牡蠣殼礫間處理初期操作對都市污水之淨化

Cheng-Shiang Kuo; 郭正翔

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/42547

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	張文亮
dc.contributor.author	Cheng-Shiang Kuo	en
dc.contributor.author	郭正翔	zh_TW
dc.date.accessioned	2021-06-15T01:15:58Z	-
dc.date.available	2010-07-31
dc.date.copyright	2009-07-31
dc.date.issued	2009
dc.date.submitted	2009-07-28
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Domestic wastewater treatment through constructed wetland in India, Water Science Technology, 32(3): 291-294. 10. Kadlec, R. H. and Hey, D. L., 1994. Constructed wetlands for river water quality improvement. Water Science Technology, 4: 159-168. 11. Kantawanichkul, S., Kladprasert, S. and Brix, H., 2009. Treatment of high-strength wastewater in tropical vertical flow constructed wetlands planted with Typha angustifolia and Cyperus involucratus. Ecological Engineering, 35: 238-247. 12. Korkusuz, E. A., Beklioglu, M. and Demirer, G. N., 2005. Comparison of the Treatment Performances of Blast Furnace Slag-Based and Gravel-Based Vertical Flow Wetlands Operated Identically for Domestic Wastewater Treatment in Turkey. Ecological Engineering, 24: 187-200. 13. Kwon, H. B., Lee, C. W., Jun, B. S., Yun, J. D., Weon, S. Y. and Ben K., 2004. Recycling waste oyster shells for eutrophication control. Resources, Conservation and Recycling, 41(1): 75-82. 14. Mitchell, C. and McNevin, D., 2001. Alternative Analysis of BOD Removal in Subsurface Flow Constructed Wetlands Employing Monod Kinetics. Water Resource, 35(5): 1295-1303. 15. Nanasivayam, C., Sakoda A., and Suzuki M., 2005. Removal of phosphate by adsorption onto oyster shell powder – kinetic studies, Journal of Chemical Technology & Biotechnology, 80: 356-358. 16. Nelson, D. L. and Cox, M. M., 2005. Lehninger Principles of Biochemistry, 4th Ed. W. H. Freeman and Company, New York, U.S.A. 17. Olga, U. B., 1994. Investigation into the Use of Constructed Reedbeds for Municipal waste Dump Leachate Treatment. Water Science Technology, 29: 289-294. 18. Olga, U. B. and Tjasa, B., 1995. Integrated constructed Wetland for Small Communities. Water Science Technology, 32: 41-47. 19. Park. Y. S., Moon, J. H., Kim, D. S. and Ahn, K. H., 2004. Treatment of a polluted stream by a fixed-bed biofilm reactor with sludge discharger and backwashing system. Chemical Engineering Journal, 99: 265-271. 20. Park, W. H. and Polprasert, C., 2008. Roles of oyster shells in an integrated constructed wetland system designed for P removal. Ecological Engineering , 34(1): 50-56. 21. Philip, M., Franklin, D. D., and Ralph, W. G. W., 1969. The composition of fossil oyster shell proteins. Biochemistry：Matter et al, 64: 970-972. 22. Platzer, C., 1999. Design Recommendations for subsurface Flow Constructed Wetlands for Nitrification and Denitrification. Water Science Technology. 40: 257-263. 23. Reed, S. C., Middlebrooks, E, J. and Crites, R. W., 1988. Natural Systems for Waste Management and Treatment, 1st Ed. McGraw-Hill, Inc. USA. 24. Scholz, M. and Xu, J., 2002. Comparison of Constructed Reed Beds with Different Filter Media and Macrophytes Treating Urban Stream Water Contaminated with Lead and Copper. Ecological Engineering, 18: 385-390. 