Transcript Quinn Good
BioEnergy Production from Food Waste By: Quinn Osgood Background Information • It has become apparent that the world needs to find an energy source other that the non-renewable ones we use today. • A potential solution can be found in food waste, which is produced in great quantity and is very rich in organic material and stored energy. • Several methods have been tested to harvest the energy stored in this waste, most of which strive to gather Methane and Hydrogen. Hydrogen and Bioenergy • Hydrogen shows great potential as a fuel source that is both efficient and environmentally safe. • Another use for Hydrogen is as an additive for Compressed Natural Gas, which reduces the formation of Nitrogen Oxides by up to 50% • Given the importance that Hydrogen may have in our energy future, efficient methods for production will be very important. Two-Stage anaerobic fermentation for H2 and CH4 production • Anaerobic dark fermentation of food waste followed by either light or dark anaerobic fermentation for H2 production • Generally result in high CH4 production but comparatively low H2 production • Poor H2 yield results from the main organic acids present after anaerobic fermentation being acetate and butyrate which more readily form other compounds Development of a novel three-stage fermentation system converting food waste to hydrogen and methane Dong-Hoon Kim and Mi-Sun Kim Abbreviations • • • • COD = Chemical Oxygen Demand LFE = Lactate fermentation effluent I/S ratio = inoculum to substrate ratio VS = volatile solids Objective • To develop of a novel three-stage fermentation system converting food waste to hydrogen and methane with an emphasis on high H2 yield. Methods Overview • The food waste was collected from a cafeteria, diluted two times by volume and shredded into pieces < 5mm in diameter. • The COD of the carbohydrates in the food waste was then adjusted to 30 ± 2 g/L • Stage 1 of fermentation: The food waste is fermented for one day for the production of lactate. • The LFE was then centrifuged • Stage 2 of fermentation: The supernatant is removed and used for H2 photo-fermentation • Stage 3 of fermentation: The residue is removed and used for CH4 production via anaerobic digestion • H2 and Ch4 content was measured with gas chromatography, other compounds were measured with HPLC and quantities such as VS and COD were determined with standard methods Schematic Methods: Stage 1 • There is no initial inoculum, but instead relies on organisms already present in the food waste. • The fermentor used had a working volume of 2.5 L and was equipped with a pH sensor and a mechanical agitator. • pH was initially 7± 0.1 and dropped to 5.0 due to fermentation products and was then held there (± 0.1) by addition of KOH. • Temperature was held at 35°C and the agitator was held at 100 rpm • Later testing showed that the primary bacteria present were Lactobacillus sp. and Streptococcus sp. Methods: Stage 2 • The inoculum used in the photo-fermentation was R. sphaeroides previously isolated from mud on an island in the West Sea of Korea • The bottles were inoculated with 0.56g of the cells, then 50 mL of the diluted supernatant from the LFE and a trace metal solution were added. • The bottles were then held at 30°C and were agitated with a magnetic stir bar at 100 rpm • The media was exposed to light with an intensity of 110W/m^2 with a halogen lamp Methods: Stage 3 • The inoculum used for CH4 production was a sample taken from an anaerobic digester at a local waste water treatment plant. • The solid portion of the LFE, inoculum and tap water were added to the bottle for a working volume of 100mL • The initial pH of the media was set to 7.5 by the addition of KOH and HCL • The sample were held at 35°C in a shaking incubator Results: Stage 1 Results: Stage 2 A maximum of 2570 mL of H2 was produce/ L of broth with the addition of 0.5mL/L Trace metal solution. This corresponds to 994 mL H2 per g COD Results: Stage 3 Results: Summary Discussion • From the results it was determined that 41% and 37% of the energy content of the food waste was converted into H2 and Ch4 respectively ▫ This corresponds to an electrical energy yield of 1146 MJ/ ton food waste which is 1.4 time more that the next best two-stage system ▫ About 3.6 MJ = 1 kWh, so the electrical energy yield is about 318 kWh • This method produced the highest efficiency H2 yield of any study that made use of waste products by converting 8.38 mol H2 per mol of hexose, which has a theoretical maximum yield of 12 mol H2 • This method, while having some down sides, is a definite step in the right direction for the development of efficient H2 production mechanisms Comparison Critiques • Not using a pure culture for lactate formation ▫ This would result in higher lactate yield and thus higher H2 yield • Figure 4 is not easily read but contains significant data ▫ Much of this is resolved if Table 2 and Figure 4 were to be place next to each other • The phrase “a certain amount” is used in place of actual quantities in multiple places in the text and I feel that this damages the reproducibility of the experiment. • Overall I thought this was a quality paper that included novel ideas and good results. Future Directions • Using a pure culture in lactate fermentation to increase lactate yield • Exploring other H2 producing microorganisms and optimization of H2 producing pathways • Lactate fermentation followed by a two stage dark/photo H2 fermentation system • Performing this test in a different region where different food wastes would be more abundant. • Development of a mechanism for removing ammonium from solution after lactate fermentation References • Kim, Dong-Hoon, and Mi-Sun Kim. "Development of a Novel ThreeStage Fermentation System Converting Food Waste to Hydrogen and Methane." Bioresource Technology 127 (2013): 267-74. 1 Oct. 2012. Web. doi: 10.1016/j.biortech.2012.09.088