The low-power wireless energy “Internet of Things” standard ZigBee, used in smart metering systems, is now available in a battery-free version which harvests energy.
The new specification will allow ZigBee, which is specified within the UK government’s ambitious smart meter programme, to operate without batteries by harvesting energy such as ambient radio waves.
Scavenging Free Green Power From Radio Waves
A free, green way to harvest energy from radio waves all around us has been developed by a research team from Georgia Tech School of Electrical and Computer Engineering.
On a waveband basis, the available power is low, but there is a lot of it with mobile phones, TV transmissions, satellite communications systems and Wi-Fi, to mention but a few, the air is full of radio waves. By scavenging this ambient energy, its AC pulses can be converted into DC power for storage in super capacitors or batteries.
A Revolution In Small Low-Energy Gadgets
For several years, the Georgia tech team has been working on very low-cost transducers that can tap into these transmissions and could result in a free, constant flow of electricity to power-up improved devices such as RFID tags, environmental monitors and medical sensors.
“There is a large amount of electromagnetic energy all around us, but nobody has been able to tap into it,” said Manos Tentzeris, a professor and research leader in the Georgia Tech School. “We are using an ultra-wideband antenna that lets us exploit a variety of signals in different frequency ranges, giving us greatly increased power-gathering capability.”
The antennas will be low-cost to produce and the research units are printed using ordinary ink-jet machines using a nanoparticle “ink”. The substrate is either paper or a flexible polymer. The ink is described as “a unique in-house recipe” containing silver nanoparticles and/or other nanoparticles in an emulsion. This not only allows RF components and circuits to be printed but also opens up the possibilities of novel sensing devices based on carbon nanotubes and other nanomaterials.
Many different frequency ranges are used by communication devices. The team’s scavenging devices can capitalise on frequencies from FM radio to radar, a range spanning 100MHz to 15GHz) or higher. The antennas can be tuned for use in specific environments, such as an airport where radar and fixed comms channels are major sources of free energy.
Scavenging Frequency Range Rapidly Increasing
Experiments using the transmission bands from a TV station half a kilometre away from the test site have yielded hundreds of microwatts of power. This was sufficient to run a temperature sensor but multi-band systems are expected to generate a milliwatt or more. The group is planning another demonstration where a microprocessor-based microcontroller would be activated simply by holding it in the air.
Super-capacitors may be used to power devices requiring above 50 milliwatts in a cycled operation. When power builds up to a preset level in the capacitor, it will be used to power the device and then will recharge.
The scavenging device could piggy-back solar energy panels so that, when the system stops generating power at sundown, the wireless energy could be used overnight to increase the battery charge or to prevent power leakage. The devices would also be useful in remote areas where an outage of a traditional power source could be flagged by sending a distress signal from an antenna-powered unit.
The possibilities are even more interesting in the world of RFID tags. Having a handy power supply attached would allow more features to be included in the tag. However, combining RFID tagging with sensors could offer even better returns.