奈米薄膜對金門原水中天然有機物之去除研究

Yu-Wen Chen; 陳郁文

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/28708

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	蔣本基
dc.contributor.author	Yu-Wen Chen	en
dc.contributor.author	陳郁文	zh_TW
dc.date.accessioned	2021-06-13T00:18:42Z	-
dc.date.available	2010-07-30
dc.date.copyright	2007-07-30
dc.date.issued	2007
dc.date.submitted	2007-07-27
dc.identifier.citation	Ahn K.H., Song K.G., Cha H.Y. and Yeom I.T. (1999), “Removal of ions in nickel electroplating rinse water using low-pressure nanofiltration.”, Desalination, 122, 77-84. Aiken G.R., McKnight D.M., Thorn K.A. and Thruman E.M. (1992), “Isolation of hydrophilic organic acids from water using non-ionic macroporous resin.”, Organic Geochemistry, 18, 567-573, (Abstract). Amy G. (1990), “Removal of dissolved organic matter by nanofiltration.”, Journal of Environmental Engineering, ASCE, 116, 1200. Amy G.L. and Sierka R.A. (1992), “Molecular-size distributions of dissolved organic matter.”, Journal American Water Works Association, 84, 67-75. Auddy Kausick, De Sirshendu and DasGupta Sunando (2005), “Performance prediction of turbulent promoter enhanced nanofiltration of a dye solution.”, Separation Purification Technology, 43, 85-94. Belfort G., Davis R.H. and Zydney A.L. (1994), “The behavior of suspensions and macromolecular solutions in cross-flow microfiltration.”, Journal of Membrane Science, 96, 1-58. Bellona Christopher, Drewes J rg E., Xu Pei and Amy Gary (2004), “Factors affecting the rejection of organic solutes during NF/RO treatment – a literature review.”, Water Research, 38, 2795-2809. Benitez F. Javier, Acero Juan L. and Leal Ana I. (2006), “Application of microfiltration and ultrafiltration processes to cork processing wastewaters and assessment of the membrane fouling.”, Separation Purification Technology, 50, 354-364. Chen C.M. (2004), “Study of nanofiltration membrane process in drinking water treatment.”, NPUST Thesis. Cheryan Munir (1998), “Ultrafiltration and Microfiltration Handbook.”, Technomic, p-46. Chiang B.H. and Cheryan M. (1987), “Modeling of hollow fiber ultrafiltration of skimmilk under mass transfer limiting condition.”, Journal of Food Engineering, 6, 241-255. Cho Jaeweon, Gary Amy and Pellegrino John (2000), “Membrane filtration of natural organic matters: factors and mechanisms affecting rejection and flux decline with charged ultrafiltration (UF) membrane.”, Journal of Membrane Science, 164, 89-110. Cho Jeaweon, Amy Gary, Pellegrino John and Yoon Yeomin (1998), “Characterization of clean and natural organic matter (NOM) fouled NF and UF membranes, and foulants characterization.”, Desalination, 118, 101-108. Choi Y. (2003), “Critical flux, resistance and removal of contaminants in ultrafiltration (UF) of natural organic materials.”, PhD Thesis, Pennsylvania State University. Combe C., Molis E., Lucas P., Riley R. and Clark M. (1999), “The effect of CA membrane properties on adsorptive fouling by humic acid.”, Journal of Membrane Science, 154, 73-87. Decloux M., Dornier M. and Gratius I. (1996), “Crossflow microfiltration of gum Arabic solutions: comparison of the classical system with the co-current permeate flow system.”, International journal of Food Science and Technology, 31, 153-166. Dey T.K., Ramachandhran V. and Misra B.M. (2000), “Selectivity