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| News > Air Force funds new generation of energy efficient UAVs |
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With AFOSR funding, a team from the University of Michigan is working on a project to integrate solar power cheaply and easily into the base materials used to build UAVs. The team is pictured above posing around a customized reel-to-reel coating apparatus they developed for making large quantities of fiber-based energy conversion devices.
(Center) Max Shtein, an assistant professor working on optoelectronic materials and devices, thin-film processing
(Left to Right) Kevin Pipe, an assistant professor working on thermal phenomena in materials and devices; Brendan O'Connor, a graduate student working on organic solar cells on fibers; Abhishek Yadav, a graduate student working on thermoelectric devices on fibers; and Steven Morris, a graduate student working on reel-to-reel deposition of films and devices on fibers.
(Photo Credit: University of Michigan)
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Air Force funds new generation of energy efficient UAVs
Posted 5/26/2009 Updated 5/26/2009
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by Molly Lachance
Air Force Office of Scientific Research
5/26/2009 - ARLINGTON, Va. -- With the ever-increasing military demand to reduce the size and weight of unmanned aerial vehicles (UAVs) while lengthening flight times, the Air Force Office of Scientific Research is funding a project to integrate solar power cheaply and easily into the base materials used to build them.
Dr. Max Shtein and his team at the University of Michigan are investigating the energy harvesting potential of many different device applications, including thin film solar cells reshaped and coated onto long continuous filaments, or fibers. When such organic semi-conductor coated fibers are woven into a fabric system, the resulting textile can be used not only to form the structural make-up of the UAV, but also to generate the electricity to power it.
To date, Shtein and his team have demonstrated small, stand-alone prototypes that strongly suggest that this type of application is possible.
Integrating the solar cells in the desired configuration, however, will require building more sophisticated fabrication equipment. They are currently working on a customized coating apparatus for making large quantities of fiber-based energy conversion devices.
Once finished, Shtein plans to develop new models that synergize optics, mechanics, electrical and energy transport, and energy storage mechanisms.
"These models will allow us to optimize the device structure using multifunctional design constraints, improving energy conversion efficiency and power density of our devices in practical configurations," he said.
Combining these functionalities would reduce the bulk mass associated with separate optical, mechanical and electrical systems leading to vehicles that have increased power, but weigh much less.
UAVs built with these materials would be light and compact, and their renewable energy source would also allow them to experience longer flight times and power propulsion systems and on-board sensors, drastically increasing state-awareness.
As a current recipient of the Presidential Early Career Award for Scientists and Engineers (PECASE), Shtein received a $200,000-a-year grant for five years to continue this innovative work. |
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