25. Seo, D. C., Cho, J. S., Lee, H. J., and Heo. J. S., 2005. Phosphorous retention capacity of filter media for estimating the longevity of constructed wetland. Water Resource, 39: 2445-2447. 26. Skenzel, H. B., 1963. Aragonite and calcite as constituents of adult oyster shells, Science, 142: 232-233. 27. Steer, D. N., Fraser, L. H. and Seibert, B. A., 2005. Cell-to-cell Pollution Reduction Effectiveness of Subsurface Domestic Treatment Wetlands. Bioresource Technology, 96: 969-976. 28. Sun, G., Zhao, Y. Q. and Allen, S. J., 2007. An Alternative Arrangement of Gravel Media in Tidal Flow Reed Beds Treating Pig Farm Wastewater. Water Air Soil Pollution, 182: 13-19. 29. Tchobanoglous, G. and Schroeder, E. D., 1985. Water Quality. Addison-Wesley Publishing Company, Inc. U.S.A. 30. Thornley, J. H. M. and Johnson, I. R., 1990. Plant and Crop Modelling. Oxford University, U. K. 31. Totten, D. K., Daridson, F. D. and Wyckoff, R. W. G., 1972. Amino-acid composition of heated oyster shells, Proceedings of the National Academy of Sciences, 69: 784-785. 32. Volodymyr, I., Olena, S., Prakitsin, S. and Piamsak M., 2006. Aggregation of ammonia-oxidizing bacteria in microbial biofilm on oyster shell surface. World Journal of Microbiology and Biotechnology, 22(8): 807-812. 33. Vymazal, J., 1998. Constructed wetlands for wastewater treatment in Europe. Backhuys Publishers, Czech Rpublic. 34. Wheaton, F., 2007. Review of oyster shell properties - part II. thermal properties. Aquacultural Engineering, 37: 14-23. 35. Yalcuk, A. and Ugurlu, A., 2009. Comparison of horizontal and vertical constructed wetland systems for landfill leachate treatment. Bioresource Technology,100(9): 2521-2526.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/42547	-
dc.description.abstract	本研究以嘉義縣東石鄉水產養殖所產生的廢棄牡蠣殼作為礫間接觸基質材料，於台北縣二重疏洪道內處理民生污水。提供應用臺灣廢棄牡蠣殼作為礫間接觸處理材料之可行性及其水質淨化之果效。水質淨化結果顯示，水頭控制牡蠣殼槽之平均單位面積BOD5、懸浮固體、氨態氮、硝酸態氮、氨態氮＋硝酸態氮、總磷、正磷之去除量可以達到13.80、51.75、7.20、0.96、4.53、0.53、0.33 g/day.m2。20℃BOD5一階分解係數為2.40 day-1，證明利用牡蠣殼礫間接觸對民生污水有淨化之效益。管路配水牡犡殼槽對於污水淨化具有較高負荷量。於槽體內部對水體再曝氣可增加並穩定槽體淨化之功效。槽體操作實驗結果顯示，水頭控制槽體之水力停留係數比值為0.7~0.8時，槽體具有較高淨化果效。管路配水槽體之水力停留係數比值大於1.36時，槽體具有較高淨化果效。故可利用調整入流流量與控制水位達到槽體均勻流流況之最佳水力停留時間。	zh_TW
dc.description.abstract	The purpose of this study is to utilize wasted oyster shells from Dong-shih, Chia-yi County as the contacted bed media to purify domestic wastewater on Er Chong drain flooded fields, Taipei County, and to provide the availability of using wasted oyster shells and water purification efficiency. In the results of the head control of overland flow with oyster shells systems, the average of mass removal of BOD5, SS, NH4+-N, NO3--N, NH4+-N+ NO3--N, TP, PO4-P were 13.80, 51.75, 7.20, 0.96, 4.53, 0.53, 0.33 g/day.m2. The BOD5 first-order reaction reducing rate constant in 20℃was 2.40 day-1. Consequently, using oyster shells showed the potential for wastewater purification by contacted bed. The gated distribution pipe of overland flow with oyster shells systems performed efficiently under much more wastewater hydraulic loading rate. Re-aerated treatment was able to increase and stabilize the pollution purification. Through operation processes, the head control of overland flow systems performed efficiency purification until the hydraulic retention time ratio between 0.7~0.8. The gated distribution of overland flow systems performed efficiency purification until the hydraulic retention time ratio higher than 1.36. The treatment systems should be managed the influent and water level to construct uniform flow under the optimal hydraulic retention time.	en
