
single-phase motors, the rotating magnetic field necessary
for self-starting must to be created by way of capacitive
phase shift. With polyphase motors, the necessary phase
shifts are there already. Plus, the direction of shaft
rotation for polyphase motors is very easily reversed: just
swap any two "hot" wires going to the motor, and it will run
in the opposite direction!
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REVIEW:
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AC "induction" and "synchronous" motors
work by having a rotating magnet follow the alternating
magnetic fields produced by stationary wire windings.
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Single-phase AC motors of this type need
help to get started spinning in a particular direction.
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By introducing a phase shift of less than
180o to the magnetic fields in such a motor, a
definite direction of shaft rotation can be established.
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Single-phase induction motors often use an
auxiliary winding connected in series with a capacitor to
create the necessary phase shift.
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Polyphase motors don't need such measures;
their direction of rotation is fixed by the phase sequence
of the voltage they're powered by.
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Swapping any two "hot" wires on a
polyphase AC motor will reverse its phase sequence, thus
reversing its shaft rotation.
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