AMES, Iowa - Iowa State University researchers are working to produce clean, renewable energy by developing a new, low-emissions burner and a new catalyst for ethanol production.
Both technologies will use the synthesis gas - a mixture of carbon monoxide and hydrogen - produced by the gasification of discarded seed corn, switchgrass, wood chips and other biomass.
The burner will be designed to efficiently and cleanly burn biomass-based gas. The catalyst will be designed to convert the synthesis gas directly into ethanol.
The project is supported by a two-year, $2.37 million grant from the Iowa Power Fund, a state program to advance energy innovation and independence.
Song-Charng Kong, an Iowa State assistant professor of mechanical engineering, is leading the project. The research team also includes Robert C. Brown, the Iowa Farm Bureau Director of Iowa State's Bioeconomy Institute, an Anson Marston Distinguished Professor in Engineering and the Gary and Donna Hoover Chair in Mechanical Engineering; Victor Lin, a professor of chemistry, director of Iowa State's Center for Catalysis, director of Chemical and Biological Sciences for the U.S. Department of Energy's Ames Laboratory and founder of Catilin Inc., an Ames-based company that produces catalysts for biodiesel production; Samuel Jones, an assistant scientist for the Center for Sustainable Environmental Technologies; plus seven graduate students and two post-doctoral researchers.
The project also includes two industrial partners: Frontline BioEnergy, an Ames-based company that builds commercial-scale gasification systems; and Hawkeye Energy Holdings, an Ames-based ethanol producer with plants in Iowa Falls, Fairbank, Menlo and Shell Rock.
"We're excited about this research," Brown said. "This project partners the thermochemical conversion of biomass with ethanol production."
The project will move ethanol production beyond the fermentation of simple sugars in corn kernels. The researchers' idea is to use heat and oxygen to gasify biomass and produce a medium Btu gas (called synthesis gas) that a new catalyst can convert directly into ethanol. They'll also generate the gas using air to make a low Btu gas (called producer gas) that can be used in gas-fired heating and drying equipment.
"We're not intending to replace grain ethanol production," Brown said. "We want to complement it."
Kong, who is leading development of the new burner, said the technology could replace natural gas in conventional ethanol production. That would provide ethanol plants with a clean and renewable source of steam and heat.
Synthesis and producer gases have been used in burners designed for natural gas and other fuels. But Kong said the biomass-based gases aren't the same kind of fuel.
Biomass, for example, contains fixed nitrogen from the air and from fertilizers used to produce the biomass. Gasifying biomass releases the fixed nitrogen as ammonia in the generated gases. Improperly burning gases containing ammonia could produce nitrogen oxide emissions. Such emissions aren't acceptable in most industrial facilities under EPA regulations because they can contribute to smog and acid rain.
Kong's goal is to develop a burner that will minimize the emission of such pollutants while maximizing combustion efficiency.
He'll start by studying a conventional gas burner now at the Iowa Energy Center's Biomass Energy Conversion Facility in Nevada. He'll use that baseline data to develop computer models of the burner's performance. He'll use those models to test new designs that optimize the combustion of producer gas from biomass. And then he'll build and test a new burner at the energy center's facility.
"We're not doing a laboratory study," Kong said. "We're doing a real-world study. This will be helpful in developing a new and clean way to use renewable energy."
Lin, who's leading the development of a new catalyst for ethanol production, said it may be possible to efficiently produce liquid fuel directly from synthesis gas.
The key will be carbon-based nanoparticles just a few billionths of a meter wide. The particles are made from graphite and carry a transition metal that produces a chemical reaction. That reaction converts synthesis gas to ethanol.
Lin said there is an existing chemical catalyst that can convert synthesis gas to ethanol. But that catalyst has a very low yield of ethanol, produces greenhouse gases such as methane, needs heat up to 540 degrees Fahrenheit and requires high pressures.
Lin said the new catalyst should work at lower temperatures and pressures while delivering a higher yield of ethanol.
Could the technology be commercially viable?
"It's premature to say whether we have a realistic chance of that or not," Lin said. "But I can say this has shown some exciting preliminary results."
The three Iowa State researchers said the project has potential to do a lot more than develop new technologies and patents.
A project summary says using biomass to produce ethanol and provide heat for ethanol production can reduce the nation's dependence on foreign oil, reduce the carbon footprint of ethanol plants, increase the plants' renewable energy ratio, boost the profitability of biorefineries and put energy dollars into local economies.
John Reardon, the research and development manager for Frontline BioEnergy, said an ethanol plant that produces 100 million gallons per year could buy enough biomass to add $10 million per year to the local economy. He also said repowering conventional ethanol plants with biomass-based gas could create more than a thousand new engineering and construction jobs over a 10-year conversion period.
Brown said all that can add up to "a potential evolution of the ethanol industry."
Song-Charng Kong, Mechanical Engineering, (515) 294-3244, firstname.lastname@example.org
Robert C. Brown, Bioeconomy Institute, (515) 294-7934, email@example.com
Victor Lin, Chemistry and Ames Laboratory, (515) 294-3135, firstname.lastname@example.org
John Reardon, Frontline BioEnergy, (515) 292-1200
Nicholas T. Ryan, Hawkeye Energy Holdings, (515) 663-6404
Mike Krapfl, News Service, (515) 294-4917, email@example.com