Biomassi tehnoloogiauuringud ja tehnoloogiate ... - bioenergybaltic
Biomassi tehnoloogiauuringud ja tehnoloogiate ... - bioenergybaltic Biomassi tehnoloogiauuringud ja tehnoloogiate ... - bioenergybaltic
3.11. Kasutatud allikad 1. Alamäe, T. (2003). Mikrobiloogia lühikonspekt 2003. Tartu Ülikool. 2. Batstone, D. J. (1999). High Rate Anaerobic Treatment of Complex Wastewater. A thesis were submitted for degree of Doctor of Philoshophy in Chemical Engineering at the University of Queensland. Queenslandi University. 3. Borja, R., Martin, A., Sanchez, E., Rincon, B., Raposo, F. (2005). Kinetic modelling of the hydrolysis, acidogenic and methanogenic steps in the anaerobic digestion of two-phase olive pomace (TPOP). Process Biochemistry, 40, 1841-1847. 4. Buyukkamaci, N., Filibeli, A. (2004). Volatile fatty acid formation in an anaerobic hybrid reactor. Process Biochemistry, 39 (11), 1491-1494. 5. Chemical Info http://www.chemindustry.com/chemicals/ (08.05.05) 6. Chen, Y., Jiang, S., Yuan, H., Zhou, Q., Gu, G. (2007). Hydrolysis and acidification of waste activated sludge at different pHs. Water Reasearch, 41, 683-689. 7. Chu, C.P., Lee, D.J. (2004) Effect of pre-hydrolysis on floc structure. Journal of Environmental Management, 71 (3), 285-292. 8. Dogan, T., Ince, O., Oz, N. A., Ince, B. K. (2005). Inhibition of volatile fatty acid production in granular sludge from a USB reactor. Journal of Environmental Science and Health, 40, 633-644. 9. Droste, R.L. (1997). Theory and Practice of Water and Wastewater Treatment. J. Wiley & Sons. 10. Gavala, H. N., Yenal, U., Skiadas, I.V., Westermann, P.,Ahring. B.K. (2003). Mesophilic and thermophilic anaerobic digestion of primary and secondary sludge. Effect of pretreatment at elevated temeparture. Water Research, 37, 4561-4572. 11. Kampas, P., Parsons, S. A., Pearce, P., Ledoux, S., Vale, P., Churchley, J., Cartmell, E. (2007). Mechanical sludge disintegration fro the production of carbon source for bilogical nutrient removal. Water Research, 41, 1734-1742. 12. Leitao, R. C., van Haandel, A. C., Zeeman, G., Lettinga, G. (2006). The effects of operational and environmental variations on anaerobic wastewater treament systems: A rewiev. Bioresource Technology, 97(9), 1105-1118. 13. Lepistö, R., Rintala, J. (1997). The effect of extreme temperatures (70-80C) on the effluent quality and sludge characteristics of UASB reactors. Water Science Technology, 36, 325-332. 14. A. Menert. Microcalorimetry of Anaerobic Digestion. Thesis on Natural and Exact Sciences, TTÜ Press, Tallinn, 2001, 83 pp, 83 P, ISBN 9985-59-243-3. 15. Menert, A., Rikmann, E., Michelis, M., Vaalu, T., Blonskaja, V., Vilu, R. Anaerobic mesophilic digestion of sludge with extra-thermophilic and high pH pre-treatment. Proceedings of 4 th Conference on the Establishment of Cooperation between Companies and Institutions in the Baltic Sea Region (Kalmar Eco-Tech '03), 2004, pp. 451-463. 16. Miron, Y., Zeeman, G., van Lier, J. B., Leetinga, G. (2000). The role of sludge retention time in the hydrolysis and acidification of lipids, carbohydrates and proteins during digestion of primary sludge in CSTR systems. Water Research, 34 (5), 1705- 1713. 17. Mölder, H (2002). Reoveepuhastusjaamades jääkmuda käitluse tehnoloogia täiustamine mudakoguse vähendamiseks ja kasutatavuse tõstmiseks. ETF granti 4283 aruanne.Tallinna Tehnikaülikool. 68(134) Lep7028-VV-15-10-vahearuanne.doc
18. Nah, I. W., Kang, Y. W. Hwang, K-Y., Song. W-K. (2000). Mechanical pretreatment of waste activated sludge for anaerobic digestion process. Water Research, 34 (8), 2362-2368. 19. Parawira, W., Murto, M., Read, J. S., Mattiasson, B. (2004). Volatile fatty acid production during anaerobic mesophilic digestion of solid potato waste. Journal of Chemical Technology and Biotechnology, 79, 673-677. 20. Park, C., Lee, C. H., Kim. S., Howard, Y. C., Chase, A. (2005). Upgrading of anaerobic digestion by incorporating two stage different hydrolysis processes. Journal of Bioscience and Bioengineering,100 (2), 164-167. 21. Penaud, V., Delgenès, J. P., Moletta. (1999). Thermo-chemical pretreatment of a microbial biomass: influence of sodium hydroxide addition on solubilization and anaerobic biodegradability. Enzyme and Microbial Technology, 25 (3-5), 258-263. 22. Pullammanappallil, P. C., Chynoweth, D. P., Lyberatos, G., Svoronos, S. A. (2001) Stable performance of anaerobic digestion in the presence of a high concenetration of propionic acid. Bioresource Technology, 78 (2), 165-169. 23. Rikmann, E. (2000). Kõrge orgaanilise reostusega toiduainetetööstuse reovete anaeroobse käitluse uurimine. Tallinna Tehnikaülikool. 