The use of Zeta Potential Measurement as a Control Tool of Surface Water Coagulation

Mroczko, Dominik; Zimoch, Izabela

doi:10.12911/22998993/118273

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Tytuł artykułu

The use of Zeta Potential Measurement as a Control Tool of Surface Water Coagulation

Autorzy

Mroczko Dominik , Zimoch Izabela

Treść / Zawartość

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DOI

10.12911/22998993/118273

Warianty tytułu

Języki publikacji

Abstrakty

The implementation or optimization of the coagulation process requires prior preliminary tests. Standard Jar-Test method is time-consuming, inaccurate and may not work well, especially for the waters characterized by high variability of quality parameters. Zeta Potential Isoelectric Point (IEP) analysis may give fast and precise data on the coagulant type and dose required for maintaining an efficient coagulation process. The research objects included the surface waters taken directly from the Mała Panew and Odra rivers. The zeta potential and set coagulant dose dependence was measured for each sample. Four aluminum-based coagulants with different characteristics were used in this research: aluminum sulfate (Alum), polyaluminum chloride (PAC), dialuminum chloride pantahydroxide (PACl), polyaluminum chloride hydroxide sulfate (PACS). Charge neutralization effectiveness, by means of Zeta Potential IEP analysis, was the basis for the choice of the most effective coagulant doses. The coagulation process efficacy was based on the parameters of the treated water (pH, turbidity, color, alkalinity), reduction of organic matter (Abs254, Total Organic Carbon (TOC), Dissolved Organic Carbon (DOC)) and residual aluminum contamination. The Zeta Potential utility evaluation was based on the DOC reduction.

Słowa kluczowe

zeta potential isoelectric point coagulation aluminum coagulants surface water

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2020

Tom

Vol. 21, nr 3

Strony

237--242

Opis fizyczny

Bibliogr. 19 poz., rys., tab.

Twórcy

autor

Mroczko Dominik

Silesian University of Technology, Faculty of Energy and Environmental Engineering, Institute of Water and Wastewater Engineering, ul. Konarskiego 18, 44-100 Gliwice, Poland
P.U.T. DEMPOL-ECO, ul. Składowa 9, 45-125 Opole, Poland

autor

Zimoch Izabela

izabela.zimoch@polsl.pl

Silesian University of Technology, Faculty of Energy and Environmental Engineering, Institute of Water and Wastewater Engineering, ul. Konarskiego 18, 44-100 Gliwice, Poland

Bibliografia

1. Chen Z., Luan Z., Fan J., Zhang Z., Peng X., Fan B. 2007. Effect of thermal treatment on the formation and transformation of Keggin Al13 and Al30 species in hydrolytic polymeric aluminum solutions. Colloids and Surfaces a Physicochemical Engineering Aspects, 292 (2–3), 110–118.
2. Chittoor V.V., Molson J. Schirmer M. 2015. Does river restoration affect diurnal and seasonal changes to surface water quality? A study along the Thur River, Switzerland. Science of the Total Environment, 532, 91–102.
3. Cochran J., Barron P., Nabors A., Cox W. 2010. Using a mobile pilot plant to evaluate need and protocol for a previously failed coagulant changeover. Proc. World Environmental and Water Resources Congress 2010: Challenges of Change, 3604–3611.
4. Edney D. 2005. Introduction to the theory of the streaming current meter. Application Note, Accurate Measurements NZ Ltd.
5. Han Y., Jiang Z., Zhou X., Peng D. 2011. The effect of dissolved organic matter on Zeta potential during the coagulation process. 2011 International Conference on Computer Distributed Control and Intelligent Environmental Monitoring.
6. Hunter R.J. 1988. Zeta Potential in Colloid Science. Principles and Applications. Academic Press.
7. Hu C., Liu H., Qu J., Wang D., Ru J. 2006. Coagulation Behavior of Aluminum Salts in Eutrophic Water: Significance of Al13 Species and pH Control. Environmental Science & Technology, 40 (1), 325–331.
8. Lopez-Maldonado E.A, Oropeza-Guzman M.T, Jurado-Baizaval J.L., Ochoa-Teran A. 2014. Coagulation-flocculation mechanism in wastewater treatment plants through zeta potential measurements. Journal of Hazardous Materials, 279, 1–10.
9. Matilainen A., Vepsalainen M., Sillanpaa M. 2010. Natural organic matter removal by coagulation during drinking water treatment: A review. Advances in Colloid and Interface Science, 159 (2), 189–197.
10. Morfesis A., Jacobson A.M., Frollini R., Helgeson M., Billica J., Gertig K.R. 2009. Role of Zeta Potential in the Optimization of Water Treatment Facility Operations. Industrial & Engineering Chemistry Research, 48, 2305–2308
11. Mroczko D., Zimoch I. 2018. Coagulation of pollutions occurring in surface waters during time of dynamic water flow. Ecological Engineering, 19 (2), 15–22 (in Polish).
12. Ordaz-Diaz L.A., Valle-Cervantes S., Rodrigues-Rosales J., Bailon-Salas A.M., Madrid-Del Palacio M., Torres-Fraga K., De la Pena-Arellano L.A. 2017. Zeta potential as a tool to evaluate the optimum performance of a coagulation-flocculation process for wastewater internal treatment for recirculation in the pulp and paper process. BioResources, 12 (3), 5953–5969.
13. Salopek B., Krasic D., Filipovic S. 1992. Measurement and application of zeta-potential. Rudarskogeolosko-naftni zbornik, 4, 147–151.
14. Sappa G., Ergul S., Ferranti F., Ngalya Sweya L. Luciani G. 2015. Effects of seasonal change and seawater intrusion on water quality for drinking and irrigation purposes, in coastal aquifers of Dar es Salaam, Tanzania. Journal of Africa Earth Science, 105, 64–84.
15. Sharp E.L., Banks J., Ballica J.A., Gertig K.R., Parsons S.A., Wilson D., Jefferson B. 2005. Application of zeta potential measurements for coagulation control: pilot-plant experiences from UK and US waters with elevated organics. Water Science and Technology: Water Supply, 5 (5), 49–56
16. Sharp E.L., Parsons S.A., Jefferson B. 2004. The effects of changing NOM composition and characteristics on coagulation performance, optimization and control. Water Science and Technology: Water Supply, 4 (4), 95–102
17. Tang H., Xiao F., Wang D. 2015. Speciation, stability, and coagulation mechanisms of hydroxyl aluminum clusters formed by PACl and alum: A critical review. Advances in Colloid and Interface Science, 226, 78–85
18. Tsirkunov V.V, Nikanorov A.M., Laznik M.M., Dongwei, Z. 1992. Analysis of long-term and seasonal river water quality changes in Latvia. Water Research, 26, 1203–1216.
19. Zhang P., Hahn H.H, Hoffmann E., Zeng G. 2004. Influence of some additives to aluminium species distribution in aluminium coagulants. Chemosphere, 57 (10), 1489–1494.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).

Typ dokumentu

Bibliografia

Identyfikator YADDA

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