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Pegah Piri TRITA-LWR Degree Project 12:14 4. CONCLUSIONS Fig. 12. Voltage produced from the microbial fuel cell. The average amount of the voltage produced from the microbial fuel cell was around 1.5 microvolt (Fig. 12). In the food products measurements achieved has given the following results: The COD measured for a solution of 10 g/l of juice sample was 1212 mg/l. COD value of the diluted milk (1 mg/l) was equal to 186 mg/l. According to the energy label on the sample package the energy value of 100 g sample is 146 kJ. If it is considered to be a linear correlation between the COD content and the weight of the sample, 100 g sample will have 12120 mg/l COD. 100 g sample juice corresponds to 146 kJ energy, 8.4 g carbohydrate (Table 7), and 12120 mg/l COD; therefore, one gram carbohydrate in this sample juice corresponds to 12.120/8.4 = 1.44 COD. The milk solution was diluted till 0.001 mg/l. The COD measured for this solution was 186 mg/l. The energy values for milk on the package were as following: 100 ml milk has 258.1kj 260 kJ Meanwhile 0.001 mg/l milk corresponds to 186 mg/l COD, which means 100 g milk corresponds to 105 × 186 g COD. Human life should be as sustainable as possible. The changes caused by human activities made on the environment should be decreased. In order to do this these changes should be measured and manipulated. In this way the concept of exergy is useful (Wall, 1977) and it can be used in the benchmarking activities to improve the treatment facilities and decrease their energy consumptions. The microbial fuel cell made in this thesis work could produce reasonable amount of energy compared to its elementary construction design. The 88% COD removal during the experiment were equal to 3.846 mA/m 2 . 36
Exergy saving and exergy production in municipal wastewater treatment 5. REFERENCES In order to conclude about the results on the food calculations and the relationship between the COD values and the fat, carbohydrate and protein content of the food there is a need to have more samples to run the COD measurement method. These two samples were not enough to gain a reliable result. Bendoricchio, G. and Jørgensen, S.E. (1997). Exergy as goal function of ecosystem dynamic. Ecological Modelling, 102, 5-16. Björklund; J., Geber, U. and Rydberg, T. (2001). Emergy analysis of municipal wastewater and generation of electricity by digestion of sewage sludge. Resources, Conservation and Recycling, 31, 293-316. Chen, G. (2004). Electrochemical technologies in wastewater treatment. Separation and Purification Technology 38, 11-41. Di Lorenzo, M., Curtis, T.P. and Head, I.M. (2009).A single-chamber microbial fuel cell as a biosensor for wastewaters. Water Research, 43, 3145-3154. Du, Z., Li, H., Gu, T. (2007). A state of the art review on the microbial fuel cells: a promising technology for wastewater treatment and bioenergy. Biotechnology advances 25, 464-482. Franks, A.E. and Nevin, K.P. (2010). Microbial fuel cells, a current review. Energies, 3, 899-919. Greer, D. (2010). Fundamental of Biogas Conditioning and Upgrading. Hamann, C.H., Hamnett, A. and Vielstich, W. (2007). Electrochemistry. Wiley-VCH, 2ndEd. Henze, M., Harremoës, P., la Cour Jansen, J. and Arvin, E. (1996). Wastewater treatment. Biological and Chemical Processes, Springer, 2nd Ed. Hlidqvist Skuladottir, B. (2005). Primary emergy evaluation of Iceland: The question of a sustainable resource management. Lund University Master´s Programme in International Environmental Science (LUMES), Sweden, 48 p. Jonasson, M. (2007). Energy benchmark for wastewater treatment processes – a comparison between Sweden and Austria. Master thesis, Dept. Industrial Electrical Engineering and Automation. Lund University, Lund, Sweden. Jönsson, H., Baky, A., Jeppsson, U., Hellström, D., Kärrman, E. (2005). Composition of urine, faeces, gray water and bio-waste, Goteborg: Chalmers University of technology. Jørgensen, S.E. (2001). Thermodynamics and ecological modeling. Lewis Publ. Baton Rouge, S.E., 287-302. Jørgensen, S.E. (2003). Structural dynamic model. Ecological Modelling, 31, 1-9. Jørgensen, S.E. and Johnsen, I. (1989). Principles of Environmental Science and Technology. Vol 14, Elsevier, 15-16. Jørgensen, S.E. and Nielsen, S.N. (2006). Application of exergy as thermodynamic indicator in ecology. Energy, 32, 673-685. Kim, B.H., Chang, I.S., Gil, G.C., Park, H.S. and Kim, H.J. (2003). Novel BOD (biological oxygen demand) sensor using mediator-less microbial fuel cell. Biotechnology Letters, 25, 542-545. Kondepudi, D. (2008). Introduction to Modern Thermodynamics. John Wiley & Sons., 489 p. 37
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