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Desalination and Water Treatment Volume 52, 2014 - Issue 31-33
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Articles

Modelling drinking water chlorination at the Breakpoint: II. Calculation of the chlorine and chloramine concentrations along municipal pipe

Khadidja DrissPharmaceutical Processes Engineering Faculty, LIPE Laboratory, Constantine 3 University, Constantine, Algeria.Correspondence[email protected]
,
Mohammed BouhelassaPharmaceutical Processes Engineering Faculty, LIPE Laboratory, Constantine 3 University, Constantine, Algeria.
&
Saadoun BoudabousPharmaceutical Processes Engineering Faculty, LIPE Laboratory, Constantine 3 University, Constantine, Algeria.
Pages 5769-5780 | Received 14 Feb 2012, Accepted 23 May 2013, Published online: 30 Jul 2013

References

  • E.J. Lee, K.J. Schwab, Deficiencies in drinking water distribution systems in developing countries. J. Water Health 03 (2005) 109–127.
  • Drinking water chlorination, World chlorine position paper, 2008. www.Worldchlorine.org
  • M.W. LeChevallier, W. Schulz, R.G. Lee, Bacterial nutrient in drinking water. Appl. Environ. Microbiol. 57 (1991) 857–862.
  • M.W. LeChevallier, T.M. Babcock, R.G. Lee, Examination and characterization of distribution system biofilms. Appl. Environ. Microbiol. 53 (1987) 2714–2724.
  • J.G. Hattersley, The negative health effects of chlorine. Townsend Letter for Doctors & Patients (2003) 60–63.
  • G.-S. Wang, Y.-C. Deng, T.-F. Lin, Cancer risk assessment from trihalomethanes in drinking water. Sci. Total Environ. 387 (2007) 86–95.
  • K. Gopal, S.S. Tripathy, J.L. Bersillon, S.P. Dubey, Chlorination byproducts, their toxicodynamics and removal from drinking water. J. Hazard. Mater. 140 (2007) 1–6.
  • C.N. Haas, S.B. Karra, J.L. Bersillon, S.P. Dubey, Kinetics of microbial inactivation by chlorine -1. Review of results in demand-systems. Water Res. 18 (1984) 1443–1449.
  • C. Lu, P. Biswas, R.M. Clark, Modeling of breakpoint reaction in drinking water distribution pipes. Environ. Int. 19 (1993) 543–560.
  • N.B. Hallam, J.R. West, C.F. Forster, J.C. Powell, I. Spencer, The decay of chlorine associated with the pipe wall in water distribution systems. Water Res. 36 (2002) 3479–3488.
  • L.A. Rossman, The effect of advanced treatment on chlorine decay in metallic pipes. Water Res. 40 (2006) 2493–2502.
  • K. Pedersen, Biofilm development on stainless steel and PVC surfaces in drinking water. Water Res. 24 (1990) 239–243.
  • J. Thogersen, E. Dahi, Chlorine decay and bacterial inactivation kinetics in drinking water in the tropics. World J. Microbiol. Biotechnol. 12 (1996) 549–556.
  • W. Lu, L. Kiéné, Y. Lévi, Chlorine demand of biofilms in water distribution systems. Water Res. 33 (1999) 827–835.
  • P. Niquette, P. Servais, R. Savoir, Impacts of pipe materials on densities of fixed bacterial biomass in a drinking water distribution system. Water Res. 34 (2000) 1952–1956.
  • M. Batté, B.M.R. Appenzeller, D. Grandjean, S. Fass, V. Gauthier, F. Jorand, L. Mathieu, M. Boualam, S. Saby, J.C. Block, Biofilms in drinking water distribution systems. Environ. Sci. Biotechnol. 2 (2003) 147–168.
  • Z. Tsvetanova, Chemical as Intentional and Accidental Global Environmental Threats, Springer, Sofia, 2006, pp. 463–468.
  • P.M.R. Jonkergouw, S.-T. Khu, D.A. Savic, D. Zhong, X.Q. Hou, H.-B. Zhao, A variable rate coefficient chlorine decay model. Environ. Sci. Technol. 43 (2009) 408–414.
  • G. Mutoti, J.D. Dietz, J. Arevalo, J.S. Taylor, Combined chlorine dissipation: Pipe material, water quality, and hydraulic effects. J. Am. Water Works Assn. 99 (2007) 96–106.
  • F. Hua, J.R. West, R.A. Barker, C.F. Forster, Modelling of chlorine decay in municipal water supplies. Water Res. 33 (1999) 2735–2746.
  • C. Lu, P. Biswas, R.M. Clark, Simultaneous transport of substrates, disinfectants and microorganisms in water pipes. Water Res. 29 (1995) 881–894.
  • P. Biswas, C. Lu, R.M. Clark, A model for chlorine concentration decay in pipes. Water Res. 27 (1993) 1715–1724.
