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2022 | OriginalPaper | Buchkapitel

Spent Filter Backwash Water Treatment by Coagulation Followed by Ultrafiltration

verfasst von : K. Sukanya, N. Sivarajasekar, K. Saranya

Erschienen in: Industrial Wastewater Treatment

Verlag: Springer International Publishing

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Abstract

Water is required for sustaining life. It is also used in anthropogenic activities such as agriculture, washing, and industries. Emerging technologies to decontaminate wastewater spent filter backwash water (SFBW) and waste sludge have been widely investigated in wastewater treatment plants. Most of the industries produce spent filter backwash water (SFBW). SFBW utilization is important due to the feasible heavy metals recycle, microorganisms and predecessor for disinfection outcomes. Modernization in coagulation and membrane techniques, particularly in Ultrafiltration and micro- treatment, provides an appropriate method for SFBW to assure the water quality needed for reuse. The main advantages of Ultrafiltration (UF) are less land consumption and reliable water quality. It can remove microorganisms from the water completely, improving the biological quality of water. The suspended particles, viruses and colloidal substances in water are purified using this method. As the primary purification technology of urban drinking water, Ultrafiltration is an alternative to recycling industrial wastewater and sewage drains. Compared with the conventional water treatment process, the EC and UF process has higher efficiency, better effects of treatment and low energy consumption. It is important to further investigate ultrafiltration technology to improve the quality of water, protect water resources, and balance the ecological environment.

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Vorheriges Kapitel Recent Developments in Membrane Filtration for Wastewater Treatment

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Adin A, Dean L, Bonner F, Nasser A, Huberman Z (2002) Characterization and destabilization of spent filter backwash water particles. Water Supply 2(2):115–122CrossRef

Ang WL, Mohammad AW, Hilal N, Leo CP (2015) A review on the applicability of integrated/hybrid membrane processes in water treatment and desalination plants. Desalination 363:2–18CrossRef

Appel C, Ma L (2002) Concentration, pH, and surface charge effects on cadmium and lead sorption in three tropical soils. J Environ Qual 31:581–589CrossRefPubMed

Aptel P, Buckley CA (1996) Categories of membrane operations (Ch. 2). In: Mallevialle J, Odendaal PE, Wiesner MR (eds) Water treatment membrane processes. McGraw-Hill, New York

Arora H, Di Giovanni G, Lechevallier M (2001a) Spent filter backwash water contaminants and treatment strategies. J Am Water Works Assoc 93(5):100–112CrossRef

Arora H, Di-Giovanni G, LeChevallier M (2001b) Spent filter backwash water contaminants and treatment strategies. J. AWWA 93:100–112CrossRef

Berthon G (2002) Aluminium speciation in relation to aluminium bioavailability, metabolism and toxicity. Coord Chem Rev 228:319–341CrossRef

Bose P, Reckhow DA (2007) The effect of ozonation on natural organic matter removal by alum coagulation. Water Res 41(7):1516–1524CrossRefPubMed

Bourgeois JC, Walsh ME, Gagnon GA (2004) Comparison of process options for treatment of water treatment residual streams. J Environ Eng Sci 3(6):477–484CrossRef

Boyd CC, Duranceau SJ (2013) Evaluation of ultrafiltration process fouling using a novel transmembrane pressure (TMP) balance approach. J Membr Sci 446:456–464CrossRef

Boyd CC, Duranceau SJ, Tharamapalan J (2012) Impact of carboxylic acid ultrafiltration recycle streams on coagulation. J Water Supply Res Technol AQUA 61(5):306–318CrossRef

Chen F, Peldszus S, Peiris RH, Ruhl AS, Mehrez R, Jekel M, Legge RL, Huck PM (2014) Pilot-scale investigation of drinking water ultrafiltration membrane fouling rates using advanced data analysis techniques. Water Res 48:508–518CrossRefPubMed