of anionic species in binary mixed electrolyte systems for nanofiltration membranes.”, Desalination, 127, 165-175. Elmaleh S. and Ghaffor N. (1996), “Upgarding oil refinery effluents by cross-flow ultrafiltration.”, Water Science Technology, 34, 231-238. Ernst Mathias, Bismarck Alexander, Springer gen and Jekel Martin (2000), “Zeta-potential and rejection rates of a polyethersulfone nanofiltration membrane in single salt solutions.”, Journal of Membrane Science, 165, 251-259. Fan Linhua, Harris John L., Roddick Felicity A. and Booker NIC A. (2001), “Influence of the characteristics of natural organic matter on the fouling of microfiltration membranes.”, Water Research, 35, 4455-4463. Garba Y., Taha S., Gondrexon N. and Dorange G. (2000), “Mechanisms involved in cadmium salts transport through a nanofiltration membrane: characterization and distribution.”, Journal of Membrane Science, 168, 135-141. Garcia-Akeman J. and Dickson J.M. (2004), “Permeation of mixed-salt solutions with commercial and pore-filled nanofiltration membranes: membrane charge inversion phenomena.”, Journal of Membrane Science, 239, 163-172. Gray S.R., Ritchie C.B. and Bolto B.A. (2004), “Effect of fractionated NOM on low pressure membrane flux declines.”, Water Science and Technology: Water Supply, 4, 189-196. Hong S. and Elimelech M. (1997), “Chemical and physical aspects of natural organic matter (NOM) fouling of nanofiltration membrane.”, Journal of Membrane Science, 132, 159-181. Humphrey J.L. and Keller G.E. (1997), Separation Process Technology, McGraw-Hill Companies, NY, U.S.A. Inaba Toshinori and Suzuki Noriyuki (2003), “Gel permeation chromatography for fractionation and isotope ratio analysis of steranes and triterpanes in oils.”, Organic Geochemistry, 34, 635-641. Jaffrin M.Y., Fupta B.B. and Blancpain P. (1990), “Membrane fouling control by backflushing in microfiltration with mineral membranes.”, Proceedings of the 5th World Filtration Congress, Nice, France, 479-483. Jansen R. H. S., Zwijnenburg A., Van der meer W. G. J. and Wessling M. (2006), “Outside-in trimming of humic substances during ozonation in a membrane contactor.”, Environmental Science & Technology, 40, 6460-6465. Jarusutthirak Chalor, Amy Gary and Croue Jean-Philippe (2002), “Fouling characteristics of wastewater effluent organic matter (EfOM) isolates on NF and UF membranes.”, Desalination, 145, 247-255. Jones K.L. and Melia C.R. O’ (2000), “Protein and humic acid adsorption onto hydrophilic membrane surfaces: effect of pH and ionic strength.”, Journal of Membrane Science, 165, 31-46. Kim Mi Hyung and Yu Myong Jin (2005), “Characterization of NOM in the Han River and evaluation of treatability using UF-NF membrane.”, Environmental Research, 97, 116-123. Ku Young, Chen Shi-Wei and Wang Wen-Yu (2005), “Effect of solution composition on the removal of copper ions by nanofiltration.”, Separation Purification Technology, 43, 135-142. Kwon Boksoon, Cho Jaeweon, Park Noeon and Pellegrino John (2006), “Organic nanocolloid fouling in UF membranes.”, Journal of Membrane Science, 279, 209-219. Kwon Boksoon, Lee Sangyoup, Cho Jaeweon, Ahn Hyowon, Lee Dongjoo and Shin Heung Sup (2005), “Biodegradability, DBP formation, and membrane fouling potential of natural organic matter: characterization and controllability.”, Environmental