Small magnetic fields from the electricity that lights our homes and powers our appliances are present all around us. Now, Penn State scientists have developed a new mechanism capable of harvesting this wasted magnetic field energy and converting it into enough electricity to power next-generation sensor networks for smart buildings and factories.
“Just like sunlight is a free source of energy we try to harvest, so are magnetic fields,” said Shashank Priya, professor of materials science and engineering and associate vice president for research at Penn State. “We have this ubiquitous energy present in our homes, office spaces, work spaces and cars. It’s everywhere, and we have an opportunity to harvest this background noise and convert it to usable electricity.”
A team led by Penn State scientists developed a device that provides 400% higher power output compared to other state-of-the-art technology when working with low-level magnetic fields, like those found in our homes and buildings.
The technology has implications for the design of smart buildings, which will require self-powered wireless sensor networks to do things like monitor energy and operational patterns and remotely control systems, the scientists said.
“In buildings, it’s known that if you automate a lot of functions, you could actually improve the energy efficiency very significantly,” Priya said. “Buildings are one of the largest consumers of electricity in the United States. So even a few percent drop in energy consumption could represent or translate into megawatts of savings. Sensors are what will make it possible to automate these controls, and this technology is a realistic way to power those sensors.”
Researchers designed paper-thin devices, about 1.5 inches long, that can be placed on or near appliances, lights, or power cords where the magnetic fields are strongest. These fields quickly dissipate away from the source of flowing electric current, the scientists said.
When placed 4 inches from a space heater, the device produced enough electricity to power 180 LED arrays, and at 8 inches, enough to power a digital alarm clock. The scientists reported the findings in the journal Energy and Environmental Science.
“These results provide significant advancements toward sustainable power for integrated sensors and wireless communication systems,” said Min Gyu Kang, an assistant research professor at Penn State and co-lead author on the study.
The scientists used a composite structure, layering two different materials together. One of these materials is magnetostrictive, which converts a magnetic field into stress, and the other is piezoelectric, which converts stress, or vibrations, into an electric field. The combination allows the device to turn a magnetic field into an electric current.
The device has a beam-like structure with one end clamped and the other free to vibrate in response to an applied magnetic field. A magnet mounted at the free end of the beam amplifies the movement and contributes toward a higher production of electricity, the scientists said.
“The beauty of this research is it uses known materials, but designs the architecture for basically maximizing the conversion of the magnetic field into electricity,” Priya said. “This allows for achieving high power density under low amplitude magnetic fields.”
Source: Penn State
