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Electric
motor
An electric motor uses
electrical energy to produce
mechanical energy. The reverse process, that of using mechanical
energy to produce electrical energy, is accomplished by a
generator or dynamo.
Traction motors used on
locomotives and some electric and hybrid automobiles often perform
both tasks if the vehicle is equipped with
dynamic brakes. Electric motors are found in household appliances
such as fans, refrigerators, washing machines, pool pumps, floor
vacuums, and fan-forced ovens. |
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History and development
The principle of conversion of electrical energy into
mechanical energy by electromagnetic means was demonstrated by the
British scientist
Michael Faraday in
1821 and consisted of a free-hanging wire dipping into a pool of
mercury. A permanent
magnet was placed in the middle of the pool of mercury. When a
current was passed through the wire, the wire rotated around the
magnet, showing that the current gave rise to a circular magnetic field
around the wire. This motor is often demonstrated in school physics
classes, but
brine (salt water) is sometimes used in place of the toxic mercury.
This is the simplest form of a class of electric motors called
homopolar motors. A later refinement is the
Barlow's Wheel. These were demonstration devices, unsuited to
practical applications due to limited power.
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Electro Magnetic
The first electric motor using
electromagnets for both stationary and rotating parts was demonstrated
by
Ányos Jedlik in
1828
Hungary, who
later developed a motor powerful enough to propel a vehicle. The first
commutator-type
direct-current electric motor capable of a practical application was
invented by the British scientist
William Sturgeon
in 1832. Following Sturgeon's work, a commutator-type direct-current
electric motor made with the intention of commercial use was built by
the American
Thomas Davenport
and patented in 1837. Although several of these motors were built and
used to operate equipment such as a printing press, due to the high cost
of
primary battery power,
the motors were commercially unsuccessful and Davenport went bankrupt.
Several inventors followed Sturgeon in the development of DC motors but
all encountered the same cost issues with primary battery power. No
electricity distribution had been developed at the time. Like Sturgeon's
motor, there was no practical commercial market for these motors.
The modern DC motor was
invented by accident in 1873, when
Zénobe Gramme
connected the
dynamo he had
invented to a second similar unit, driving it as a motor. The
Gramme machine
was the first electric motor that was successful in the industry.
In 1888
Nikola Tesla
invented the first practicable
AC motor and with
it the polyphase power transmission system. Tesla continued his work on
the AC motor in the years to follow at the Westinghouse company
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Categorization of electric
motors
The classic division of
electric motors has been that of
Direct Current
(DC) types vs
Alternating Current
(AC) types. This is more a de facto convention, rather than a
rigid distinction. For example, many classic DC motors run happily on AC
power.[citation
needed]
The ongoing trend toward
electronic control further muddles the distinction, as modern drivers
have moved the commutator out of the motor shell. For this new breed of
motor, driver circuits are relied upon to generate sinusoidal AC drive
currents, or some approximation of. The two best examples are: the
brushless DC motor
and the
stepping motor,
both being polyphase AC motors requiring external electronic control.
There is a clearer distinction
between a
synchronous motor
and asynchronous types. In the synchronous types, the rotor rotates in
synchrony with the oscillating field or current (eg. permanent magnet
motors). In contrast, an asynchronous motor is designed to slip; the
most ubiquitous example being the common AC
induction motor
which must slip in order to generate torque.
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DC motors
A DC motor is designed to run
on DC electric power. Two examples of pure DC designs are
Michael Faraday's
homopolar motor
(which is uncommon), and the
ball bearing motor,
which is (so far) a novelty. By far the most common DC motor types are
the brushed and brushless types, which use internal and external
commutation respectively to create an oscillating AC current from the DC
source -- so they are not purely DC machines in a strict sense.
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Brushed DC motors
Main article:
Brushed DC electric motor
The classic DC motor design
generates an oscillating current in a wound rotor with a split ring
commutator, and
either a wound or permanent magnet stator. A rotor consists of a coil
wound around a rotor which is then powered by any type of battery.