Science & Technology, 39, 732-739. Lee Sangyoup, Kwon Boksoon, Sun Minjung and Cho Jaeweon (2005), “Characterization of NOM included in NF and UF membrane permeates.”, Desalination, 173, 131-142. Lin C., Lin T. and Hao O.J. (1999), “Effects of humic substance characteristics on UF performance.”, Water Research, 34, 1097-1106. Lin Y.L. (2007), “Nanofiltration for removing organic precursors of disinfection by-products in drinking water treatment process.”, NTU Thesis. Maarten A., Swart P. and Jacobs E.P. (1998), “Humic membranes foultants in natural brown water: characterization and removal.”, Desalination, 153, 215-227. Maarten A., Swart P. and Jacobs E.P. (1999), “Feed water pretreatment methods to reduce membrane fouling by natural organic matter.”, Journal of Membrane Science, 162, 51-62. Madaeni Sayed S., Fane Anthony G. and Wiley Dianne E. (1999), “Factors influencing critical flux in membrane filtration of activated sludge.”, Journal of Chemical Technology and Biotechnology, 74, 539-543. Mallevialle J., Anselme C. and Marsigny O. (1996), “Effect of humic substances on membrane process.”, Aquatic Humic Substances, Proc. 193th meeting, American Chemical Society, 749-747. Manttari M.L., Puro J., Jokinen N. and Nystrom M. (2000), “Fouling effect of polysaccharides and humic acid un nanofiltration.”, Journal of Membrane Science, 165, 1-17. Milisic V. and Aim R.B. (1986), “Developing a better understanding of cross-flow microgiltration.”, Filtration and Separation, 23, 28-30. Mo L. and Huang X. (2003), “Fouling characteristics and cleaning strategies in a coagulation-microfiltration combination process for water purification.”, Desalination, 159, 1-9. Mohammadi Toraj and Esmaeelifar Ashkan (2005), “Wastewater treatment of a vegetable oil factory by a hybrid ultrafiltration-activated carbon process.”, Journal of Membrane Science, 254, 129-137. Murthy Z.V.P. and Gupta Sharad K. (1997), “Estimation of mass transfer coefficient using a combined nonlinear membrane transport and film theory model.”, Desalination, 109, 39-49. Nakatsuka S., I. Nakata, and T. Miyano, (1996) “Drinking water treatment by using hollow fiber ultrafiltration membrane.”, Desalination, 106, 55-61. Nilson J.A. and DiGiano F.A. (1996), “Influence of NOM composition on nanofiltration.”, Journal American Water Works Association, 88, 53-66. Oliver B. G. and Lawrence J. (1979), “Haloforms in drinking water: a study of precursors and precursor removal.”, Journal American Water Works Association, 71, 161-163. Park Noeon, Kwon Boksoon, Kim Sang-Don and Cho Jaeweon (2006), “Characterizations of the colloidal and microbial organic matters with respect to membrane foulants.”, Journal of Membrane Science, 275, 29-36. Park Noeon, Kwon Boksoon, Sun Minjeong, Ahn Hyowon, Kim Chunghwan, Kwoak Changho, Lee Dongju, Chae Seonha, Hyung Hoon and Cho Jaeweon (2005), “Application of various membranes to remove NOM typically occurring in Korea with respect to DBP, AOC and transport parameters.”, Desalination, 178, 161-169. Pontalier P.Y., Ismail A. and Ghoul M. (1997), “Mechanisms for the selective rejection of solutes in nanofiltration membranes.”, Separation and Purification Technology, 12, 175-181. Ratanatamskul C., Yamamoto K., Urase T. and Ohgaki S. (1996), “Effect of operating conditions on rejection of anionic