dc.description.provenance	Made available in DSpace on 2021-06-15T01:15:58Z (GMT). No. of bitstreams: 1 ntu-98-R96622048-1.pdf: 3100266 bytes, checksum: 2c4e1d78d58c90efa3bc1634f65e171e (MD5) Previous issue date: 2009	en
dc.description.tableofcontents	目錄中文摘要……………………………………………………………………………Ⅰ 英文摘要……………………………………………………………………………Ⅱ 目錄 ……………………………………………………………………………Ⅲ 圖目錄 ……………………………………………………………………………Ⅳ 表目錄………………………………………………………………………………Ⅴ 第一章前言.....................................................1 第二章文獻回顧.................................................2 2.1 人工濕地.................................................2 2.2 地下流人工濕地...........................................2 2.3 不同流況之地下流人工濕地.................................3 2.4 使用不同基質之地下流人工濕地.............................3 2.5 臺灣礫間接觸案例.........................................5 2.6 牡蠣殼材料介紹...........................................5 2.7 牡蠣殼對磷之吸附.........................................6 2.8 應用牡蠣殼作為礫間接觸基質案例...........................6 2.9 牡蠣殼礫間接觸淨化機制...................................6 2.10 研究目的.................................................7 第三章理論.....................................................9 3.1 濃度移除率...............................................9 3.2 質量移除率...............................................9 3.3 BOD5一階分解係數........................................9 3.4 單位面積去除量..........................................10 3.5 Michaelis-Menten Equation.................................11 3.6 飽和導水係數............................................12 3.7 理論槽體水力停留時間....................................12 3.8 槽體水力停留時間........................................14 3.9 水力停留係數比值........................................15 第四章試驗方法................................................16 4.1 背景資料................................................16 4.1.1 位置....................................................16 4.1.2 氣候....................................................17 4.1.3 水文....................................................17 4.2 實驗設計................................................18 4.2.1 模場規格................................................18 4.2.2 槽體流況與代號..........................................19 4.2.3 採樣方式................................................20 4.2.4 檢驗項目與方法..........................................20 4.3 水樣菌種(原核生物)分析..................................21 4.3.1 培養基製備..............................................21 4.3.2 活菌培養與菌落計算......................................21 4.3.3 細菌純化................................................22 4.3.4 聚合酶連鎖反應..........................................22 4.3.5 膠體電泳................................................22 4.3.6 限制切割片段長度多型性..................................23 4.4 生物膜厚度與型態........................................23 第五章結果與討論..............................................25 5.1 槽體孔隙率與水位率定....................................25 5.2 槽體導水係數與入流流量率定..............................27 5.3 水力停留係數比值與水質淨化果效比較......................29 