Many of the limitations of the
classic
commutator DC
motor are due to the need for brushes to press against the commutator.
This creates
friction. At
higher speeds, brushes have increasing difficulty in maintaining
contact. Brushes may bounce off the irregularities in the commutator
surface, creating sparks. This limits the maximum speed of the machine.
The current density per unit area of the brushes limits the output of
the motor. The imperfect electric contact also causes
electrical noise.
Brushes eventually wear out and require replacement, and the commutator
itself is subject to wear and maintenance. The commutator assembly on a
large machine is a costly element, requiring precision assembly of many
parts.
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Brushless DC motors
Main article:
Brushless DC electric motor
Some of the problems of the
brushed DC motor are eliminated in the brushless design. In this motor,
the mechanical "rotating switch" or commutator/brushgear assembly is
replaced by an external electronic switch synchronised to the rotor's
position. Brushless motors are typically 85-90% efficient, whereas DC
motors with brushgear are typically 75-80% efficient.
Midway between ordinary
DC motors and
stepper motors
lies the realm of the
brushless DC motor.
Built in a fashion very similar to stepper motors, these often use a
permanent magnet external rotor, three phases of driving coils,
one or more
Hall effect sensors
to sense the position of the rotor, and the associated drive
electronics. The coils are activated, one phase after the other, by the
drive electronics as cued by the signals from the Hall effect sensors.
In effect, they act as three-phase synchronous motors containing their
own
variable-frequency drive
electronics. A specialized class of brushless DC motor controllers
utilize EMF feedback through the main phase connections instead of Hall
effect sensors to determine position and velocity. These motors are used
extensively in electric
radio-controlled
vehicles. When configured with the magnets on the outside, these are
referred to by modelists as outrunner motors.
Brushless DC motors are
commonly used where precise speed control is necessary, as in computer
disk drives or in
video cassette recorders,
the spindles within
CD,
CD-ROM (etc.)
drives, and mechanisms within office products such as
fans,
laser printers
and
photocopiers.
They have several advantages over conventional motors:
- Compared
to AC fans using shaded-pole motors, they are very efficient,
running much cooler than the equivalent AC motors. This cool
operation leads to much-improved life of the fan's
bearings.
- Without
a
commutator to
wear out, the life of a DC brushless motor can be significantly
longer compared to a DC motor using brushes and a commutator.
Commutation also tends to cause a great deal of electrical and RF
noise; without a commutator or brushes, a brushless motor may be
used in electrically sensitive devices like audio equipment or
computers.
- The same
Hall effect sensors that provide the commutation can also provide a
convenient
tachometer
signal for closed-loop control (servo-controlled) applications. In
fans, the tachometer signal can be used to derive a "fan OK" signal.
- The
motor can be easily synchronized to an internal or external clock,
leading to precise speed control.
-
Brushless motors have no chance of sparking, unlike brushed motors,
making them better suited to environments with volatile chemicals
and fuels.
-
Brushless motors are usually used in small equipment such as
computers and are generally used to get rid of unwanted heat.
- They are
also very quiet motors which is an advantage if being used in
equipment that is affected by vibrations.
Modern DC brushless motors
range in power from a fraction of a
watt to many
kilowatts. Larger brushless motors up to about 100 kW rating are used in
electric vehicles. They also find significant use in high-performance
electric model aircraft.
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Coreless DC motors
Nothing in the design of any of
the motors described above requires that the iron (steel) portions of
the rotor actually rotate; torque is exerted only on the windings of the
electromagnets. Taking advantage of this fact is the coreless DC
motor, a specialized form of a brush or brushless DC motor.
Optimized for rapid
acceleration,
these motors have a rotor that is constructed without any iron core. The
rotor can take the form of a winding-filled cylinder inside the
stator magnets, a
basket surrounding the stator magnets, or a flat pancake
(possibly formed on a
printed wiring board)
running between upper and lower stator magnets. The windings are
typically stabilized by being impregnated with Electrical
epoxy potting
systems. Filled epoxies that have moderate mixed viscosity and a long
gel time. These systems are highlighted by low shrinkage and low
exotherm. Typically UL 1446 recognized as a potting compound for use up
to 180C (Class H) UL File No. E 210549.