pollutants in the water environment by nanofiltration especially in very low pressure range.”, Water Science Technology, 34, 149-156. Reiss C.R., Taylor J.S. and Robert C. (1999), “Surface water treatment using nanofiltration – pilot testing results and design considerations.”, Desalination, 125, 97-112. Sch fer A.I., Fane A.G and Waite T.D. (2000), “Fouling effects on rejection in the membrane filtration of natural waters.”, Desalination, 131, 215-224. Shim Yongki, Lee Hong-Joo, Lee Sangyoup, Moon Seung-Hyeon and Cho Jaeweon (2002), “Effects of natural organic matter and ionic species on membrane surface charge.”, Environmental Science & Technology, 36, 3864-3871. Shon H. K., Vigneswaran S. Aim R. Ben, Ngo H. H., Kim In S. and Cho J. (2005), “Influence of flocculation and adsorption as pretreatment on the fouling of UF and NF membranes: application with biologically treated sewage effluent.”, Environmental Science & Technology, 39, 3864-3871. Siddiqui Mohamed, Amy Gary, Ryan Joseph and Odem Wilbert (2000), “Membranes for the control of natural organic matter from surface waters.”, Water Research, 34, 3355-3370. Song Wonho, Ravindran Varadarajan, Koel Bruce E. And Pirbazari Massoud (2004), “Nanofiltration of natural organic matter with H2O2/UV pretreatment: fouling mitigation and membrane surface characterization.”, Journal of Membrane Science, 241, 143-160. Tan L. and Amy G. L. (1991), “Comparing ozonation and membrane separation for color removal and disinfection by-product control.”, Journal American Water Works Association, 83, 5-74. Tansel B., Bao W.Y. and Tansel I.N. (2000), “Characterization of fouling kinetics in ultrafilation systems by resistances in series model.”, Desalination, 129, 7-14. Thurman E.M. (1985), “Organic geochemistry of natural waters.”, Martinus Nijhoff/Dr W. Junjk, Dordrecht. Visvanathan C., Marsono Bowo Djoko and Basu Biswadeep (1998), “Removal of THMP by nanofiltration: effects of interference parameters.”, Water Research, 32, 3527-3538. Vladisavljevic G.T., Milonjic S.J. Nikolic D. and Pavasovic V.L. (1992), “Influence of temperature on the ultrafilatration of silica sol in a stirred cell.”, Journal of Membrane Science, 66, 9-17. Vrijenhoek E.M. and Waypa J.J. (2000), “Arsenic removal from drinking water by a losses nanofiltration membrane.”, Desalination, 130, 265-277. Weber Walter J., Huang Qingguo and Pinto Roger A. (2005), “Reduction of disinfection byproduct formation by molecular reconfiguration of the fulvic constituents of natural background organic matter.”, Environmental Science & Technology, 39, 6446-6452. Wiesner M.R. and Aptel. P. (1996), “Mass transport and permeate flux and fouling in pressure driven process.”, American Water Works Association, Water Treatment: Membrane Processes, McGraw-Hill. Yuan W. and Zydney A.L. (1999), “Humic acid fouling during microfiltration.”, Journal of Membrane Science, 157, 1-12. Zhao Yu, Taylor James S. and Chellam Shankar (2005), “Predicting RO-NF water quality by modified solution diffusion model and artifical neutral networks.”, Journal of Membrane Science, 263, 38-46. Zularisam A.W., Ismail A. F. and Salim Razman (2006), “Behaviours of natural organic matter in membrane filtration for surface water treatment – a review.”, Desalination, 194, 211-231.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/28708	-
