New research at Illinois could make ethanol production more efficient and economic
- The enzymes needed to convert corn starch to glucose fermented to ethanol by yeast can now be found in new corn and ‘superior yeast,’ reducing the total enzyme addition by more than 80 percent.
- Using a vacuum flashing process, removing ethanol from the tank as it is produced insures yeast health and allows complete fermentation of corn solids up to 40 percent.
- Using high solids in the slurry reduces the amount of water needed as well as the amount of energy required to remove the water.
URBANA - New research at the Integrated Bioprocessing Research Laboratory (IBRL) on the University of Illinois Urbana-Champaign campus could significantly change ethanol production by lowering operating costs and simplifying the dry grind process.
“There are currently more than 200 dry grind plants that are processing corn to produce ethanol,” says Vijay Singh, director of IBRL and a professor in agricultural and biological engineering. “The dry grind process requires two different enzymes to convert corn starch to glucose, which is further fermented to ethanol by yeast.”
Singh says that process has been simplified by combined use and optimization of three new technologies. “A new corn developed by transgenic technology, known as amylase corn, produces one of these enzymes in the grain itself, and a newly engineered ‘superior yeast’ provides the second enzyme, as well as fermenting the glucose.
“There is a high expression level of the first enzyme, α-amylase, in the new corn, so only a small amount [15 percent was tested in these studies] of this corn is required to be mixed with conventional dent corn,” Singh notes. “The superior yeast provides the second enzyme, glucoamylase, and also provides an alternate metabolic pathway to reduce by-product formation during fermentation. Combined use of this corn and superior yeast can reduce the total enzyme addition by more than 80 percent.”
Another approach to improve the dry grind process is to use high solids in the plant. However, according to Singh, high solid concentrations leads to high ethanol build-up in the tank. “High ethanol affects the yeast viability and inhibits its fermentation performance, so we have added a third technology to the process. We remove the ethanol as it is being produced, using a vacuum flashing process that is patented technology from the University of Illinois. Only a couple of vacuum cycles of 1 to 1.5 hours can bring the ethanol concentration below the inhibitory levels without affecting yeast health and allow complete fermentation of corn solids up to 40 percent,” says Singh.
Deepak Kumar, a postdoctoral research associate in agricultural and biological engineering, says because the dry grind process uses a significant amount of water, using more solid material in the slurry - 40 percent as opposed to 30-35 percent - means less water going into the process. “When ethanol is produced, it is in a very dilute solution. You have a small amount of ethanol and a large amount of water,” says Kumar. “We cut down the water use by pushing high solids. When we reduce the amount of water, we also reduce the amount of energy required to remove the water.”
Singh believes this new research has the potential to improve the economics and process efficiencies and simplify the dry grind process. “By developing highly optimized technologies, we will benefit the entire dry grind industry,” he concludes.
Singh and Kumar received the 2016 Bioenergy Society of Singapore (BESS) Achievement Award for their work, in particular their paper “Dry-grind Processing using Amylase Corn and Superior Yeast to Reduce the Exogenous Enzyme Requirements in Bioethanol Production.” This award recognizes the importance of research on bio-energy and bio-based chemicals and was given to Singh and Kumar for their contributions to biofuels research. The paper has been published in Biotechnology for Biofuels, and the full text can be found online at http://bit.ly/2f4JFe3.