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The study was conducted on a laboratory scale with the aim to examine how the type and dose of the aluminium coagulant as well as water pH influence the extent of colloid destabilization. The samples used for the purpose of the study contained water from the River Odra, with a natural or an adjusted pH, and were treated with aluminium sulphate (alum) or prehydrolyzed polyaluminium chlorides. The results obtained have revealed that polyaluminium chlorides are more efficient neutralizers of the negative electrokinetic potential of the colloids than alum. As a consequence, the substitution of alum by polyaluminium chlorides reduced the required concentration (g Al/m3) of watersoluble aluminium hydrolysis products which provided a comparable decrease in the absolute value of the ? potential. The efficiency of polyaluminium chlorides was found to increase with their basicity and with the polymerization of the products of aluminium prehydrolysis. A major factor contributing to the value of the negative ? potential of the colloids and to the extent of their destabilization was the concentration of H+ ions. The decrease in the pH value was concomitant with the decrease in the absolute value of the ? potential of the colloids that were present in the river water and with the increase in the extent of their destabilization by the coagulants examined. The effect of H+ ion concentration (in the water being treated) on the destabilization of colloids was the strongest with the alum coagulant and decreased with the increasing basicity of the polyaluminium chlorides tested.
Czasopismo
Rocznik
Tom
Strony
63--72
Opis fizyczny
bibliogr. 13 poz.
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autor
autor
- Institute of Environmental Protection Engineering, Wybrzeże Wyspiańskiego 27, 50-370 Wrocław, maria.swiderska-broz@pwr.wroc.pl
Bibliografia
- [1] BUSTAMANTE H.A. et al., Interaction between Cryptosporidium oocysts and water treatment coagulants, Wat. Res., 2001, Vol. 35, 13, 3179.
- [2] CHENG W.P., CHI F.H., A study of coagulation mechanisms of polyferric sulfate reacting with humic acid using a fluorescence-quenching method, Wat. Res., 2002, Vol. 36, 11, 4583.
- [3] CHOI K.V., DEMPSEY B.A., In-line coagulation with low-pressure membrane filtration, Wat. Res., 2004, Vol. 38, 4271.
- [4] DENNET K.E. et al., Coagulation: its effect on organic matter, JAWWA, 1996, 4, 136.
- [5] EDZWALD J.K. et al., Polyaluminium coagulants for drinking water, Chemical Water and Wastewater Treatment, Springer-Verlag, 2000, 3.
- [6] EIKEBROKK B. et al., NOM characteristics and treatability by coagulation: Comparison of Norwegian and Australian waters, Chemical Water and Wastewater Treatment, IWA Publishing, 2007, 207.
- [7] Informacje katalogowe o koagulantach, Kemipol sp. z o.o., Police.
- [8] JIANG J.Q., GRAHAM N.J.D., Evaluation of poly-alumino-iron sulphate (PAFS) as a coagulant for water treatment, Chemical Water and Wastewater Treatment, Springer-Verlag, 1998, 15.
- [9] SØGAARD E.G., Production of the coagulation agent PAX-14. Contents of polyaluminium chloride compounds, Chemical Water and Wastewater Treatment, IWA Publishing, 2002, 3.
- [10] TANG H.X., LUAN Z.K., The differences of behaviour and coagulating mechanism between inorganic polymer flocculants and traditional coagulants, Chemical Water and Wastewater Treatment, Springer-Verlag, 1996, 83.
- [11] TANG H.X., LUAN Z.K., Differences in coagulation efficiencies between PACl and PICl, JAWWA, 2003, 1, 79–85.
- [12] TANG H.X. et al., Optimization of the concepts for poly-aluminium species, Chemical Water and Wastewater Treatment, IWA Publishing, 2004, 139.
- [13] Van BENSCHOTEN J.E., EDZWALD J.K., Chemical aspects of coagulation using aluminum salts – I. Hydrolytic reactions of alum and polyaluminum chloride, Wat. Res., 1990, 12, 1519.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BPW8-0010-0007