dc.description.abstract	目前台灣飲用水水質日趨嚴格，然部分淨水廠仍以傳統處理單元為主，尚難符合飲用水之水質標準；此外，水中的天然有機物更是造成後續消毒程序產生消毒副產物之主要前趨物質，故本研究以金門太湖淨水廠為例，利用奈米薄膜(NF270)對進行後續處理，期許達成有效處理水中天然有機物之目的。另外，以樹脂鑑定原水特性，並分析水中天然有機物之分子量分佈，結合薄膜特性分析，藉以進行奈米薄膜處理天然原水之效能評估，尋求最適操作條件。金門太湖原水中DOC約6.54 mg/L、SUVA254值約1.70 L/mg m，主要以疏水性有機物為主(58.4%)，分子量分布範圍廣泛，小於1K Da之有機物約佔30%，1K - 5K Da約32%，大於5K Da 佔38%。本研究利用聚醯胺(polyamide)奈米複合(thin-film composite)薄膜(NF270)作後續處理，探討操作壓力(75~150 psi)、掃流速度(0.08~0.60 m/s)及前處理程序(SF及UF)對NF270薄膜程序之影響。研究結果顯示，濾液通量衰減隨操作壓力增加而增加，反之，提高掃流速度則可減緩通量之衰減。掃流速度對DOC處理成效影響不大，但UV254 值隨掃流速度增加而提升；另一方面，DOC及UV254處理成效隨壓力增加而提高，但當壓力超過100 psi時，去除率趨近定值。在操作過程中，薄膜表面會有溶質逐漸累積，進而造成阻力而導致濾液通量衰減，隨著操作壓力增加，薄膜結構更為緻密，溶質亦難通過薄膜而提升去除效率；當掃流速度增加時，薄膜表面易產生擾流現象，因在高掃流速度下會形成較少之質量傳送阻力，因此可減少濃度極化，提升濾液量，減緩濾液通量衰減。在不同前處理試驗中，以UF-NF程序可獲得較高之水通量，此外，UF較SF去除較多之疏水性物質，減緩通量衰減；然而，對於天然有機物之處理則以SF-NF較優。因此，以SF作前處理程序，結合掃流式NF薄膜在100 psi、0.30 m/s操作條件下將可有效處理天然有機物並達到省能源之目的。	zh_TW
dc.description.abstract	The drinking water quality standards in Taiwan are becoming more stringent in the future. However, parts of water treatment plants in Taiwan still employ the conventional treatment processes which are hard to meet the standards. Besides, the natural organic matters (NOMs) are the main precursors of the disinfection by-products (DBPs) during the disinfection process. In this investigation, the Tai-Lake raw water in Kin-men Water Treatment Plant in Taiwan was selected to analyze the NOMs by resins and by molecular weight distribution. The NF270 membrane was characterized to evaluate its performance for reducing the NOMs and then to determine the optimum operating conditions. The DOC concentration in Kin-men raw water was found to be approximately 6.54 mg/L, SUVA254 value was about 1.70 L/mg m and the hydrophobic NOMs (58.4%) were the major components. The molecular weight distributed broadly, i.e., lower than 1K (30%), 1K to 5K (32%) and larger than 5K (38%). This study utilized the polyamide thin-film composite (TFC) nanofiltration membrane (NF270) to treat the water samples and investigated the effects of the transmembrane pressure (75 to 150 psi), the cross-flow velocity (0.08 to 0.60 m/s) and the pre-treatment process (SF and UF) on the rejection ratios of NOMs. The results displays that the permeate flux declines obviously with increasing the transmembrane pressure. On the contrary, increasing the cross-flow velocity could ease off the permeate flux declined. The DOC rejection ratio was not affected by changing the cross-flow velocity (0.08 to 0.60 m/s) but the reduction ratio of UV254 decreased with increasing the cross-flow velocity. On the other, DOC and UV254 reduced efficiently with increasing the applied pressure. However, while the pressure was over 100 psi, the reduction ratio was tended to be constant. During operation, the solute might accumulate on the membrane surface and resulted in the permeate flux declined causing by resistance. Increasing the pressure resulted in the membrane structure became more compact and the solute could hardly pass through the membrane. Hence, the rejection ratio increased. Further, with increasing the cross-flow velocity, the permeate flux increased but the flux declined decreased, due to the reduction of the concentration polarization effect. By comparing the pre-treatment process, the UF-NF processes could obtain the higher permeate flux. The UF membrane process rejected more hydrophobic NOMs than by the rapid sand filter (SF) process and decreased the permeate flux declined. But the SF-NF reduced the NOMs more efficiently than the UF-NF. The SF-NF was the proposed treatment process because it can remove the NOMs effectively with lower energy consumption.