Save energy by dressing up in your favourite HVAC unit
June 2, 2015 - Imagine a smart fabric that will keep your body at a comfortable temperature—regardless of how hot or cold it is—and its potential for reducing heating and air-conditioning bills for buildings and homes.
June 3, 2015 By Anthony Capkun
That’s the goal of an engineering project at the University of California, San Diego, funded with a $2.6-million grant from the U.S. Department of Energy’s Advanced Research Projects Agency-Energy (ARPA-E).
PHOTO: Garment-based printable electrodes developed in the lab of Joseph Wang.
By regulating the temperature around an individual person rather than a large room, the smart fabric could potentially cut the energy use of buildings and homes by at least 15%, explained Joseph Wang, distinguished professor of nanoengineering at UC San Diego, and leader of the project known as ATTACH (Adaptive Textiles Technology with Active Cooling and Heating).
“In cases where there are only one or two people in a large room, it’s not cost-effective to heat or cool the entire room,” said Wang. “If you can do it locally, like you can in a car by heating just the car seat instead of the entire car, then you can save a lot of energy.”
The smart fabric will be designed to regulate the temperature of the wearer’s skin—keeping it at 93F—by adapting to temperature changes in the room. When the room gets cooler, the fabric will become thicker. When the room gets hotter, the fabric will become thinner. To accomplish this feat, researchers will insert polymers that expand in the cold and shrink in the heat inside the fabric.
“Regardless if the surrounding temperature increases or decreases, the user will still feel the same without having to adjust the thermostat,” said Wang.
“93F is the average comfortable skin temperature for most people,” added Renkun Chen, assistant professor of mechanical and aerospace engineering at UC San Diego, and one of the collaborators on this project.
Chen’s contribution to ATTACH is to develop supplemental heating and cooling devices, called thermoelectrics, that are printable and will be incorporated into specific spots of the smart fabric. The thermoelectrics will regulate the temperature on “hot spots”—such as areas on the back and underneath the feet—that tend to get hotter than other parts of the body when a person is active.
“This is like a personalized air-conditioner and heater,” added Chen.
“With the smart fabric, you won’t need to heat the room as much in the winter, and you won’t need to cool the room down as much in the summer. That means less energy is consumed. Plus, you will still feel comfortable within a wider temperature range,” Chen continued.
The researchers are also designing the smart fabric to power itself. It will include rechargeable batteries for powering the thermoelectrics, as well as biofuel cells that can harvest electrical power from human sweat. Plus, all of these parts—batteries, thermoelectrics and biofuel cells—will be printed using the technology developed in Wang’s lab to make printable wearable devices. These parts will also be thin, stretchable and flexible to ensure the smart fabric is neither bulky nor heavy.
“We are aiming to make the smart clothing look and feel as much like the clothes that people regularly wear. It will be washable, stretchable, bendable and lightweight. We also hope to make it look attractive and fashionable to wear,” said Wang.
In terms of price, the team has not yet concluded how much the smart clothing will cost. This will depend on the scale of production, but the printing technology in Wang’s lab will offer a low-cost method to produce the parts. Keeping the costs down is a major goal, the researchers said.
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