Chen Y, Dong BZ, Gao NY, Fan JC (2007) Effect of coagulation pretreatment on fouling of an ultrafiltration membrane. Desalination 204(1–3):181–188CrossRef

Chowdhury S, Mazumder MAJ, Al-Attas O, Husain T (2016) Heavy metals in drinking water: occurrences, implications, and future needs in developing countries. Sci Total Environ 569:476–488CrossRefADSPubMed

Cornwell DA, Lee RG (1994) Waste stream recycling-its effect on water-quality. J AWWA 86:50–63CrossRef

Cornwell DA, Macphee MJ (2001) Effects of spent filter backwash recycle on Cryptosporidium removal. J AWWA 93(4):153–162CrossRef

Das D, Nandi BK (2019) Defluoridization of drinking water by electrocoagulation (EC): process optimization and kinetic study. J Dispersion Sci Technol 40(8):1136–1146CrossRef

Das D, Nandi BK (2021) Arsenic removal from tap water by electrocoagulation: investigation of process parameters, kinetic analysis, and operating cost. J Dispersion Sci Technol 42(3):328–337CrossRef

Dehghani MH, Omrani GA, Karri RR (2021) Solid waste—sources, toxicity, and their consequences to human health. In: Soft computing techniques in solid waste and wastewater management (Elsevier)

Di Giovanni G et al (1999) Quantitation of intact and infectious cryptosporidium parvum oocysts using quantitative sequence detection. Proc 1996 AWWA WQTC, Tampa, Fla

Ebrahimi A, Taheri E, Pashaee A, Mahdavi M (2015) The effectiveness of polyaluminum ferric chloride (PAFCl) for turbidity and color removal from Isfahan raw water. Desalin Water Treat 55:1966–1972CrossRef

Gao B, Yue Q (2005) Effect of ratio and OH−/Al3+ value on the characterization of coagulant poly-aluminum-chloride-sulfate (PACS) and its coagulation performance in water treatment. Chemosphere 61:579–584CrossRefADSPubMed

Gao W, Liang H, Ma J, Han M, Chen Z-L, Han Z-S, Li G-B (2011) Membrane fouling control in ultrafiltration technology for drinking water production: a review. Desalination 272(1–3):1–8CrossRef

Guigui C, Rouch JC, Durand-Bourlier L, Bonnelye V, Aptel P (2002) Impact of coagulation conditions on the in-line coagulation/UF process for drinking water production. Desalination 147(1–3):95–100CrossRef

Howe KJ, Marwah A, Chiu KP, Adham SS (2006) Effect of coagulation on the size of MF and UF membrane foulants. Environ Sci Technol 40(24):7908–7913CrossRefADSPubMed

Huang C, Lin J-L, Lee W-S, Pan JR, Zhao B (2011) Effect of coagulation mechanism on membrane permeability in coagulation-assisted microfiltration for spent filter backwash water recycling. Colloids Surf, A 378:72–78CrossRef

Huang H, Schwab K, Jacangelo JG (2009) Pretreatment for low pressure membranes in water treatment: a review. Environ Sci Technol 43(9):3011–3019CrossRefADSPubMed

Huang H, Young TA, Jacangelo JG (2008) Unified membrane fouling index for low pressure membrane filtration of natural waters: principles and methodology. Environ Sci Technol 42(3):714–720CrossRefADSPubMed

Jacangelo JG, Aieta EM, Carns KE, Cummings EW, Mallevialle J (1989) Assessing Hollow-Fiber Ultrafiltration for Participate Removal. Journal (Amer Water Works Assoc) 81(11):68–75CrossRef

Jermann D, Pronk W, Meylan S, Boller M (2007) Interplay of different NOM fouling mechanisms during Ultrafiltration for drinking water production. Water Res 41(8):1713–1722CrossRefPubMed

Karri RR, Ravindran G, Dehghani MH (2021) Wastewater—sources, toxicity, and their consequences to human health. In: Soft computing techniques in solid waste and wastewater management. Elsevier, pp. 3–33