Because the rotor is much
lighter in weight (mass)
than a conventional rotor formed from
copper windings
on
steel
laminations, the rotor can accelerate much more rapidly, often achieving
a mechanical
time constant
under 1
ms. This is
especially true if the windings use
aluminum rather
than the heavier copper. But because there is no metal mass in the rotor
to act as a heat sink, even small coreless motors must often be cooled
by forced air.
These motors were commonly used
to drive the
capstan(s) of
magnetic tape
drives and are still widely used in high-performance servo-controlled
systems, like radio-controlled vehicles/aircraft, humanoid
robotic systems,
industrial automation, medical devices, etc.
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Universal motors
A variant of the wound field DC
motor is the universal motor. The name derives from the fact that it may
use AC or DC supply current, although in practice they are nearly always
used with AC supplies. The principle is that in a wound field DC motor
the current in both the field and the
armature (and
hence the resultant magnetic fields) will alternate (reverse polarity)
at the same time, and hence the mechanical force generated is always in
the same direction. In practice, the motor must be specially designed to
cope with the AC current (impedance
must be taken into account, as must the pulsating force), and the
resultant motor is generally less efficient than an equivalent pure DC
motor. Operating at normal power line frequencies, the maximum output of
universal motors is limited and motors exceeding one kilowatt are rare.
But universal motors also form the basis of the traditional railway
traction motor in
electric railways.
In this application, to keep their electrical efficiency high, they were
operated from very low frequency AC supplies, with 25 Hz and 16 2/3
hertz operation being common. Because they are universal motors,
locomotives using this design were also commonly capable of operating
from a
third rail
powered by
DC.
The advantage of the universal
motor is that AC supplies may be used on motors which have the typical
characteristics of DC motors, specifically high starting torque and very
compact design if high running speeds are used. The negative aspect is
the maintenance and short life problems caused by the
commutator. As a
result such motors are usually used in AC devices such as food mixers
and power tools which are used only intermittently. Continuous speed
control of a universal motor running on AC is very easily accomplished
using a
thyristor
circuit, while stepped speed control can be accomplished using multiple
taps on the field coil. Household blenders that advertise many speeds
frequently combine a field coil with several taps and a
diode that can be
inserted in series with the motor (causing the motor to run on half-wave
rectified AC).
Universal motors can rotate at
relatively high revolutions per minute (rpm). This makes them useful for
appliances such as
blenders,
vacuum cleaners,
and
hair dryers where
high-speed operation is desired. Many vacuum cleaner and
weed trimmer
motors exceed 10,000 rpm,
Dremel and other
similar miniature grinders will often exceed 30,000 rpm. Motor damage
may occur due to overspeed (rpm in excess of design specifications) if
the unit is operated with no significant load. On larger motors, sudden
loss of load is to be avoided, and the possibility of such an occurrence
is incorporated into the motor's protection and control schemes. Often,
a small fan blade attached to the armature acts as an artificial load to
limit the motor speed to a safe value, as well as provide cooling
airflow to the armature and field windings.
With the very low cost of
semiconductor
rectifiers, some
applications that would have previously used a universal motor now use a
pure DC motor, sometimes with a permanent magnet field.
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AC motors
Main article:
AC motor
In 1882,
Nikola Tesla
identified the
rotating magnetic field
principle, and pioneered the use of a rotary field of force to operate
machines. He exploited the principle to design a unique two-phase
induction motor in 1883. In 1885,
Galileo Ferraris
independently researched the concept. In 1888, Ferraris published his
research in a paper to the Royal Academy of Sciences in Turin.
Introduction of Tesla's motor
from 1888 onwards initiated what is sometimes referred to as the
Second Industrial Revolution,
making possible the efficient generation and long distance distribution
of electrical energy using the alternating current transmission system,
also of Tesla's invention (1888).[1]
Before the invention of the rotating magnetic field, motors operated by
continually passing a conductor through a stationary magnetic field (as
in
homopolar motors).
