Researchers transmit power wirelessly for over 30 meters using Infrared light
We know that to transmit electricity, we need to use conducting wires through which the electricity must travel. The higher the conductivity of the wire the lower is the loss of transmission of electrical power. Although short distance transmission of electricity is now commercially used in the wireless chargers, these can transmit power over very short distances by using the magnetic induction. In this method the electricity is used to create an AC magnetic field which is used to induce the electrical power into a receiving coil to capture the power from the magnetic field. When the distance increases, the magnetic field drops inversely with the square of the distance and quickly becomes non-useful for the purpose.
What if we could actually beam electricity over a distance? Well, if we can do this commercially it could lead to a host of new applications which don’t create a mess of wires and even do away with batteries to a large extent.
Now, a team of researchers from Sejong University in South Korea have successully demonstrated a system that can wirelessly send power over a distance of 30 meters using infrared light.
While testing the wireless laser charging system, the researchers safely transmitted 400 mW of light and used it to power an LED light.
They have used the principle of electromagnetic radiation which can easily be transmitted as a beam aimed at the point of use of the power! This is a major breakthrough. The next step is to scale up the distance and power handling.
“We could use this technology to supply wireless power to IoT sensors in smart homes or digital signage (displays) in big shopping centers and other locations,” says Jinyong Ha, who led the study.
Ha also envisions industrial applications of this technology in locations where the use of wires could pose safety hazards. The findings of the research were published in an article in the journal Optics Express in September.
The system developed by the researchers consists of a transmitter and a receiver. When both are within line of sight of each other, they can be used to deliver light-based power. But the system goes into a power-safe mode where it stops transmitting energy if an obstacle comes between the transmitter and receiver. This is intended to minimise risks associated with the system.
The transmitter has an erbium-doped fibre amplifier (EDFA) power source that has a wavelength of 1,550 nm. According to the researchers, this wavelength range is safe and poses no danger to human eyes or skin at the intended power level. EDFA was first invented in 1987 and is commonly used to compensate for the loss of signal during long-range fibre-optic transmission.
The receiver unit comprises a photovoltaic cell and a spherical ball lens retroreflector that helps decrease the scattering of the light emitted by the transmitter and focuses it on the photovoltaic cell for maximum efficiency. The researchers found that the system’s performance was heavily dependent on the refractive index of the ball lens and that a refractive index of 2.003 was the most effective.
During experimental testing, the transmitter could provide an optical power of 400mW over a distance of 30 metres. The 10 by 10-millimetre receiver’s photovoltaic cell was able to convert the light energy into 85 mW of electrical power, which was used to power an LED. The researchers also demonstrated the safety of the system by placing a human hand in between the transmitter and receiver. At this point, the system went into a low-power mode where it produced a low-intensity light so that it doesn’t cause any harm.
“The efficiency can be much improved. As we now use 1,550nm wavelength light, we have low efficiency of a PV cell (GaSb). If we use an approximately 900 nm infrared light, the efficiency can be improved by 40 per cent,” Ha said. Currently, the photovoltaic cell is made of gallium arsenide (GaAs). Other materials can be tried that will be more effective at different wavelengths to increase efficiency.
The team is now working on increasing the efficiency of the system and scaling it up so that it can be used for IoT sensors in smart factories before the technology finds other applications.
That’s all in this newsletter; more next week.
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