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Journal of Zhejiang University SCIENCE B 2008 Vol.9 No.3 P.232-242

http://doi.org/10.1631/jzus.B0710634


Problems of drinking water treatment along Ismailia Canal Province, Egypt


Author(s):  Mohamed H. GERIESH, Klaus-Dieter BALKE, Ahmed E. EL-RAYES

Affiliation(s):  Geology Department, Faculty of Science, Suez Canal University, P.C. 41522, Ismailia, Egypt; more

Corresponding email(s):   helmi_mohamed@hotmail.com

Key Words:  Drinking water treatment, Hazardous by-products, Natural attenuation, Ismailia Canal, Egypt


Mohamed H. GERIESH, Klaus-Dieter BALKE, Ahmed E. EL-RAYES. Problems of drinking water treatment along Ismailia Canal Province, Egypt[J]. Journal of Zhejiang University Science B, 2008, 9(3): 232-242.

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author="Mohamed H. GERIESH, Klaus-Dieter BALKE, Ahmed E. EL-RAYES",
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%DOI 10.1631/jzus.B0710634

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DOI - 10.1631/jzus.B0710634


Abstract: 
The present drinking water purification system in egypt uses surface water as a raw water supply without a preliminary filtration process. On the other hand, chlorine gas is added as a disinfectant agent in two steps, pre- and post-chlorination. Due to these reasons most of water treatment plants suffer low filtering effectiveness and produce the trihalomethane (THM) species as a chlorination by-product. The ismailia Canal represents the most distal downstream of the main Nile River. Thus its water contains all the proceeded pollutants discharged into the Nile. In addition, the downstream reaches of the canal act as an agricultural drain during the closing period of the High Dam gates in January and February every year. Moreover, the wide industrial zone along the upstream course of the canal enriches the canal water with high concentrations of heavy metals. The obtained results indicate that the canal gains up to 24.06×106 m3 of water from the surrounding shallow aquifer during the closing period of the High Dam gates, while during the rest of the year, the canal acts as an influent stream losing about 99.6×106 m3 of its water budget. The reduction of total organic carbon (TOC) and suspended particulate matters (SPMs) should be one of the central goals of any treatment plan to avoid the disinfectants by-products. The combination of sedimentation basins, gravel pre-filtration and slow sand filtration, and underground passage with microbiological oxidation-reduction and adsorption criteria showed good removal of parasites and bacteria and complete elimination of TOC, SPM and heavy metals. Moreover, it reduces the use of disinfectants chemicals and lowers the treatment costs. However, this purification system under the arid climate prevailing in egypt should be tested and modified prior to application.

Darkslateblue:Affiliate; Royal Blue:Author; Turquoise:Article

Reference

[1] APHA (American Public Health Assoc.), AWWA (American Water Works Assoc.), WPCF (Water Poll. Contr. Fed.), 1995. Standard Methods for the Examination of Water and Waste Water, 13th Ed. Am. Public Health Assoc., Washington, DC, p.874.

[2] Brown, D.M., 1974. Metabolism of chloroform. I. The metabolism of 14C-chloroform by different species. Xenobiotica, 4:151-163.

[3] EHCW (Egyptian, Higher Committee of Water), 1995. Egyptian Standards for Drinking and Domestic Water According to the Act 27/1978 in Regulating of the Public Water Supplies. Egyptian Governmental Press, Egypt.

[4] EPA (U.S. Environmental Protection Agency), 2003. National Interim Primary Drinking Water Regulations List of Drinking Water Contaminants and Their MCLs. Annual Report, 816-F-03-016.

[5] Geriesh, M.H., El-Shamy, I.Z., Farouk, H., 1999. Source of Pollution of the Sweet Suez Canal Water, Suez Canal Province, Egypt. Proc. 4th International Conference of Geochemistry. Alexandria, Egypt, p.353-368.

[6] Geriesh, M.H., Stueben, D., Berner, Z., Ibraheim, M., 2004. Deficiencies of Simple Technologies in Surface Water Purification: A Case Study of Surface Water Treatment for Drinking Purposes at Suez City, Egypt. The 7th International Conference of Geology of Arab World (GAW 7). Cairo, Egypt, p.429-437.

[7] Habtamu, H.T., 2007. Suitability of Local Materials to Purify Akaki Sub-Basin Water. Ph.D Thesis, Institute of Mineralogy and Geochemistry, Karlsruhe University, Germany.

[8] Hütter, U., Remmler, F., 2006. Study on Application of Alternative Filter Materials Using Slow Sand Filtration. The 4th Intern. Conf. Slow Sand and Alternative Biological Filtration Conference. Institute of Water Researches, Haftung, Dortmund, Germany.

[9] Hütter, U., Preuß, G., Zullei-Seibert, N., 2006. Behavior of Cryptosporidium Oocysts and Giardia Cysts during Artificial Groundwater Recharge. The 4th Inter. Slow Sand and Alternative Biological Filtration Conference. Institute of Water Researches, Haftung, Dortmund, Germany.

[10] IARC (International Agency for Research on Cancer), 1991. Monographs on the Evaluation of Carcinogenic Risks to Humans. Chlorinated Drinking Water, Chlorination By-Products; Some Other Halogenated Compounds; Cobalt and Cobalt Compounds. IARC, Lyon, France, Vol. 52, p.544.

[11] Preuß, G., Nehrkom, A., 1996. Succession of Microbial Communities during Bank Filtration and Artificial Groundwater Recharge. Proceedings of the International Symposium of Artificial Recharge of Groundwater. Helsinki, Finland, p.215-221.

[12] Preuß, G., Schulte-Ebbert, U., 2000. Artifical Groundwater Recharge and Bank Filtration. In: Klin, J., Winter, J. (Eds.), Biotechnology. Environmental Processes III, Soild Waste and Waste Gas Treatment, Preparation of Drinking Water. Wiley-VCH, Weinhem, Chichester, New York, p.426-444.

[13] Rook, J., 1974. Formation of haloforms during chlorination of natural waters. J. Water Treat. Exam., 23:234-243.

[14] Skark, C., Remmler, F., Zullei-Seibert, N., 2006. Classification of Riverbank Filtration Sites and Removal Capacity. The 4th Intern. Conf. Slow Sand and Alternative Biological Filtration Conference. Institute of Water Researches, Haftung, Dortmund, Germany.

[15] Wolf, C.R., Mansuy, D., Nasatainczyk, W., Deutschmann, G., Ullrich, V., 1977. The Reduction of Polyhalogenated Methan by Liver Microcsomal Cytochrome P-450. Mol. Pharmacol., 13:698-705.

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