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Clean Technologies and Environmental Policy
Erschienen in: Clean Technologies and Environmental Policy 5/2014

01.06.2014 | Original Paper

Modeling exposure period for solar disinfection (SODIS) under varying turbidity and cloud cover conditions

verfasst von: Husnain Haider, Waris Ali, Sajjad Haydar, Solomon Tesfamariam, Rehan Sadiq

Erschienen in: Clean Technologies and Environmental Policy | Ausgabe 5/2014

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Abstract

Solar disinfection (SODIS) is widely practiced all around the world. The process requires variable exposure periods depending upon a number of process parameters (e.g., water turbidity, atmospheric temperature, and cloud cover conditions). This paper describes the development of a mathematical model to estimate required exposure period to achieve Fecal coliforms (FCs) removal for changing process parameters. Daily and hourly solar radiation were estimated and found to be suitable for SODIS application with intensity of 500 W/m2 over a period of 3–5 h/day. Randomized SODIS experiments over a period of 3 years were conducted to consider seasonal and weather variations. Six samples each for five levels of turbidity (0, 5, 10, 20, and 30 NTU) were exposed to sunlight under variable cloud cover conditions on different days during the 3-year sampling period. Samples were collected and analyzed for remaining FCs at different intervals in each sampling day. Analysis of variance revealed that turbidity and percent of cloud cover are the most significant process parameters. It was found that FCs die-off in SODIS bottles followed the first-order kinetics. Different data sets were used for the development and calibration of the model. The calibrated model was further verified against the literature. Simple characteristics curves have also been established for practical application at household level to estimate exposure periods. The study revealed a significant difference between the required exposure periods for different turbidity and cloud cover conditions.
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Literatur
Acra A, Jurdi M, Mu’allem H, Karanhagopian Y, Raffoul Z (1989) Water disinfection by solar radiation: assessment and application. Ottawa, Ontario
Ahmed K, Shah S (2007) Physical and microbiological assessment of drinking water of Nomal Valley, Northern Areas, Pakistan. Pak J Zool 39(6):367–373
APHA (1998) Standard methods for the examination of water and wastewater, 20th edn. American Public Health Association, Washington, DC20005-2605
Berney M (2006) Inactivation of enteric bacteria by solar disinfection. PhD thesis, Swiss Fedearl Institute of Technology, Zürich
Boyle M, Sichel C, Fernandez-Ibanez P, Arias-Quiroz GB, Iriarte-Puna M, Mercado A, Ubomba-Jaswa E, McGuigan KG (2008) Appl Environ Microbiol 74(10):2997–3001CrossRef
Brock T (1981) Calculating solar radiations for ecological studies. Ecol Model 14:1–19CrossRef
Caslake LF, Connolly DJ, Menon V, Duncanson CM, Rojas R, Tavakoli J (2004) Disinfection of contaminated water by using solar irradiation. Appl Environ Microbiol 70:1145–1150CrossRef
Cooper PI (1969) The absorption of solar radiation in solar stills. Sol Energy 12(3):333–346CrossRef
Duffie JA, Beckman WA (1991) Solar engineering of thermal processes. Wiley-Interscience, New York
Eawag/Sandec (2002) Solar water disinfection: a guide for the application of SODIS. SANDEC report no. 06/02, Switzerland
Eawag/Sandec (2006) SODIS solar water disinfection. SANDEC (Water & Sanitation in Developing Countries) at EAWAG (Swiss Federal Institute for Environmental Science and Technology), Dubendorf
FCDPH (2009) E. coli or Fecal coliform bacteria contamination in your water supply. Notice distribute to private well owners. Fresno County Department of Public Health, Fresno
Fisher MB, Keenan CR, Nelson KL, Voelker BM (2008) Speeding up solar disinfection (SODIS): effect of hydrogen peroxide, temperature, pH and copper plus ascorbate on the photo inactivation of E. coli. J Water Health 6:35–51CrossRef
Frere EA (1980) Graphs given in A.A. Flocas paper estimation and prediction of global solar radiation over the Greece. Sol Energy 24:63–70CrossRef