Tesla had suggested that the
commutators from
a machine could be removed and the device could operate on a rotary
field of force. Professor Poeschel, his teacher, stated that would be
akin to building a
perpetual motion machine.[2]
Tesla would later attain
U.S. Patent 0,416,194 ,
Electric Motor (December 1889), which resembles the motor seen in
many of Tesla's photos. This classic alternating current
electro-magnetic motor was an induction motor.
Michail Osipovich Dolivo-Dobrovolsky
later invented a three-phase "cage-rotor" in 1890. This type of motor is
now used for the vast majority of commercial applications.
Components
A typical AC motor consists of
two parts:
- An
outside stationary stator having coils supplied with AC current to
produce a rotating magnetic field, and;
- An
inside rotor attached to the output shaft that is given a torque by
the rotating field.
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Torque motors
A torque motor is a specialized form of
induction motor
which is capable of operating indefinitely at
stall (with the
rotor blocked
from turning) without damage. In this mode, the motor will apply a
steady
stall torque to
the load (hence the name). A common application of a torque motor would
be the supply- and take-up
reel motors in a
tape drive. In
this application, driven from a low voltage, the characteristics of
these motors allow a relatively-constant light tension to be applied to
the tape whether or not the
capstan is
feeding tape past the tape heads. Driven from a higher voltage, (and so
delivering a higher torque), the torque motors can also achieve
fast-forward and rewind operation without requiring any additional
mechanics such as
gears or
clutches. In the
computer world, torque motors are used with
force feedback
steering wheels |
Slip ring
The slip ring or wound rotor
motor is an induction machine where the rotor comprises a set of coils
that are terminated in
slip rings to
which external impedances can be connected. The stator is the same as is
used with a standard squirrel cage motor.
By changing the impedance
connected to the rotor circuit, the speed/current and speed/torque
curves can be altered.
The slip ring motor is used
primarily to start a high inertia load or a load that requires a very
high starting torque across the full speed range. By correctly selecting
the resistors used in the secondary resistance or slip ring starter, the
motor is able to produce maximum torque at a relatively low current from
zero speed to full speed. A secondary use of the slip ring motor is to
provide a means of speed control. Because the torque curve of the motor
is effectively modified by the resistance connected to the rotor
circuit, the speed of the motor can be altered. Increasing the value of
resistance on the rotor circuit will move the speed of maximum torque
down. If the resistance connected to the rotor is increased beyond the
point where the maximum torque occurs at zero speed, the torque will be
further reduced.
When used with a load that has a torque curve that increases with speed,
the motor will operate at the speed where the torque developed by the
motor is equal to the load torque. Reducing the load will cause the
motor to speed up, and increasing the load will cause the motor to slow
down until the load and motor torque are equal. Operated in this manner,
the slip losses are dissipated in the secondary resistors and can be
very significant. The speed regulation is also very poor.
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Stepper motors
Main article:
Stepper motor
Closely related in design to
three-phase AC synchronous motors are
stepper motors,
where an internal rotor containing permanent magnets or a large iron
core with salient poles is controlled by a set of external magnets that
are switched electronically. A stepper motor may also be thought of as a
cross between a DC electric motor and a
solenoid. As each
coil is energized in turn, the rotor aligns itself with the magnetic
field produced by the energized field winding. Unlike a synchronous
motor, in its application, the motor may not rotate continuously;
instead, it "steps" from one position to the next as field windings are
energized and de-energized in sequence. Depending on the sequence, the
rotor may turn forwards or backwards.
Simple stepper motor drivers
entirely energize or entirely de-energize the field windings, leading
the rotor to "cog"
to a limited number of positions; more sophisticated drivers can
proportionally control the power to the field windings, allowing the
rotors to position between the cog points and thereby rotate extremely
smoothly. Computer controlled stepper motors are one of the most
versatile forms of positioning systems, particularly when part of a
digital
servo-controlled
system.
