Wireless Power
Transmission
Source: How it works
Scientists have
tried to develop methods of
wireless power transmission
that could cut the clutter or lead
to clean sources of electricity.
While the idea may sound futuristic,
it isn't particularly new. Nicola
Tesla proposed theories of wireless
power transmission in the late 1800s
and early 1900s. One of his more
spectacular displays involved
remotely powering lights in the
ground at his Colorado Springs
experiment station.
Tesla's work was
impressive, but it didn't
immediately lead to widespread,
practical methods for wireless power
transmission. Since then,
researchers have developed several
techniques for moving electricity
over long distances without wires.
Some exist only as theories or
prototypes, but others are already
in use. If you have an electric
toothbrush, for example, you
probably take advantage of one
method every day.
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Most electric
toothbrushes recharge
through inductive
coupling. An
electric toothbrush's
base and handle contain
coils that allow the
battery to recharge.
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A toothbrush's
daily exposure to water makes a
traditional plug-in charger
potentially dangerous. Ordinary
electrical connections could also
allow water to seep into the
toothbrush, damaging its components.
Because of this, most toothbrushes
recharge through inductive
coupling.
Inductive
coupling uses magnetic fields that
are a natural part of current's
movement through wire. Any time
electrical current moves through a
wire, it creates a circular
magnetic field around the
wire. Bending the wire into a coil
amplifies the magnetic field. The
more loops the coil makes, the
bigger the field will be.
If you place a
second coil of wire in the magnetic
field you've created, the field can
induce a current in
the wire. This is essentially how a
transformer works,
and it's how an electric toothbrush
recharges. It takes three basic
steps:
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Current from
the wall outlet flows through a
coil inside the charger,
creating a magnetic field. In a
transformer, this coil is called
the primary winding.
-
When you
place your toothbrush in the
charger, the magnetic field
induces a current in another
coil, or secondary
winding, which connects
to the battery.
-
This current
recharges the battery.
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©
Copyright Splashpower
2006
A Splashpower mat uses
induction to recharge
multiple devices
simultaneously.
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You can use the
same principle to recharge several
devices at once. For example, the
Splashpower recharging mat and
Edison Electric's Powerdesk both use
coils to create a magnetic field.
Electronic devices use corresponding
built-in or plug-in receivers to
recharge while resting on the mat.
These receivers contain compatible
coils and the circuitry necessary to
deliver electricity to devices'
batteries.
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Wireless energy
could power consumer, industrial electronics
Dead cell phone inspired
researcher's innovation
Source: Massachusetts Institute of Technology
Recharging your laptop
computer, your cell phone and a variety of other
gadgets may one day be as convenient as surfing
the web--wirelessly.
Marin Soljacic, an assistant
professor in MIT's Department of Physics and
Research Laboratory of Electronics, will
describe his and his MIT colleagues' research on
that wireless future on Tuesday, Nov. 14 at the
American Institute of Physics Industrial Physics
Forum in San Francisco.
Like many of us, Soljacic
(pronounced Soul-ya-CHEECH) often forgets to
recharge his cell phone, and when it is about to
die it emits an unpleasant noise. "Needless to
say, this always happens in the middle of the
night," he said. "So, one night, at 3 a.m., it
occurred to me: Wouldn't it be great if this
thing charged itself?" He began to wonder if any
of the physics principles he knew of could turn
into new ways of transmitting energy.
After all, scientists and
engineers have known for nearly two centuries
that transferring electric power does not
require wires to be in physical contact.
Electric motors and power transformers contain
coils that transmit energy to each other by the
phenomenon of electromagnetic induction. A
current running in an emitting coil induces
another current in a receiving coil; the two
coils are in close proximity, but they do not
touch.
Later, scientists discovered
electromagnetic radiation in the form of radio
waves, and they showed that another form of
it--light--is how we get energy from the sun.
But transferring energy from one point to
another through ordinary electromagnetic
radiation is typically very inefficient: The
waves tend to spread in all directions, so most
of the energy is lost to the environment.
Soljacic realized that the
close-range induction taking place inside a
transformer--or something similar to it--could
potentially transfer energy over longer
distances, say, from one end of a room to the
other. Instead of irradiating the environment
with electromagnetic waves, a power transmitter
would fill the space around it with a "non-radiative"
electromagnetic field. Energy would only be
picked up by gadgets specially designed to
"resonate" with the field. Most of the energy
not picked up by a receiver would be reabsorbed
by the emitter.
In his talk, Soljacic will
explain the physics of non-radiative energy
transfer and the possible design of
wireless-power systems.
While rooted in well-known
laws of physics, non-radiative energy transfer
is a novel application no one seems to have
pursued before. "It certainly was not clear or
obvious to us in the beginning how well it could
actually work, given the constraints of
available materials, extraneous environmental
objects, and so on. It was even less clear to us
which designs would work best," Soljacic said.
He and his colleagues tackled the problem
through theoretical calculations and computer
simulations.
With the resulting designs,
non-radiative wireless power would have limited
range, and the range would be shorter for
smaller-size receivers. But the team calculates
that an object the size of a laptop could be
recharged within a few meters of the power
source. Placing one source in each room could
provide coverage throughout your home.
Soljacic is looking forward
to a future when laptops and cell phones might
never need any wires at all. Wireless, he said,
could also power other household gadgets that
are now becoming more common. "At home, I have
one of those robotic vacuum cleaners that cleans
your floors automatically," he said. "It does a
fantastic job but, after it cleans one or two
rooms, the battery dies." In addition to
consumer electronics, wireless energy could find
industrial applications powering, for example,
freely roaming robots within a factory pavilion. |