  • O.N. Ozdemir, A. Metin ger, Realistic numerical simulation of chlorine decay in pipes, Water Res. 32 (1998) 3307–3312.
  • O.N. Ozdemir, A. Metin Ger, Unsteady 2-D chlorine transport in water supply pipes, Water Res. 33 (1999) 3637–3645.
  • A. Muslim, Q. Li, M.O. Tadé, Simulation of free chlorine decay and adaptive chlorine dosing by discrete time-space model for drinking water distribution system. Chem. Prod. Process Model. 2 (2007) 1–19.
  • G.R. Munavalli, M.S. Mohan Kumar, Dynamic simulation of multicomponent reaction transport in water distribution systems, Water Res. 38 (2004) 1971–1988.
  • L. Cozzolino, D. Pianese, F. Pirozzi, Control of DBPs in water distribution systems through optimal chlorine dosage and disinfection station allocation. Desalination 176 (2005) 113–125.
  • A. Jadas-Hécart, A. El Morer, M. Stitou, P. Bouillot, B. Legube, The chlorine demand of a treated water, Water Res. 26 (1992) 1073–1084.
  • F. Dossier-Berne, B. Panais, N. Merlet, A. Jadas-Hécart, B. Cauchi, B. Legube, Automation of long term chlorine demand measurement of treated waters, Water Res. 31 (1997) 375–384.
  • L.A. Rossman, R.M. Clark, W.M. Grayman, Modelling chlorine residual in drinking water distribution system. J. Environ. Eng. 120 (1994) 803–820.
  • M.K. Stenstrom, H.G Tran, A theoretical and experimental investigation of the dynamic of Breakpoint chlorination in dispersed flow reactors, a report to the University of California Water Resources Center, Davis, California, 1984.
  • J.C. Morris, R.A. Issac, A critical review of kinetics and thermodynamic constants for the aqueous chlorine, Water Chlorination: Environmental impact and Health Effects, Ann Arbo, Ann arbor science, 5 (1985).
  • Z. Qiang, C.D. Adams, Determination of monochloramine formation rate constants with stopped-flow spectrophotometry. Environ. Sci. Technol. 38 (2004) 1435–1444.
  • F. Shang, J.G. Uber, L.A. Rossman, EPANAT Multi-Species Extension User’s manual EPA/600/S-07/021. US Environmental Protection Agency, Cincinnati, OH, 2011.
  • F. Shang, J.G. Uber, L.A. Rossman, Modeling reaction and transport of multiple species in water distribution systems. Environ. Sci. Technol. 42 (2008) 808–814.
  • N.J. Themelis, Transport and chemical rate Phenomena, Gordon and Breach Science Publishers, Switzerland, 1995.
  • Y.J. Yang, J.A. Goodrich, R.M. Clark, S.Y. Li, Modeling and testing of reactive contaminant transport in drinking water pipes: Chlorine response and implications for online contaminant detection. Water Res. 42 (2008) 1397–1412.
  • W.B. Krantz, D.T. Wasan, A correlation for velocity and eddy diffusivity for the flow of power-law fluids close to a pipe wall. Ind. Eng. Chem. Fundam. 10 (1971) 424–427.
  • J.P. Kirkpatrick, L.V. McIntire, W.G. Characklis, Mass and heat transport in a circular tube with biofouling. Water Res. 14 (1980) 117–127.
  • R.H. Notter, C.A. Sleicher, The eddy diffusivity in the turbulent boundary layer near a wall. Chem. Eng. Sci. 26 (1971) 161–171.
  • C.S. Lin, R.W. Moulton, G.L. Putnam, Mass transfer between solid wall and fluid streams. Mechanism and eddy distribution relationships in turbulent flow. Ind. Eng. Chem. 45 (1953) 636–640.
  • J.C. Powell, N.B. Hallam, J.R. West, C.F. Forster, J. Simms, Factors which control bulk chlorine decay rates. Water Res. 34 (2000) 117–126.
  • E.R. Blatchley III, R.W. Johnson, J.E. Alleman, W.F. Mccoy, Effective Henry’s law constants for free chlorine and free bromine, Water Res. 26 (1992) 99–106.
  • Metcalf and Eddy, Inc., Wastewater Engineering, Treatment and Reuse, 4th ed., McGraw-Hill, New York, 2003, pp. 1219–1286.
  • F.W. Pontius (Ed.), Water Quality and Treatment—A Handbook Community Water Supplies, 4th ed., McGraw, New York, 1990, pp. 877–931.
  • R.E. Connick, Y.-T. Chia, The hydrolysis of chlorine and its variation with temperature. J. Chem. Soc. 81 (1959) 1280–1284.
  • C.J. Morris, The acid ionization constant of HOCl from 5 to 35. J. Phys. Chem. 70 (1966) 3798–3805.
  • E.A. Betterton, Henry’s law constants of soluble and moderately soluble organic gases: Effects on aqueous phase chemistry, in: J.O. Nriagu (Ed.), Gaseous Pollutants: Characterization and Cycling, John Wiley & Sons, New York, NY, 1992, pp. 1–50.