Lai C-H, Chou Y-C, Yeh H-H (2015) Assessing the interaction effects of coagulation pretreatment and membrane material on UF fouling control using HPSEC combined with peak-fitting. J Membr Sci 474:207–214CrossRef

Lee JD, Lee SH, Jo MH, Park PK, Lee CH, Kwak JW (2000) Effect of coagulation conditions on membrane filtration characteristics in coagulation-microfiltration process for water treatment. Environ Sci Technol 34(17):3780–3788CrossRefADS

Lee W, Lee H-W, Choi J-S, Oh HJ (2013) Effects of transmembrane pressure and ozonation on the reduction of ceramic membrane fouling during water reclamation. Desalin Water Treat 52(4–6):612–617

LeGouellec YA, Cornwell DA, MacPhee MJ (2004) Treating Microfiltration Backwash. J AWWA 96(1):72–83

Lehman SG, Liu L (2009) Application of ceramic membranes with pre-ozonation for treatment of secondary wastewater effluent. Water Res 43(7):2020–2028CrossRefPubMed

Li S, Heijman SGJ, Verberk J, Verliefde ARD, Amy GL, Van Dijk JC (2012) Removal of different fractions of NOM foulants during demineralized water backwashing. Sep Purif Technol 98:186–192CrossRef

Lin JL, Huang CP, Pan JR, Wang DS (2008) Effect of Al (III) speciation on coagulation of highly turbid water. Chemosphere 72:189–196CrossRefADSPubMed

Mahdavi M, Amin MM, Hajizadeh Y, Farrokhzadeh H, Ebrahimi A (2016) Removal of different NOM fractions from spent filter backwash water by polyaluminum ferric chloride and ferric chloride. Arabian J Sci Eng, 1–8

Mahdavi M, Amin MM, Mahvi AH, Pourzamani H, Ebrahimi A (2018) Metals, heavy metals and microorganism removal from spent filter backwash water by hybrid coagulation-UF processes. J Water Reuse Desalination 8(2):225–233CrossRef

Mulder M (1997) Basic principles of membrane technology (2nd edition, corrected). Kluwer Academic Publishers, Dordrecht

Nasser A, Huberman Z, Dean L, Bonner F, Adin A (2002) Coagulation as a pretreatment of SFBW for membrane filtration. Water Supply 2(5–6):301–306CrossRef

Nguyen AH, Tobiason JE, Howe KJ (2011) Fouling indices for low pressure hollow fiber membrane performance assessment. Water Res 45(8):2627–2637CrossRefPubMed

Orrono DI, Lavado RS (2009) Distribution of extractable heavy metals in different soil fractions. Chem Speciat Bioavailab 21:193–198CrossRef

Peter-Varbanets M, Margot J, Traber J, Pronk W (2011) Mechanisms of membrane fouling during ultra-low pressure ultrafiltration. J Membr Sci 377:42–53CrossRef

Raj CBC, Kwong TE, Cheng WW, Fong LM, Tiong SH, Klose PS (2008) Wash water in waterworks: contaminants and process options for reclamation. J Environ Sci 20:1300–1305CrossRef

Reissmann FG, Uhl W (2006) Ultrafiltration for the reuse of spent filter backwash water from drinking water treatment. Desalination 198(1–3):225–235CrossRef

Sartor M, Schlichter B, Gatjal H, Mavrov V (2008) Demonstration of a new hybrid process for the decentralized drinking and service water production from surface water in Thailand. Desalination 222(1–3):528–540CrossRef

Schneider OD, Tobiason JE (2000) Preozonation effects on coagulation. Journal (Amer Water Works Assoc) 92(10):74–87CrossRef

Singer PC, Arlotta C, Snider-Sajdak N, Miltner R (2003) Effectiveness of preand intermediate ozonation on the enhanced coagulation of disinfection byproduct precursors in drinking water. Ozone Sci Eng 25(6):453–471

