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Article Details

Article Details

  • Article Code : NWSA-2405-1417
  • Article Type : Araştırma Makalesi
  • Publication Number : 1A0064
  • Page Number : 48-54
  • Doi : 10.12739/
  • Abstract Reading : 2379
  • Download : 536
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Issue Details

  • Year : 2010
  • Volume : 5
  • Issue : 1
  • Number of Articles Published : 9
  • Published Date : 1.01.2010

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Dergi Kapağı
Engineering Sciences

Serial Number : 1A
ISSN No. : 1308-7231
Release Interval (in a Year) : 4 Issues

Engin GÜRTEKİN 1

Keywords

THE EFFECTS OF TEMPERATURE ON BIOLOGICAL PHOSPHORUS REMOVAL IN ANAEROBIC/ANOXIC SEQUENCING BATCH REACTOR

Engin GÜRTEKİN 1

ABSTRACT In this study, it was investigated to effects of temperature on biological phosphorus removal (BPR) in two anaerobic/anoxic sequencing batch reactor fed with acetate and glucose. In both reactors, sludge retention time was 10 days and hydraulic retention time was 12 hours. The studies were made at 20o C, 25oC, 30oC and 35oC, respectively. The optimum temperature for biological phosphorus removal in both acetate and glucose-fed anaerobic/anoxic sequencing batch reactor was 20oC.

Keywords
Biological Phosphorus Removal, Temperature Effect, Sequencing Batch Reactor, Phosphorus Release, COD Uptake,

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Authors

Engin GÜRTEKİN (1) (Corresponding Author)
Fırat Üniversitesi
egurtekin@firat.edu.tr

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References
[1] Filipe, C.D., Daigger G.T., Grady C.P.L Jr., (2001). Effects of pH on the rates of aerobic metabolism of phosphate-accumulating and glycogen-accumulating organisms, Water Environment Research, 73, pp:213-222

[2] Filipe, C.D., Daigger, G.T., and Grady, C.P.L.Jr., (2001). pH as a key factor in the competition between glycogen-accumulating organisms and phosphorus-accumulating organisms, Water Environment Research, 73, pp:223-232.

[3] Lemos, P.C., Viana, C., Salgueiro, E.N., Ramos, A.M., Crespo, J.P.S.G. and Reis, M.A.M., (1998). Effect of carbon source on the formation of polyhydroxyalkanoates (PHA) by a phosphate accumulating mixed culture, Enzyme and Microbial Technology, 22, pp:662-671.

[4] Mamais, D. and Jenkins, D., (1992). The effects of MCRT and temperature on enhanced biological phosphorus removal, Water Science and Technology, 26, pp:955-965.

[5] Brdjanovic, D., van Loosdrecht, M.C.M., Hoojmans, C.M., Alaerts, G.J., and Heijnen, J.J., (1997). Temperature effects on physiology of biological phosphorus removal. Journal of Environmental Engineering, 123, pp:144-153.

[6] Brdjanovic, D., Slamet, A., van Loodsdrecht, M.C.M., Hooijmans, C.M., Alaerts, G.J., and Heijnen, J.J., (1998). Influence of temperature on BPR: Process and molecular ecological studies, Water Research, 32, pp:1035-1048.

[7] Cech, J.S. and Hartman, P., (1990). Glucose induced breakdown of enhanced biological phosphate removal, Environmental Technology, 11, pp:651-656.

[8] Cech, J.S. and Hartman, P., (1993). Competition between polyphosphate and polysaccharide accumulating bacteria in enhanced biological phosphate removal systems, Water Research, 27, pp:1219-1225.

[9] Satoh, H., Mino, T., and Matsuo, T., (1994). Deterioration of enhanced biological phosphorus by the domination of micro-organisms without polyphosphate accumulation, Water Science and Technology, 30, pp:203-211.

[10] Metcalf and Eddy, (1991). Wastewater engineering: treatment, disposal and reuse. McGraw-Hill, New York.

[11] Jones, P.H., Tadwalkar, A.D., and Hsu, C.L., (1987). Enhanced uptake of phosphorus by activated sludge-effect of substrate addition. Water Research, 21, pp:301-308.

[12] Yeoman, S., Hunter, M., Stephenson, T., Lester, J.N., and Perry, R., (1988). The removal of phosphorus during wastewater treatment, Environmental Pollution, 49, pp:183-233.

[13] McClintock S.A., Randall, C.W. and Pattarkine, V.M., (1993). Effects of temperature and mean cell residence time on biological nutrient removal processes, Water Environment Research, 65, pp:110-118.

[14] Converti, A., Rovatti, M., and Del Borghi, M., (1995). Biological removal of phosphorus from wastewater by alternating aerobic and anaerobic conditions. Water Research, 29, pp:263-269.

[15] Sell, R.L., Krichten, D.J., Noichl, O.J., and Hartzog, D.G., (1981). Low temperature biological phosphorus removal. Proc., 54th Water Pollution Control Federation Conferation, Detroit.

[16] Kang, S.J., Horvatin, P.J., and Brisco, L., (1985). Full-scale biological phosphorus removal using A/O process in a cold climate. Proc. Int. Conf. Mgmt. Strategies for Phosphorus in the Environment, Selper Ltd, U.K., 72-77.

[17] Barnard, J.L., Stevens, G.M., and Leslie, P.J., (1985). Design strategies for nutrient removal plant. Water Science and Technology, 17, 233-242.

[18] Viconneau, J.C., Hascoet, M.C., and Florentz, M., (1985). The first application of biological phosphorus removal in France. Proc. Int. Conf. Mgmt. Strategies for Phosphorus in the Environment, Selper Ltd, U.K., 47-53.

[19] Florentz, M., Caille, D., Bourdon, F., And Sibony, J., (1987). Biological phosphorus removal in France. Water Science and Technology, 19, pp:1171-1173.

[20] Kern-Jespersen, J.P. and Henze, M., (1993). Biological phosphorus uptake under anoxic and aerobic conditions. Water Research, 27, pp:617-624.

[21] Kuba, T., Smolders, G.J.F., van Loosdrecht, M.C.M., and Heijnen, J.J., (1993). Biological phosphorus removal from wastewater by anaerobic anoxic sequencing batch reactor. Water Science and Technology, 27, pp:241-252.

[22] Ng, W.J., Ong, S.L., and Hu, J.Y., (2001). Denitrifying phosphorus removal by anaerobic/anoxic sequencing batch reactor. Water Science and Technology, 43, pp:139-146.

[23] Kuba, T., van Loosdrecht, M.C.M., and Heijnen, J.J., (1996). A Metabolic model for biological phosphorus removal by denitrifying organisms, Biotechnology and Bioengineering, 52, 685-695.

[24] Zeng, R., Yuan, Z., and Keller, J., (2003). Enrichment of denitrifying glycogen-accumulating organisms in anaerobic/anoxic activated sludge system, Biotechnology and Bioengineering, 81, pp:397-404.

[25] APHA, AWWA, WCPF., (1998). Standart Methods for the Examination of Water and Wastewater, 20th Edition, American Public Health Association, Washington, D.C.

[26] Whang L.M. and Park J.K., (2002). Competition between polyphosphate- and glycogen-accumulating organisms in biological phosphorus removal systems-effect of temperature, Water Science and Technology, 46, pp:191-194.

[27] Panswad, T., Doungchai, A., and Anotai, J., (2003). Temperature effect on microbial community of enhanced biological phosphorus removal system, Water Research, 37, pp:409-415.