UCF researchers have advanced NASA technologies to develop a power suit for an electric car that is as strong as steel, lighter than aluminum and helps boosts the vehicle’s power capacity.

The suit is made of layered carbon composite material that works as an energy-storing supercapacitor-battery hybrid device due to its unique design at the nanoscale level.

The development appeared recently as the cover story in the journal Small and could have applications in a range of technologies that require lightweight sources of power, from electric vehicles to spacecraft, airplanes, drones, portable devices and wearable tech.

“Our idea is to use the body shells to store energy to supplement the power stored in batteries,” told Jayan Thomas, the team leader and a professor in UCF’s NanoScience Technology Center and Department of Materials Science and Engineering. “The advantage is that this composite can reduce the weight of your car and increase the miles per charge. It is as strong as or even stronger than steel but much lighter.”

The material, when used as a car body shell, could increase an electric car’s range by 25%, meaning a 200 miles per charge vehicle could go an extra 50 miles and reduce its overall weight.

As a supercapacitor, it also would boost an electric car’s power, giving it the extra push it needs to go from zero to 60 mph in 3 seconds.

UCF and NASA researchers design charged ‘Power Suits’ for electric vehicles and spacecraft.

On cars, the supercapacitor composite material would get its power through charging, like a battery, as well as when the car brakes, Jayan Thomas introduced. “Its charge-discharge cycle life is 10 times longer than an electric car battery.”

The materials used are also nontoxic and nonflammable, which is very important for passenger safety in case of an accident, he said.

Besides, due to its unique design that uses multiple layers of carbon fiber, the material has significant impact and bending strength, essential for withstanding an auto collision, as well as tensile strength.

To construct the material, the researchers created positively and negatively charged carbon fiber layers, that when stacked and attached in an alternating pattern, create a strong, energy-storing composite.

Nanoscale graphene sheets attached on the carbon fiber layers allow for increased charge storing ability, while metal oxides deposited on attached electrodes enhance voltage and provide higher energy density. This provides the supercapacitor-battery hybrid with its unprecedented energy storage ability and charging life cycle, Thomas says.

Deepak Pandey, the study’s lead author and a doctoral student in Jayan Thomas’ lab, worked on forming, shaping and optimizing the composite, as well as developing the method to add metal oxides to the carbon graphene strips.

Study co-author Kowsik Sambath Kumar, a doctoral student in Jayan Thomas’ lab, developed a way to vertically align nanoscale graphene on carbon fiber electrodes. He remarked that one of the most important developments from this supercapacitor composite is that it is lightweight.

Moreover, these materials could also be employed as frames for cube satellites, structures on off-world habitats, or even as part of futuristic eyewear, such as mixed and virtual reality headsets.

“Making a cubic satellite out of this composite will make the satellite light in weight and will help to eliminate the heavy battery pack,” he says. “Further, free volume gained by removal of big batteries could help pack in more sensors and testing equipment, increasing the functionality of satellite,” Deepak Pandey said.

Luke Roberson, study co-author and a senior principal investigator for research and development at NASA’s Kennedy Space Center, added that the technology is currently at a technology readiness level of five, which means it has been tested in a relevant environment before moving to being tested in a real environment, such as on a space flight, which would be level six testing.

To pass the last level of testing, level nine, and reach the commercial environment, it will require further development and testing focused on commercial applications, he said.

UCF researchers have advanced NASA technologies to develop a power suit for an electric car that is as strong as steel, lighter than aluminum and helps boosts the vehicle’s power capacity.

The suit is made of layered carbon composite material that works as an energy-storing supercapacitor-battery hybrid device due to its unique design at the nanoscale level.

The development appeared recently as the cover story in the journal Small and could have applications in a range of technologies that require lightweight sources of power, from electric vehicles to spacecraft, airplanes, drones, portable devices and wearable tech.

“Our idea is to use the body shells to store energy to supplement the power stored in batteries,” told Jayan Thomas, the team leader and a professor in UCF’s NanoScience Technology Center and Department of Materials Science and Engineering. “The advantage is that this composite can reduce the weight of your car and increase the miles per charge. It is as strong as or even stronger than steel but much lighter.”

The material, when used as a car body shell, could increase an electric car’s range by 25%, meaning a 200 miles per charge vehicle could go an extra 50 miles and reduce its overall weight.

As a supercapacitor, it also would boost an electric car’s power, giving it the extra push it needs to go from zero to 60 mph in 3 seconds.

UCF and NASA researchers design charged ‘Power Suits’ for electric vehicles and spacecraft.

On cars, the supercapacitor composite material would get its power through charging, like a battery, as well as when the car brakes, Jayan Thomas introduced. “Its charge-discharge cycle life is 10 times longer than an electric car battery.”

The materials used are also nontoxic and nonflammable, which is very important for passenger safety in case of an accident, he said.

Besides, due to its unique design that uses multiple layers of carbon fiber, the material has significant impact and bending strength, essential for withstanding an auto collision, as well as tensile strength.

To construct the material, the researchers created positively and negatively charged carbon fiber layers, that when stacked and attached in an alternating pattern, create a strong, energy-storing composite.

Nanoscale graphene sheets attached on the carbon fiber layers allow for increased charge storing ability, while metal oxides deposited on attached electrodes enhance voltage and provide higher energy density. This provides the supercapacitor-battery hybrid with its unprecedented energy storage ability and charging life cycle, Thomas says.

Deepak Pandey, the study’s lead author and a doctoral student in Jayan Thomas’ lab, worked on forming, shaping and optimizing the composite, as well as developing the method to add metal oxides to the carbon graphene strips.

Study co-author Kowsik Sambath Kumar, a doctoral student in Jayan Thomas’ lab, developed a way to vertically align nanoscale graphene on carbon fiber electrodes. He remarked that one of the most important developments from this supercapacitor composite is that it is lightweight.

Moreover, these materials could also be employed as frames for cube satellites, structures on off-world habitats, or even as part of futuristic eyewear, such as mixed and virtual reality headsets.

“Making a cubic satellite out of this composite will make the satellite light in weight and will help to eliminate the heavy battery pack,” he says. “Further, free volume gained by removal of big batteries could help pack in more sensors and testing equipment, increasing the functionality of satellite,” Deepak Pandey said.

Luke Roberson, study co-author and a senior principal investigator for research and development at NASA’s Kennedy Space Center, added that the technology is currently at a technology readiness level of five, which means it has been tested in a relevant environment before moving to being tested in a real environment, such as on a space flight, which would be level six testing.

To pass the last level of testing, level nine, and reach the commercial environment, it will require further development and testing focused on commercial applications, he said.