Song H, Fan X, Zhang Y, Wang T, Feng Y (2001) Application of microfiltration for reuse of backwash water in a conventional water treatment plant-a case study. Water Supply 1(5–6):199–206CrossRef

Song P, Yang Z, Zeng G, Yang X, Xu H, Wang L, Xu R, Xiong W, Ahmad K (2017) Electrocoagulation treatment of arsenic in wastewater: a comprehensive review. Chem Eng J 317:707–725CrossRef

Susanto H (2007) Fouling study in ultrafiltration-mechanism and control via membrane surface modification, Universität Duisburg-Essen, Fakultät für Chemie» Technische Chemie

Sutherland RA (2003) Lead in grain size fractions of road-deposited sediment. Environ Pollut 121:229–237CrossRefPubMed

Thakur LS, Mondal P (2017) Simultaneous Arsenic and fluoride removal from synthetic and real groundwater by electrocoagulation process: parametric and cost evaluation. J Environ Manag 190:102–112CrossRef

Thirugnanasambandham K, Karri RR (2021) Preparation and characterization of Azadirachta indica A. Juss. plant based natural coagulant for the application of urban sewage treatment: modelling and cost assessment. Environ Technol Innov 23:101733

Udayakumar GP, Muthusamy S, Selvaganesh B, Sivarajasekar N, Rambabu K, Sivamani S, Hosseini-Bandegharaei A (2021) Ecofriendly biopolymers and composites: preparation and their applications in water-treatment. Biotechnol Adv, 107815

Van Geluwe S, Braeken L, Van der Bruggen B (2011) Ozone oxidation for the alleviation of membrane fouling by natural organic matter: a review. Water Res 45(12):3551–3570CrossRefPubMed

Walsh ME, Gagnon GA, Alam Z, Andrews RC (2008) Biostability and disinfectant by-product formation in drinking water blended with UF-treated filter backwash water. Water Res 42(8–9):2135–2145CrossRefPubMed

Wang H, Qu F, Ding A, Liang H, Jia R, Li K, Bai L, Chang H, Li G (2016) Combined effects of PAC adsorption and in situ chlorination on membrane fouling in a pilot-scale coagulation and ultrafiltration process. Chem Eng J 283:1374–1383CrossRef

Wang Z, Teychene BT, Chalew TEA, Ajmani GS, Zhou T, Huang H, Wu X (2014) Aluminum-humic colloid formation during pre-coagulation for membrane water treatment: mechanisms and impacts. Water Res 61:171–180CrossRefPubMed

Yu W-Z, Graham N, Liu H-J, Qu J-H (2013) Comparison of FeCl3 and alum pre-treatment on UF membrane fouling. Chem Eng J 234:158–165CrossRef

Zhang L-L, Yang D, Zhong Z-J, Gu P (2008) Application of hybrid coagulation-microfiltration process for treatment of membrane backwash water from waterworks. Sep Purif Technol 62:415–422CrossRef

Zhao H, Hu C, Liu H, Zhao X, Qu J (2008) Role of aluminum speciation in the removal of disinfection byproduct precursors by a coagulation process. Environ Sci Technol 42:5752–5758CrossRefADSPubMed

Zularisam AW, Ismail AF, Salim R (2006) Behaviours of natural organic matter in membrane filtration for surface water treatment—a review. Desalination 194(1–3):211–231CrossRef

Titel: Spent Filter Backwash Water Treatment by Coagulation Followed by Ultrafiltration
verfasst von: K. Sukanya
N. Sivarajasekar
K. Saranya
Verlag: Springer International Publishing
Buch: Industrial Wastewater Treatment
Print ISBN: 978-3-030-98201-0

Electronic ISBN: 978-3-030-98202-7

Copyright-Jahr: 2022
DOI: https://doi.org/10.1007/978-3-030-98202-7_2