Hindiyeh M, Ali A (2010) Investigating the efficiency of solar energy system for drinking water disinfection. Desalination 259:208–215CrossRef
Joyce TM, McGuigan KG, Elmore-Meegan M, Conroy RM (1996) Inactivation of fecal bacteria in drinking water by solar radiation. Appl Environ Microbiol 62(2):399–402
Kehoe SC, Joyce TM, Ibrahim P, Gillespie JB, Shahar RA, McGuigan KG (2001) Effect of agitation, turbidity, aluminium foil reflectors, and volume on inactivation efficiency of batch-process solar disinfectors. Water Res 35(4):1061–1065CrossRef
Kohler M (2003) Migration of organic components from polyethylene terephthalate (PET) bottles into water. Report 429670. Swiss Federal Laboratories for Materials Testing and Research (EMPA), Duebendorf
Liu S (2002) Fecal coliform decay and regrowth kinetics in an anaerobic dairy wastewater environment. MSc thesis, Louisiana State University and Agricultural and Mechanical College, Baton Rouge
Mahvi AH (2007) Feasibility of solar energy in disinfection of drinking water in Iran. American-Eurasian J Agric Environ Sci 2(4):407–410
McGuigan KG, Joyce TM, Conroy RM (1999) Solar disinfection: use of sunlight to decontaminate drinking water in developing countries. J Med Microbiol 48:785–787CrossRef
Milankovitch M (1930) Mathematische Klimalehre und Astronomische Theorie der Klimaschwankungen, Handbuch der Klimalogie Band 1, Teil A. Borntrager, Berlin
Oates PM, Shanahan P, Polz MF (2003) Solar disinfection (SODIS): simulation of solar radiation for global assessment and application for point-of-use water treatment in Haiti. Water Res 37:47–54CrossRef
Reddy SJ (1971) An empirical method for the estimation of net radiation intensity. Sol Energy 13:291–292CrossRef
Reed RH (1997) Solar inactivation of faecal bacteria in water: the critical role of oxygen. Lett Appl Microbiol 24(4):276–280CrossRef
Rodrigues CP, Ziolli RL, Guimarães JR (2007) Inactivation of Escherichia coli in water by TiO2-assisted disinfection using solar light. J Braz Chem Soc 18(1):126–134CrossRef
Rose A, Roy S, Abrahan V, Holmgren G, George K, Balraj V, Abrahan S, Muliyil J, Joseph A, Kang G (2006) Solar disinfection of water for diarrhoeal prevention in southern India. Arch Dis Child 91:139–141CrossRef
Schmid P, Kohler M, Meierhofer R, Luzi S, Wegelin M (2008) Does the reuse of PET bottles during solar water disinfection pose a health risk due to the migration of plasticisers and other chemicals into the water? Water Res 42(20):5054–5060CrossRef
Severin BF, Suidan MT, Engelbrecht RS (1983) Kinetic modeling of UV disinfection of water. Water Res 17(11):1669–1678CrossRef
Severin BF, Suidan MT, Engelbrecht RS (1984) Effect of temperature on ultraviolet light disinfection. Environ Sci Technol 17(12):717–721CrossRef
Smith RJ, Kehoe SC, McGuigan KG, Barer MR (2000) Effects of simulated solar disinfection of water on infectivity of Salmonella typhimrium. Lett Appl Microbiol 41:297–302
Ubomba-Jaswa E, Fernánez-Ibáñez P, McGuigan KG (2010) A preliminary Ames fluctuation assay assessment of the genotoxicity of drinking water that has been solar disinfected in polyethylene terephthalate (PET) bottles. J Water Health 08(4):712–719CrossRef
Wegelin M, Canoniaca S, Alder AC, Marazuela D, Suter MJ-F, Bucheli TD, Haefliger OP, Zenobi R, McGuigan G, Kelly MT, Ibrahim P, Larroque M (2001) Does sunlight change the material and content of polyethylene terephthalate (PET) bottles? J Water Supply Res Technol Aqua 50(3):125–133
WHO (2002) Managing water in the home: accelerated health gains from improved water supply. WHO, Geneva
WHO (2012) Progress on drinking water and sanitation—2012 update. WHO and UNICEF Joint Monitoring Programme for Water Supply and Sanitation, USA
Metadaten
Titel
Modeling exposure period for solar disinfection (SODIS) under varying turbidity and cloud cover conditions
verfasst von
Husnain Haider
Waris Ali
Sajjad Haydar
Solomon Tesfamariam
Rehan Sadiq
Publikationsdatum
01.06.2014
Verlag
Springer Berlin Heidelberg
Erschienen in
Clean Technologies and Environmental Policy / Ausgabe 5/2014
Print ISSN: 1618-954X
Elektronische ISSN: 1618-9558
DOI
https://doi.org/10.1007/s10098-013-0677-4

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