Big power from tiny device

Researchers at the US Department of Energy’s Pacific Northwest National Laboratory have created world’s smallest catalytic fuel processing reactor system.

Researchers at the US Department of Energy’s Pacific Northwest National Laboratory have created world’s smallest catalytic fuel processing reactor system to provide a low-watt power source for hand-held wireless equipment, sensors and other small devices used by the US military.

The petite power system is said to convert liquid fuel to electricity via a microscale fuel processor coupled with a microscale fuel cell developed by Case Western Reserve University in Ohio.

An integral part of the system is PNNL’s fuel reformer, which enables the system to convert fuel and water into hydrogen-rich gas. The fuel cell then generates electricity by converting hydrogen and oxygen from the air into electrical power and clean water.

‘Our miniaturised fuel processor incorporates several chemical processes and operations in one device,’ said Evan Jones, PNNL principal investigator. The fuel processor system contains two vaporisers, a heat exchanger, a catalytic combustor and a steam reformer, all within a compact package no larger than a penny.

The military envisions many useful applications for this emerging miniaturised energy-generating technology. According to Terry Doherty, director of PNNL’s Department of Defense programs, soldiers could power personal, lightweight cooling systems while wearing protective suits and gear, prolonging their own comfort and efficiency during a reconnaissance.

‘Vital personal communications devices could function for extended periods without the added weight of bulky, inefficient batteries,’ Doherty said. He added that miniature sensors powered by the same technology could be scattered before advancing troops to monitor ground vibrations or detect dangerous toxic agents and relay this information electronically to soldiers. This technology broadens the possibilities for using self-sustaining items such as mobile devices in remote or difficult-to-access locations.

While methanol has proved to be the most effective fuel source, other liquid fuels such as butane, jet fuel (JP-8) or even diesel may be used. And, because the hydrogen power source is only produced as needed, there is no need to store or carry the volatile gas, reducing risk and creating a lighter load.

Testing has revealed that performance from the reformer and fuel cell prototype is impressive. ‘This system can produce an equivalent power (20 mW) to batteries, but at one-third the weight,’ Jones said.

Similar micro fuel cell systems with greater power output (50 W) currently under development are providing power equal to that of batteries weighing 10 times as much. Researchers suggest that with additional system efficiencies and improvements, even greater performance may be achievable.

PNNL researchers have found that huge processing plants, traditionally used to produce chemicals and other products, can be scaled down exponentially. ‘What can be achieved on a large scale,’ Jones said, ‘can be achieved at a microscale.’

For further information on the catalytic fuel processing reactor system and other PNNL-created microscale research, go to: <A HREF=’’>PNNL</A>