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T00:18:42Z (GMT). No. of bitstreams: 1 ntu-96-R94541106-1.pdf: 10846134 bytes, checksum: e46d52cb1a3c6a2c8fdf2593597a4a20 (MD5) Previous issue date: 2007	en
dc.description.tableofcontents	謝誌 Abstract I 摘要 III Contents V List of Figures VIII List of Tables XIII Nomenclature XV Chapter 1 Introduction 1-1 Background 1-1 1-2 Objectives 1-3 Chapter 2 Literature Review 2-1 Classification and Characteristics of NOMs in Surface Water 2-1 2-2 Hydrophobic Resins (DAX-8 and XAD-4) Fractionation 2-4 2-2-1 Principles of Resins Fractionation 2-4 2-2-2 Applications of Resins 2-4 2-3 Gel Filtration Chromatograph 2-5 2-3-1 Principles of Gel Filtration Chromatography 2-5 2-3-2 Applications of Gel Filtration Chromatography 2-5 2-4 Membrane Treatment Process 2-6 2-4-1 Characteristics of Membrane 2-6 2-4-2 Operation Conditions Affected Performance of Membrane Process 2-9 2-4-3 Membrane Process for Rejection of NOMs 2-12 2-4-4 Concentration Polarization and Membrane Fouling 2-15 2-4-5 NF Membrane Rejection Mechanisms 2-18 Chapter 3 Materials and Methods 3-1 Experimental Design 3-1 3-2 Instruments and Methods 3-3 3-2-1 Pretreatment Process 3-3 3-2-2 Membrane Filtration Setup 3-4 3-2-3 Resin Fractionation 3-6 3-2-4 Molecular Weight Distribution 3-8 3-3 Analytical Methods 3-9 3-3-1 TOC Measurement 3-9 3-3-2 UV254 Measurement 3-10 3-3-3 Observation of Membrane Surfaces 3-11 Chapter 4 Results and Discussions 4-1 Characteristics of NF Membrane 4-1 4-1-1 Determination of Membrane Pure Water Permeability 4-1 4-1-2 Identification of Functional Groups of Membrane 4-2 4-1-3 Determination of NF270 Membrane Contact Angle 4-4 4-1-4 SEM Images of NF270 Membrane 4-4 4-1-5 AFM Images of NF270 Membrane 4-6 4-2 Identification of NOMs in Source Water 4-8 4-2-1 NOMs Fractionation of Source Water 4-9 4-2-2 Molecular Weight Distributions of Source Water 4-11 4-3 Effect of Operating Parameters on Rejection Efficiency by NF Membrane 4-14 4-3-1 Effect of Cross-Flow Velocity 4-16 4-3-2 Effect of Operating Pressure 4-22 4-3-3 Effect of Pre-Treatment Process 4-30 4-3-4 Determination of the Optimum Operation Conditions 4-41 4-4 Model Analysis for NOMs Reduction by NF270 Membrane 4-47 Chapter 5 Conclusions and Recommendations 5-1 Conclusions 5-1 5-2 Recommendations 5-2 Reference
dc.language.iso	en
dc.title	奈米薄膜對金門原水中天然有機物之去除研究	zh_TW
dc.title	Rejection of NOMs in Kin-men Raw Water by NF Membrane	en
dc.type	Thesis
dc.date.schoolyear	95-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	張怡怡,曾迪華,林財富,顧洋
dc.subject.keyword	奈米薄膜(NF270),天然有機物,掃流式過濾,自來水處理,	zh_TW
dc.subject.keyword	Nanofiltration (NF270),Natural organic matters (NOMs),Cross-flow,Water treatment,	en
dc.relation.page	122
dc.rights.note	有償授權
dc.date.accepted	2007-07-27
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	環境工程學研究所	zh_TW
顯示於系所單位：	環境工程學研究所

文件中的檔案：

檔案	大小	格式
ntu-96-1.pdf 目前未授權公開取用	10.59 MB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。