Stepper motors can be rotated
to a specific angle with ease, and hence stepper motors are used in
pre-gigabyte era computer disk drives, where the precision they offered
was adequate for the correct positioning of the read/write head of a
hard disk drive. As drive density increased, the precision limitations
of stepper motors made them obsolete for hard drives, thus newer hard
disk drives use read/write head control systems based on
voice coils.
Stepper motors were upscaled to
be used in electric vehicles under the term SRM (switched reluctance
machine).
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Linear motors
Main article:
Linear motor
A
linear motor is
essentially an electric motor that has been "unrolled" so that, instead
of producing a
torque
(rotation), it produces a linear force along its length by setting up a
traveling electromagnetic field.
Linear motors are most commonly
induction motors or stepper motors. You can find a linear motor in a
maglev (Transrapid)
train, where the train "flies" over the ground, and in many
roller-coasters where the rapid motion of the motorless railcar is
controlled by the rail.
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Doubly-fed electric motor
Doubly-fed electric motors
have two independent multiphase windings that actively participate in
the energy conversion process with at least one of the winding sets
electronically controlled for variable speed operation. Two is the most
active multiphase winding sets possible without duplicating singly-fed
or doubly-fed categories in the same package. As a result, doubly-fed
electric motors are machines with an effective constant torque speed
range that is twice synchronous speed for a given frequency of
excitation. This is twice the constant torque speed range as
singly-fed electric machines,
which have only one active winding set.
A doubly-fed motor allows for a smaller electronic converter but the
cost of the rotor winding and slip rings may offset the saving in the
power electronics components. Difficulties with controlling speed near
synchronous speed limit applications |
Singly-fed electric motor
Singly-fed electric machines
incorporate a single multiphase winding set that is connected to a power
supply. Singly-fed electric machines may be either induction or
synchronous. The active winding set can be electronically controlled.
Induction machines develop starting torque at zero speed and can operate
as standalone machines. Synchronous machines must have auxiliary means
for startup, such as a starting induction squirrel-cage winding or an
electronic controller. Singly-fed electric machines have an effective
constant torque speed range up to synchronous speed for a given
excitation frequency.
The induction (asynchronous) motors (i.e., squirrel cage rotor or wound
rotor), synchronous motors (i.e., field-excited, permanent magnet or
brushless DC motors, reluctance motors, etc.), which are discussed on
the this page, are examples of singly-fed motors. By far, singly-fed
motors are the predominantly installed type of motors |
Nanotube nanomotor
Main article:
Nanomotor
Researchers at
University of California, Berkeley,
recently developed rotational bearings based upon multiwall carbon
nanotubes. By attaching a gold plate (with dimensions of the order of
100nm) to the outer shell of a suspended multiwall carbon nanotube (like
nested carbon cylinders), they are able to electrostatically rotate the
outer shell relative to the inner core. These bearings are very robust;
devices have been oscillated thousands of times with no indication of
wear. These nanoelectromechanical systems (NEMS) are the next step in
miniaturization that may find their way into commercial aspects in the
future.
See also:
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Materials
Further information:
Materials science
There is an impeding shortage
of many rare raw materials used in the manufacture of hybrid and
electric cars (Nishiyama 2007) (Cox 2008). For example, the
rare earth element
dysprosium is
required to fabricate many of the advanced
electric motors
used in hybrid cars (Cox 2008). However, over 95% of the world's rare
earth elements are mined in
China (Haxel et
al. 2005), and domestic Chinese consumption is expected to consume
China's entire supply by 2012 (Cox 2008).[citation
needed]
A few non-Chinese sources such
as
Thor Lake and
Hoidas Lake in
Canada, as well
as
Mt Weld in
Australia are
currently under development (Lunn 2006). However, it is not known if
they will be online in time to supply sufficient production by the time
shortage hits.[citation
needed]
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Motor standards
The following are major design
and manufacturing standards covering electric motors:
See also
Motor control:
Components:
Scientists and engineers:
Related subjects:
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