Approbation of alternative polymeric coagulants to eliminate turbidity of model surface water

Автор: Movafagh Sara Ramzani, Taheri Fard Ali Reza, Malah Hamid, Andrianova Maria

Журнал: Строительство уникальных зданий и сооружений @unistroy

Статья в выпуске: 2 (53), 2017 года.

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Performance to remove turbidity was studied in model waters for five coagulants: ferric chloride, alum, polyaluminum chloride, polyferric sulfate and polyaluminum chloride ferrous. In waters with high turbidity (100-300 NTU) performance of coagulants are similar (over 90%). Polymer coagulants showed better performance and low optimal dosages in waters with low turbidity (10 NTU). In general, polyferric sulfate showed better performance in removal of turbidity.

Water treatment, coagulation, polyferric sulfate, alum, polyaluminum chloride, ferric chloride, polyaluminum chloride ferrous

Короткий адрес:

IDR: 14322370   |   DOI: 10.18720/CUBS.53.3

Список литературы Approbation of alternative polymeric coagulants to eliminate turbidity of model surface water

  • Eddy Y. Zeng. A new page for environmental pollution. Environmental Pollution. 2015. Vol. 204, P. A1.
  • Ceyhun Elgin, Oguz Oztunali, Pollution and informal economy. Economic Systems. 2014. Vol. 38, No. 3, Pp. 333-349.
  • Tarique Ahmad, Kafeel Ahmad, Abdul Ahad, Mehtab Alam, Characterization of water treatment sludge and its reuse as coagulant. Journal of Environmental Management. 2016. Vol. 182. Pp. 606-611.
  • Molodkina L. M. Kolloidaya khimija v sfere bezopasnosti vodnyh system . SPb, 2010. 205 p. (rus)
  • Schulz, C. R., and Okun, D. A. Surface Water Treatment for Communities in Developing Countries. John Wiley and Sons, New York. 1984. 299 p.
  • Andrianova M. Ju., Molodkina L.M., Chusov A.N. Changing in contaminants content and disperse state during treatment and transportation of drinking water. Applied Mechanics and Materials. 2014. Vol. 587-589. Pp. 573-577.
  • Prakash N.B., Sockan V., Jayakaran P. Waste Water Treatment by Coagulation and Flocculation. International Journal of Engineering Science and Innovative Technology. 2014. Vol. 3, No. 2. Pp.478-484.
  • Holt P.K., Barton G.W., Wark M., Mitchell C.A. A Quantitative Comparison between Chemical Dosing and Electro coagulation. Colloids and Surfaces A: Physicochemical Engineering Aspects. 2002. Vol. 211, Pp. 233-248.
  • Duan J., Gregory J., Coagulation by hydrolysing metal salts. Advances in Colloid & Interface Science. 2003. Vol. 100-102. Pp. 475-502.
  • Health Canada. Guidelines for Canadian Drinking Water Quality: Guideline Technical Document -Turbidity. Water and Air Quality Bureau, Healthy Environments and Consumer Safety Branch, Health Canada, Ottawa, Ontario. 2012. (Catalogue No H144-9/2013E-PDF), 80 p.
  • Kashkoli H. A. Coagulation chart and usage of coagulants in surface water. Seminar for coagulation in water treatment. 2000. Ahwaz, Iran (in Farci).
  • Dennett K. E., Amirtharajah A., Moran T. F., and Gould J. P. Coagulation: Its Effect on Organic Matter. Journal AWWA. 1996. Vol. 88 No.4, Pp.129 -142.
  • EPA. The history of drinking water treatment. Environmental Protection Agency, Office of Water (4606), Fact Sheet EPA-816-F-00-006, United States. 2000. 4 p.
  • Faust S.D., Osman M. A. Chemistry of Water Treatment. CRC Press. 1998. 600p.
  • Jia Z., He F., Liu Z., Synthesis of polyaluminium chloride with a membrane reactor: operating parameter effects and reaction pathways. Industrial and Engineering Chemistry Research. 2004. Vol. 43, Pp. 12-17.
  • Semmens M. J., Field T. K. Coagulation: Experiences in Organics Removal. Journal AWWA. 1980. Vol. 72 No. 8. Pp. 476-483.
  • Gebbie P. Using polyaluminium coagulants in water treatment. Proceedings of 64th Annual Water Industry Engineers and Operators’ Conference. Bendigo, Australia 5-6 September, 2001. Pp. 39-47.
  • Tzoupanos N.D., Zouboulis A.I., Zhao Y.-C. The application of novel coagulant reagent (polyaluminium silicate chloride) for the posttreatment of landfill leachates. Chemosphere. 2008. Vol. 73 No.5. Pp. 729-36.
  • He Y., Li F., Jiang J-Q., Wang H. Preparation and application of polyferric sulfate in drinking water treatment. Proceedings of the 12th International conference in Environmental science and technology, 2011. Rhodes, Greece, Pp. A714-A720.
  • Zouboulis A.I., Traskas G. Comparable evaluation of various commercially available aluminum-based coagulants for the treatment of surface water and for the post-treatment of urban wastewater. Journal of Chemical Technology & Biotechnology. 2005. Vol. 80. Pp. 1136-1147.
  • Sinha S., Yoon Y., Amy G., Yoon J. Determining the effectiveness of conventional and alternative coagulants through effective characterization schemes. Chemosphere. 2004. Vol. 57. Pp. 1115-1122.
  • Cao B., Wang M., Gao B., Wang J. Floc Properties of Polyaluminum Ferric Chloride in Water Treatment: The Effect of Al/Fe Molar Ratio and Basicity. Journal of Colloid and Interface Science. 2015. Vol. 458. Pp. 247-254.
  • Leili M., Naghibi A., Norouzi H., Khodabakhshi M.J. The Assessment of Chemical Quality of Drinking Water in Hamadan Province, the West of Iran. Res. Health Sci. 2015. Vol. 15 No.4 Pp.234-238.
  • Vatin N.I., Chechevichkin V.N., Chechevichkin A.V., Shilova Ye., Yakunin L.A. Application of natural zeolites for aquatic and air medium purification. Applied Mechanics and Materials. 2014. Vol. 587-589. Pp. 565-572.
  • Kim A., Chernikov N. Water Quality Improvement by Additional Filtering through Sorption Loading Modified by Fullerenes. Applied Mechanics and Materials, 2015.Vol. 725-726, Pp. 1338-1334.
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