  • R.G. Bates, G.D. Pinching, Dissociation constant of aqueous ammonia at 0 to 50 from E.M.F. studies of the ammonia salt of a weak acid. J. Am. Chem. Soc. 72 (1950) 1393–1396.
  • V. Snoeyink, D. Jenkins, Water Chemistry, John Wiley & Sons, New York, NY, 1980, pp. 316–430.
  • D.R. Rowe, I.M. Abdel-Magid, Handbook of Wastewater Reclamation and Reuse, Lewis Publishers, Boca Raton, FL, 1995.
  • R.H.J. Sarbatly, D. Krishnaiah, Free chlorine residual content within the drinking water distribution system, Int. J. Phys. Sci. 2 (2007) 196–201.
  • M. Deborde, U. Von Gunten, Reactions of chlorine with inorganic and organic compounds during water treatment—kinetics and mechanisms: A critical review, Water Res. 42 (2008) 13–51.
  • I. Wiel, C.J. Morris, Kinetic studies on the chloramines.I. The rates of formation of monochloramine, N-Chlormethylamine and N-Chlordimethylamine. J. Am. Chem. Soc. 71 (1949) 1664–1671.
  • V.C. Hand, D.W. Margerum, Kinetics and mechanisms of the decomposition of dichloramine in aqueous solution. Inorg. Chem. 22 (1983) 1449–1456.
  • A.E. Griffin, N.S. Chamberlin, Relation of ammonia-nitrogen to Break-Point chlorination. Am. J. Public Health 31 (1941) 803–808.
  • C.J. Morris, Chlorination and disinfection—State of the art. J. Am. Water Works Assn. 63 (1971) 769–774.
  • Priority Substances List Assessment report, Inorganic chloramines, Canadian Environmental Protection Act, 1999.
  • US EPA, Guidance Manual Alternative Disinfectants and oxidants, EPA 815-R-99-014, April 1999.
  • A. Nikolaou, Haloforms and Related Compounds in Drinking Water, 5G the Handbook of Environmental of Chemistry. Springer-Verlag, Berlin, 2003, pp. 1–19.
  • M.M. Donnerrmair, E.R. Blatchley III, Disinfection efficacy of organic chloramines. Water Res. 37 (2003) 1557–1570.
  • R.A. Isaac, J.C. Morris, Transfer of active chlorine from chloramine to nitrogenous organic compounds.1. Kinetics. Environ. Sci. Technol. 17 (1983) 738–742.
  • J. Yoon, J.N. Jensen, Distribution of aqueous chlorine with nitrogenous compounds: Chlorine transfer from organic chloramines to ammonia. Environ. Sci. Technol. 27 (1993) 403–409.
  • M.P. Snyder, D.W. Margerum, Kinetics of chlorine transfer from chloramine to amines, amino acids, and peptides, Inorg. Chem. 21 (1982) 2545–2550.
  • P.J. Vikesland, K. Ozekin, R.L. Valentine, Effect of natural organic matter on monochloramine decomposition: Pathway elucidation through the use of mass and redox balances. Environ. Sci. Technol. 32 (1998) 1409–1416.
  • US EPA, Combined Sewer Overflow Technology Fact Sheet—Chlorine Disinfection, Office of water Washington,D.C. EPA 832-F-99-034, September 1999.
  • M.R. Schock, S.C. Schock, Effect of container type on pH and alkalinity stability. Water Res. 16 (1982) 1455–1464.
  • W.G. Characklis, Attached microbial growths—I. Attachment and growth, Water Res. 7 (1973) 1113–1127.
  • N.B. Hallam, J.R. West, C.F. Forster, J. Simms, The potential for biofilm growth in water distribution systems. Water Res. 35 (2001) 4063–4071.
  • S.L. Percival, J.S. Knapp, R. Edyvean, D.S. Wales, Biofilm development on stainless steel in mains water. Water Res. 32 (1998) 243–253.
  • B. Warton, A. Heitz, C. Joll, R. Kagi, A new method for calculation of the chlorine demand of natural and treated waters. Water Res. 40 (2006) 2877–2884.
  • P.V. Scarpino, G. Berg, S.L. Chang, D. Dahling, M. Lucas, A comparative study of the inactivation of viruses in water by chlorine. Water Res. 6 (1972) 959–965.
  • J.V. Maston, J.F. Andrews, M.T. Garrett, Reduction in chlorine requirements by control of nitrification in an oxygen activated sludge process. Water Res. 16 (1982) 1083–1091.
  • C.T. Jafvert, R.L. Valentine, Dichloramine decomposition in the presence of excess ammonia. Water Res. 21 (1987) 967–973.
  • B.S. Yiin, D.W. Margerum, Non-metal redox kinetics: Reactions of trichloramine with ammonia and with dichloramine. Inorg. Chem. 29 (1990) 2135–2141.

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