This post is also available in: עברית (Hebrew)
Scientists have demonstrated a highly efficient method for wirelessly transferring power to a drone while it is flying.
The breakthrough could in theory allow flying drones to stay airborne indefinitely, simply hovering over a ground support vehicle to recharge, opening up new potential industrial applications. The ground vehicle will serve as a mobile charging station.
While the use of small drones for commercial purposes, in surveillance, for reconnaissance missions, and search and rescue operations are rapidly growing, the distance that a drone can travel and the duration it can stay in the air is limited by the availability of power and re-charging requirements. Wireless power transfer technology may solve this.
The technology uses inductive coupling, a concept initially demonstrated by inventor Nikola Tesla over 100 years ago. Two copper coils are tuned into one another, using electronics, which enables the wireless exchange of power at a certain frequency. Scientists have been experimenting with this technology for decades, but have not yet been able to wirelessly power flying technology.
Now scientists from Imperial College London have removed the battery from an off-the-shelf mini-drone and demonstrated that they can wirelessly transfer power to it via inductive coupling. They believe their demonstration is the first to show how this wireless charging method can be efficiently done with a flying object like a drone, potentially paving the way for wider use of the technology.
To demonstrate their approach the researchers bought an off-the-shelf quadcopter drone, around 12 cm in diameter, and altered its electronics and removed its battery. They made a copper foil ring, which is a receiving antennae that encircles the drone’s casing. On the ground, a transmitter device made out of a circuit board is connected to electronics and a power source, creating a magnetic field.
According to Imperial College website, the drone’s electronics are tuned or calibrated at the frequency of the magnetic field. When it flies into the magnetic field an alternating current (AC) voltage is induced in the receiving antenna and the drone’s electronics convert it efficiently into a direct current (DC) voltage to power it.
The technology is still in its experimental stage. The drone can only currently fly ten centimetres above the magnetic field transmission source. The team estimate they are one year away from a commercially available product. When commercialised they believe their breakthrough could have a range of advantages in the development of commercial drone technology and other devices.
Wirelessly transferring power could have also applications in other areas such as sensors, healthcare devices and further afield, on interplanetary missions.
Professor Paul Mitcheson, from the Department of Electrical and Electronic Engineering at Imperial College London, explains: “Imagine using a drone to wirelessly transmit power to sensors on things such as bridges to monitor their structural integrity. This would cut out humans having to reach these difficult to access places to re-charge them”.
Another application could include implantable miniature diagnostic medical devices, wirelessly powered from a source external to the body. This could enable new types of medical implants to be safely recharged, and reduce the battery size to make these implants less invasive.
The next stage will see team exploring collaborations with potential industrial partners.