"We didn't invent anything scientifically new," says Ely Cohen, vice president of marketing and business development for the four-year-old company.
The novelty factor: instead of using electricity to push air into the water, Emefcy uses a permeable filter that allows air in but doesn't let liquid out, much like how a diaper works. The polyethylene plastic membrane, similar to materials used in construction, surrounds the fuel cell chamber into which wastewater flows.
Inside the fuel cell, Emefcy coaxes anaerobic bacteria, primarily Shewanella oneidensis and Geobacter sulfurreducens, to release electrons in an oxygen-free environment. The electrons flow to an anode and then into a circuit to cathodes in a separate chamber on the outside of the membrane. The electrons allow the carbon cathodes to react with oxygen to form carbon dioxide.
The practical side of the Emefcy fuel cell relates to the materials engineering: both the anode and cathode are made of a carbon cloth that acts as a conductor. Precious metals have long been used as conducting materials in batteries and other types offuel cells but are too expensive to use at a commercial scale in microbial fuel cells.
For a typical paper-recycling factory, one Emefcy fuel cell module, which is about the size of a cubic meter, could treat about three cubic meters per day of wastewater depending on the amount of organic material present, according to Cohen, and the modules can be scaled to meet the needs of larger or smaller plants.
The bacteria eat a lot to produce electricity and live a longer life because the environment is optimized for their survival, so sludge can be cut down by 80 percent, Cohen says. Roughly four watts of electricity are produced for every kilogram of organic material that the bacteria consume. The amount of electricity generated will not exactly power the entire town, or even the entire processing facility, but it can offset the energy used to clean the water.
"The energy we don't consume is more important than the electricity we might produce," says environmental engineer Bruce Logan of Pennsylvania State University, an Emefcy advisor.
Municipal and industrial wastewater plants comprise about 2 percent of the annual electrical power used in the U.S., but treatment methods have remained largely unchanged for decades. In traditional systems, most of the power goes into pumping air through the water so that bacteria in the water can grow and consume organic material that remains after the largest particles have been removed. Another substantial chunk of energy goes into trucking away the leftover sludge, which almost always ends up in landfills.
Emefcy's technology has its limitations. The fuel cell is ideal for wastewater that is high in organic material, mostly wastewater from agriculture and food processing rather than municipalities. Logan estimates that quantities of food and beverage wastewater equal domestic wastewater, and animal and farm wastewater is more than the other two markets combined. Cohen said that the food additives industry, in particular, may become a very attractive market for the technology.
Sludge reduction and regulatory compliance are also significant drivers for the food and beverage industry, which is pushing more companies to process wastewater on site rather than just sending it directly to municipal treatment facilities, according to a report from Global Water Intelligence (GWI), a water industry market research firm based in England. With increasing regulation, Emefcy's technology could become appealing for this market as well.
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