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| 論文分類 | 碩士論文 |
|---|---|
| 學號 | 9065603 |
| 姓名 | 鐘興 |
| 標題(中) | 台中市福田水資源回收中心下水道系統微生物族群及水質變動之研究 |
| 標題(英) | The Study of Microbial Population and Water Quality Variations of the Sewer System for the Futien Water Resources Recycling Center in Taichung |
| 指導教授 | 白子易 |
| 畢業日期 | 2004-01 |
| 附件檔案 | |
| 參考連結 | http://ir.lib.cyut.edu.tw:8080/handle/310901800/1693 |
| 摘要 | 本研究以台中市福田水資源回收中心下水道系統探討微生物族群、溶氧傳輸、污水中活性biomass及水質變動之反應機制,並進行OUR批次實驗以估計下水道系統中微生物族群中異營菌 (XH)、氨氮氧化菌(XAOB) 、亞硝酸鹽氧化菌 (XNOB) 等活性biomass的比例及動力參數。 本研究實驗項目包括:pH值、水溫、DO、BOD5、TCOD、SS、氨氮 (NH3-N) 、總氮 (T-N) 、OUR批次實驗等。實驗結果,獲致結論:(1)污水下水道起始點濃度低、有機物少,上游流速最快。(2)SS的污染物濃度由上游至 |
| 參考文獻 | I.中文部份 書籍: 歐陽嶠暉,”下水道工程學”,長松,台北(2000)。 歐陽嶠暉,”環境工程概論”,中華民國環境工程學會,台北(1994)。 黃政賢,”污水工程”,高立圖書有限公司,台北(1995)。 陳國誠,”廢水生物處理學”,國立編譯館,茂昌圖書有限公司,台北(1991)。 研討會論文: 徐毓蘭、張德明、葉美賢、蕭如容、許雅芬、阮慕玲、蔡茂昇、陳啟祥、林畢修平,〝攝氧率測定於廢水處里之應用〞,中華環境工程學會,第27屆廢水處裡技術研討會,台北市台灣大學,W-A-P08-P13,台北(2002)。 白子易、江舟峰、鐘興、許庭維、陳盈如、蘇奕綾、羅永翔、何欣憲, 〝台中市福田水資源回收廠下水道管網現地水質變動之研究〞,中華環境工程學會,第28屆廢水處裡技術研討會,台中市中興大學,台中(2003)。 博碩士論文: 白子易,“下水道系統生化動力模式建立之研究”,國立中央大學環境工程學研究所博士論文,中壢(2001)。 廖婉君,“利用攝氧率量測AO活性污泥程序異營菌質量及動力參數之研究”,私立朝陽科技大學環境工程與管理研究所碩士論文,霧峰(2003)。 研究報告: 台中市污水下水道系統整體規劃報告(1998)。 II.英文部份 Abdul-Tailb S., Hvitved-jacobsen T., Vollertsen J. and Ujang. Z. (2002). Anoxictransfomations of wastewater organic matter in sewers-process Kinetics, model concept and wastewater treatment potential, Water Science and Technology., 45(3), 53-60. Balmer P. and Tagizadeh-Nasser M. (1995). Oxygen transfer in gravity flow sewers, Wat. Sci. Tech., 31(7), 127-135. Bjerre H.L., Hvitved-Jacobsen T., Schlegel S. and Teichgraber B. (1998b). Modeling of aerobic wastewater transformations under sewer conditions in the Ernscher River, Germany, Environ. Sci. Tech., 70(6), 1151-1160. Davies J.W., Butler D., Small J.L., Sekuloski V. and Jefferies C. (1998). Gross solids transport and degradation, Wat. Sci. Tech., 37(1), 61-68. Dobbins w. e.(1964). BOD and oxygen relationships in stream, J. San. Eng. Div., ASCE, 94, 319-344. Gromaire-Mertz M.C., Chebbo G. and Saad M. (1998). Origins and characteristics of urban wet weather pollution in combined sewer systems: the experimental urban catchment “LE MARAIS” in Paris, Wat. Sci. Tech., 37(1), 35-43. Gudjonsson G., Vollertsen J. and Hvitved-jacobsen T. (2002). Dissolved oxygen in gravity sewers–measurement and simulation, Water Science and Technology., 45(3), 35-44. Henze M., Harremoes P., Jansen J.C. and Arvin E. (1995). Wastewater Treatment: Biological and Chemical Processes, Springer-Verlag, Berlin. Hvitved-Jacobsen T., Vollertsen J. and Nielsen P.H. (1998a). A process and model concept for microbial wastewater transformations in gravity sewers, Wat. Sci. Tech., 37(1), 233-241. Hvitved-Jacobsen T., J.Vollertsen and J.S. Matos (2002). The sewer as a bioreator-a dry weather approach, Water Science and Technology., 45(3), 11-24. Jensen N.Aa. (1994). Air-water oxygen transfer in gravity sewers, Ph.D. Thesis. Env. Lab. Aalborg University, Denmark. Jimenez C.B. and Landa VH.