A group of researchers at KAIST has developed a wireless-power
transfer (WPT) technology that allows mobile devices to be charged at
any location and in any direction, even if the devices are away from the
power source, just as Wi-Fi works for Internet connections. With this
technology, so long as mobile users stay in a designated area where the
charging is available, e.g., the Wi-Power zone, the device, without
being tethered to a charger, will pick up power automatically, as
needed.
The research team led by Professor Chun T. Rim of the Nuclear and
Quantum Engineering Department at KAIST has made great strides in WPT
development. Their WPT system is capable of charging multiple mobile
devices concurrently and with unprecedented freedom in any direction,
even while holding the devices in midair or a half meter away from the
power source, which is a transmitter. The research result was published
in the June 2015 on-line issue of
IEEE Transactions on Power Electronics,
which is entitled "Six Degrees of Freedom Mobile Inductive Power
Transfer by Crossed Dipole Tx (Transmitter) and Rx (Receiver) Coils."
Professor Rim's team has successfully showcased the technology on
July 7, 2015 at a lab on KAIST's campus. They used high-frequency
magnetic materials in a dipole coil structure to build a thin, flat
transmitter (Tx) system shaped in a rectangle with a size of 1m2. Either
30 smartphones with a power capacity of one watt each or 5 laptops with
2.4 watts each can be simultaneously and wirelessly charged at a 50 cm
distance from the transmitter with six degrees of freedom, regardless of
the devices' three-axes positions and directions. This means that the
device can receive power all around the transmitter in three-dimensional
space. The maximum power transfer efficiency for the laptops was 34%.
The researchers said that to fabricate plane Tx and Rx coils with the
six-degree-of-freedom characteristic was a bottleneck of WPT for mobile
applications.
Dipole Coil Resonance System (DCRS)
The research team used the Dipole Coil Resonance System (DCRS) to
induce magnetic fields, which was developed by the team in 2014 for
inductive power transfer over an extended distance. The DCRS is composed
of two (transmitting and receiving) magnetic dipole coils, placed in
parallel, with each coil having a ferrite core and connected with a
resonant capacitor. Comparing to a conventional loop coil, the dipole
coil is very compact and has a less dimension. Therefore, a crossed
dipole structure has 2-dimension rather than 3-dimension of a crossed
loop coil structure. The DCRS has a great advantage to transfer power
even when the resonance frequency changes in the range of 1% (Q factor
is below 100). The ferrite cores are optimally designed to reduce the
core volume by half, and their ability to transfer power is nearly
unaffected by human bodies or surrounding metal objects, making DCRS
ideal to transmit wireless power in emergency situations. In a test
conducted in 2014, Professor Rim succeeded in transferring 209 watts of
power wirelessly to the distance of five meters.
Greater Flexibility and Safer Charging
The research team rearranged the two dipole coils from a parallel
position to cross them in order to generate rotating magnetic fields,
which was embedded in the Tx's flat platform. This has made it possible
for mobile devices to receive power from any direction.
Although wireless-power technology has been applied to smartphones,
it could not offer any substantial advantages over traditional wired
charging because the devices still require close contact with the
transmitter, a charging pad. To use the devices freely and safely,
including in public spaces, the WPT technology should provide mobile
users with six degrees of freedom at a distance. Until now, all
wireless-charging technologies have had difficulties with the problem of
short charging distance, mostly less than 10 cm, as well as charging
conditions that the devices should be placed in a fixed position. For
example, the Galaxy S6 could only be charged wirelessly in a fixed
position, having one degree of freedom. The degree of freedom represents
mobile devices' freedom of movement in three-dimensional space.
In addition, the DCRS works at a low magnetic field environment.
Based on the magnetic flux shielding technology developed by the
research team, the level of magnetic flux is below the safety level of
the International Commission on Non-Ionizing Radiation Protection
(ICNIRP) guideline (27µT) for general public exposure to electromagnetic
field (EMF).
Professor Rim said, "Our transmitter system is safe for humans and
compatible with other electronic devices. We have solved three major
issues of short charging distance, the dependence on charging
directions, and plane coil structures of both Tx and Rx, which have
blocked the commercialization of WPT."
Currently, the research team and KAIST's spin-off company, TESLAS,
Inc., have been conducting pilot projects to apply DCRS in various
places such as cafes and offices.
Video:
https://www.youtube.com/watch?v=JU64pMyJioc
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