FuelCellsWorks

ANN ARBOR, MICH. – Adaptive Materials, the solid oxide fuel cell manufacturer that’s leading the portable power revolution, recently completed a successful demonstration of its UGV (unmanned ground vehicle) power source at the Naval Air Weapons Station, China Lake. Adaptive Materials worked with iRobot, a primary supplier of UGVs to the U.S. military, to show the capabilities of a fuel cell powered UGV in a real world environment.

“Adaptive Materials has once again showed that its fuel cells have evolved beyond development and into viable, reliable power sources for critical military devices,” said Michelle Crumm, chief business officer, Adaptive Materials. “In a relevant military environment, Adaptive Materials’ fuel cells perform as intended, providing portable power that enables new possibilities.”

Adaptive Materials’ fuel cells were successful demonstrated over the course of the 3-days in a real world environment where ambient temperatures exceeded 110 degrees. Throughout the 3-day demonstration, the fuel cell powered UGV ran various sensor packages and traveled along sandy, desert roads.

The Adaptive Materials 150-watt system performed flawlessly throughout the demonstration. The fuel cell, which has been designed specifically for UGV use, showed potential to increase the range and duration of robot missions by up to 500 percent.

Dr. Arum Han, assistant professor in the Department of Electrical and Computer Engineering at Texas A+M University, and Dr. Paul de Figueiredo (PI) from the plant pathology and microbiology department have received a grant from the National Science Foundation (NSF) to develop a microbial fuel cell (MFC) array for bioenergy research.

Han will develop a microfabricated MFC array, a compact and user-friendly platform for the identification and characterization of microbes capable of direct electricity generation.

Microbial fuel cells (MFCs) are remarkable “green energy” devices that exploit microbes to generate electricity from organic compounds. MFCs have generated significant excitement in the bioenergy community because of their potential for powering diverse technologies, including wastewater treatment and bioremediation devices, autonomous sensors for long-term operations in low accessibility regions, mobile robot/sensor platforms, microscopic drug-delivery systems and renewable energy systems.

MFC devices currently being used and studied do not generate sufficient power to support widespread and cost-effective applications so research has focused on strategies to enhance the power output of the MFC devices, including exploring more electrochemically active microbes to expand the few already known electricigen families. However, most of the MFC devices are not compatible with high throughput screening for finding microbes with higher electricity generation capabilities.

The MFC array being developed in the Han and de Figueiredo labs has 24-96 miniaturized MFCs on a single chip format and enables direct and parallel comparisons of microbial electricity generation. The team’s recent paper, “Microfabricated Microbial Fuel Cell Arrays Reveal Electrochemically Active Microbes,” appeared in the August issue of the journal PLoS ONE.

In this work they took environmental samples from the Brazos River and Lake Somerville in Texas, screened the environmental isolates using the 24-well MFC array for electricity generation and found an environmental microbe showing 2.3-fold increased power generation compared to the reference strain Shewanella oneidensis MR-1. The team is currently working on a 96-well MFC array and expects to use it for high throughput screening of environmental microbes or genetically modified microbes, or finding optimum operation conditions for maximum power generation. Just as high throughput microarrays (e.g. DNA microarray, protein microarray) transformed the field of biology and medical science, the team expects that such MFC arrays can greatly accelerate research in the bioenergy field.

Han, director of the NanoBio Systems Lab and an expert in nano/micro technologies for bio/medical applications, joined the bio­medical area of the de­partment in August 2005. He received his bachelor’s degree from the Seoul Na­tional University (Ko­rea) in 1997 and his master’s degree from the University of Cincinnati in 2000. In August 2005, he received his Ph.D. degree in electrical engineering from the Georgia Institute of Technology.

Han’s research interests lie in the devel­opment of miniaturized systems for cel­lular and molecular analysis using micro and nano fabrication technologies. His re­search area includes Lab-on-a-Chip (µTAS), BioMEMS, NanoBio Systems, Micro and Nano Fluidic Systems and Bioenergy.

CHARLESTON, W.Va. (AP) – Yeager Airport near Charleston is the home of a hydrogen fuel production plant that is expected to serve the needs of airport and state National Guard vehicles.

State and federal officials were to dedicate the facility at the mountaintop airport during a ceremony Monday afternoon.

The Office of Fossil Energy’s National Energy Technology Laboratory provided $2.6 million on the experimental plant. The goal is to demonstrate the feasibility of using hydrogen fuel instead of petroleum.

When announcing the project earlier this year, the agency said it would test and evaluate the plant for two years.