5.3.1 水力停留係數比值與各處理單元單位面積BOD5去除量........29 5.3.2 水力停留係數比值與各處理單元BOD5一階分解係數（20℃）....31 5.3.3 水力停留係數比值與各處理單元單位面積SS去除量...........32 5.3.4 水力停留係數比值與各處理單元單位面積氨態氮去除量........33 5.3.5 水力停留係數比值與各處理單元單位面積硝酸態氮去除量......34 5.3.6 水力停留係數比值與各處理單元單位面積氨態氮硝酸態氮去除量35 5.3.7 水力停留係數比值與各處理單元單位面積總磷去除量..........36 5.3.8 水力停留係數比值與各處理單元單位面積正磷去除量..........36 5.4 以Michaelis-Menten Equation推估槽體BOD5最大去除量與入流濃度 .......................................................37 5.5 菌種分析結果............................................39 5.6 生物膜厚度與型態........................................41 5.6.1 生物膜厚度..............................................41 5.6.2 生物膜型態..............................................43 第六章結論與建議..............................................44 6.1 結論...................................................44 6.2 建議...................................................45 參考文獻 ........................................................46 附錄A 公式代號對照表 .........................................49 附錄B 原始數據................................................51 圖目錄圖4-1 實驗場址之位置示意圖..................................... 16 圖4-2 礫間處理場址配置示意圖................................... 18 圖4-3 二重疏洪道牡蠣殼礫間接觸場址..............................19 圖5-1 水頭控制曝氣牡蠣殼槽孔隙率與水深關係......................25 圖5-2 水頭控制礫石槽孔隙率與水深關係............................25 圖5-3 水頭控制牡蠣殼槽孔隙率與水深關係..........................26 圖5-4 管路配水牡蠣殼槽孔隙率與水深關係......................... 26 圖5-5 水頭控制曝氣牡蠣殼槽飽和導水係數與入流流量之關係..........27 圖5-6 水頭控制礫石槽飽和導水係數與入流流量之關係................27 圖5-7 水頭控制牡蠣殼槽飽和導水係數與入流流量之關係..............28 圖5-8 管路配水牡蠣殼槽圖飽和導水係數與入流流量之關係............28 圖5-9 水頭控制曝氣牡蠣殼槽BOD5入流濃度與單位面積去除量之關係....37 圖5-10 水頭控制礫石槽BOD5入流濃度與單位面積去除量之關係..........37 圖5-11 水頭控制牡蠣殼槽BOD5入流濃度與單位面積去除量之關係........38 圖5-12 管路配水牡犡殼槽BOD5入流濃度與單位面積去除量之關係........38 表目錄表 5-1 各處理單元單位面積BOD5去除量..............................29 表 5-2 各處理單元BOD5一階分解係數............................... 31 表 5-3 各處理單元單位面積SS去除量................................32表5-4 各處理單元單位面積氨態氮去除量.............................33 表5-5 各處理單元單位面積硝酸態氮去除量...........................34 表5-6 各處理單元單位面積氨態氮+硝酸態氮之去除量..................35 表5-7 各處理單元單位面積總磷去除量...............................36 表5-8 各處理單元單位面積正磷去除量...............................36 表5-9 各槽體之最大單位面積BOD5去除量與可處理最大BOD5入流濃度..39 表5-10 菌種外部特徵...............................................39 表5-11 菌種基因序列比對結果.......................................40 表5-12 各處理單元生物膜不同時間之厚度.............................41 表5-13 牡蠣殼生物膜型態..........................................43
dc.language.iso	zh-TW
dc.subject	牡蠣殼	zh_TW
dc.subject	人工濕地	zh_TW
dc.subject	礫間接觸	zh_TW
dc.subject	生物膜	zh_TW
dc.subject	contacted bed	en
dc.subject	constructed wetland	en
dc.subject	biofilm	en
dc.subject	oyster shell	en
dc.title	牡蠣殼礫間處理初期操作對都市污水之淨化	zh_TW
dc.title	Initial Operation of Purification of Municipal Wastewater by Oyster Shell Contacted Beds	en
dc.type	Thesis
dc.date.schoolyear	97-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	張尊國,張倉榮,游進裕
dc.subject.keyword	人工濕地,礫間接觸,牡蠣殼,生物膜,	zh_TW
dc.subject.keyword	constructed wetland,contacted bed,oyster shell,biofilm,	en
dc.relation.page	76
dc.rights.note	有償授權
dc.date.accepted	2009-07-28
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	生物環境系統工程學研究所	zh_TW
顯示於系所單位：	生物環境系統工程學系

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