24. Sötemann, S. W., van Rensburg, P., Ristow, N. E., Wentzel, M. C., Loewenthal, R. E., Ekama, G. A. (2006). Integrated chemical, physical and bilogical processes modelling of anaerobic digestion of sewage sludge. Water Science and Technology, 54, 109-117. 25. Wang, Q., Kuninobu, M., Ogawa, H. I., Kato, Y. (1999). Degradation of volatile fatty acids in highly efficient anaerobic digestion. Biomass and Bioenergy, 16 (6), 407-416. 26. Vlyssides, A. G., Karlis, P. K. (2003). Thermal-alkaline solubilization of waste activated sludge as a pre-treatment stage for anaerobic digestion. Bioresource Technology, 91 (2), 201-206. 27. Yang, K., Yu, Y., Hwang, S. (2003). Selective optimization in thermophilic acidogenesis of cheese-whey wastwater to acetic and butyric acids: partial acidification and methanation. Water Research, 37, 2467-2477. 69(134) Lep7028-VV-15-10-vahearuanne.doc
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3.11. Kasutatud allikad<br />
1. Alamäe, T. (2003). Mikrobiloogia lühikonspekt 2003. Tartu Ülikool.<br />
2. Batstone, D. J. (1999). High Rate Anaerobic Treatment of Complex Wastewater. A<br />
thesis were submitted for degree of Doctor of Philoshophy in Chemical Engineering at<br />
the University of Queensland. Queenslandi University.<br />
3. Bor<strong>ja</strong>, R., Martin, A., Sanchez, E., Rincon, B., Raposo, F. (2005). Kinetic modelling<br />
of the hydrolysis, acidogenic and methanogenic steps in the anaerobic digestion of<br />
two-phase olive pomace (TPOP). Process Biochemistry, 40, 1841-1847.<br />
4. Buyukkamaci, N., Filibeli, A. (2004). Volatile fatty acid formation in an anaerobic<br />
hybrid reactor. Process Biochemistry, 39 (11), 1491-1494.<br />
5. Chemical Info http://www.chemindustry.com/chemicals/ (08.05.05)<br />
6. Chen, Y., Jiang, S., Yuan, H., Zhou, Q., Gu, G. (2007). Hydrolysis and acidification of<br />
waste activated sludge at different pHs. Water Reasearch, 41, 683-689.<br />
7. Chu, C.P., Lee, D.J. (2004) Effect of pre-hydrolysis on floc structure. Journal of<br />
Environmental Management, 71 (3), 285-292.<br />
8. Dogan, T., Ince, O., Oz, N. A., Ince, B. K. (2005). Inhibition of volatile fatty acid<br />
production in granular sludge from a USB reactor. Journal of Environmental Science<br />
and Health, 40, 633-644.<br />
9. Droste, R.L. (1997). Theory and Practice of Water and Wastewater Treatment. J.<br />
Wiley & Sons.<br />
10. Gavala, H. N., Yenal, U., Skiadas, I.V., Westermann, P.,Ahring. B.K. (2003).<br />
Mesophilic and thermophilic anaerobic digestion of primary and secondary sludge.<br />
Effect of pretreatment at elevated temeparture. Water Research, 37, 4561-4572.<br />
11. Kampas, P., Parsons, S. A., Pearce, P., Ledoux, S., Vale, P., Churchley, J., Cartmell,<br />
E. (2007). Mechanical sludge disintegration fro the production of carbon source for<br />
bilogical nutrient removal. Water Research, 41, 1734-1742.<br />
12. Leitao, R. C., van Haandel, A. C., Zeeman, G., Lettinga, G. (2006). The effects of<br />
operational and environmental variations on anaerobic wastewater treament systems:<br />
A rewiev. Bioresource Technology, 97(9), 1105-1118.<br />
13. Lepistö, R., Rintala, J. (1997). The effect of extreme temperatures (70-80C) on the<br />
effluent quality and sludge characteristics of UASB reactors. Water Science<br />
Technology, 36, 325-332.<br />
14. A. Menert. Microcalorimetry of Anaerobic Digestion. Thesis on Natural and Exact<br />
Sciences, TTÜ Press, Tallinn, 2001, 83 pp, 83 P, ISBN 9985-59-243-3.<br />
15. Menert, A., Rikmann, E., Michelis, M., Vaalu, T., Blonska<strong>ja</strong>, V., Vilu, R. Anaerobic<br />
mesophilic digestion of sludge with extra-thermophilic and high pH pre-treatment.<br />
Proceedings of 4 th Conference on the Establishment of Cooperation between<br />
Companies and Institutions in the Baltic Sea Region (Kalmar Eco-Tech '03), 2004, pp.<br />
451-463.<br />
16. Miron, Y., Zeeman, G., van Lier, J. B., Leetinga, G. (2000). The role of sludge<br />
retention time in the hydrolysis and acidification of lipids, carbohydrates and proteins<br />
during digestion of primary sludge in CSTR systems. Water Research, 34 (5), 1705-<br />
1713.<br />
17. Mölder, H (2002). Reoveepuhastus<strong>ja</strong>amades jääkmuda käitluse tehnoloogia<br />
täiustamine mudakoguse vähendamiseks <strong>ja</strong> kasutatavuse tõstmiseks. ETF granti 4283<br />
aruanne.Tallinna Tehnikaülikool.<br />
68(134) Lep7028-VV-15-10-vahearuanne.doc
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