(1998). Physico-chemical and bacteriological characterization of wastewater from Mexico City, Wat. Sci. Tech., 37(1), 1-8. Krenkel P.A. and Orlob G.T.(1962). Turbulent diffusion and the reaeration coefficient, J. San. Eng., Dive., ASCE, 88(SA2),53-58. Kristensen, G. H., and Jorgensen, P. E., “Characterization of Functional Microorganism Groups and Substrate in Activated Sludge and Wastewater by AUR, NUR and OUR,” Wat. Sci. Tech., Vol. 25, No. 6, pp. 43-57 (1997). Langeveld J.G., Clemens F.H.L.R. and van der Graaf J.H.J.M. (2002). Increasing wasterwater system performance – the importance of interactions between sewerage and wastewater treatment, Water Science and Technology., 45(3), 45-52. Lau Y.L (1990). Modelling the consumption of dissvoled contaminants by biofilm periphyton in open channel, Wat. Res., 24(10), 1269-1274. Lin S.H., Lin T.M., and Leu H.G. (1998). Determination of oxygen diffusion coefficient in wastewaters, J. Env. Eng., ASCE, 116(4), 988-990. Nielsen P.H., Raunkjær K., Norsker N.H., Jensen N.A. and Hvitved-Jacobsen T. (1992). Transformation of wastewater in sewer systems - a review, Wat. Sci. Tech., 25(6),17-31. O,Connor D.J. and Dobbins W.E.(1958). Mechanisms of reaeration in natural streams. Transtions, ASCE,123, 641-684. Owens M., edwards R.W. AND Gibbs j.w.(1964). Some reaeration studies in streams, Int J. Air Wat. Poll.,8,469-486. Pai T.Y., Ouyang C.F., Chen C.Y., Leu H.K. and Liao, Y.C. (2000d) The simulation of transformation of nitrogen compounds in the sewer, 1st World Congress of the IWA, Paris. Parkhurst J.D. andPomeroy R.D.(1972). Oxygen Absorption in streams, J. San. Eng., Dive., ASCE,98(SAI), 101-124. Seidl M., Servais P., Martaud M., Gandouin C. and Mouchel J.M. (1998). Organic carbon biodegradability and heterotrophic bacteria along a combined sewer catchment during rain events, Wat. Sci. Tech., 37(1), 25-33. Tanaka N and Hvitved-Jacobsen T.(1998).Transformation of wastewater organic matter in sewers under changing aerobic/anaerobic conditions. Wat. Sci. Tech.,37(1),105-113. Thackston E.L. and Krenkel P.A.(1969).Reaeration prediction in natural streams, J. San.Eng. Div.,ASCE, 95(SAI),65-94. Tsivoglou E.C. and Wallace J.R.(1972). Characterization of stream reaeration capacity, Report No EPA-R2-72-012., U.S. Enviromental protection Agency, Washington DC. Vollertsen J. and Hvitved-Jacobsen T.(1998). Aerobic microbial transformations of resuspended sediments in combined sewers- a conceptual model, Wat. Sci. Tech., 37(1), 69-76. Vollertsen J., and Hvitved-Jacobsen T.(2002). Biodegradability of wastewater-a m ethod for COD-fraction, Water Science and Technology., 45(3), 25-34. |
