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Prepared by: Purbashree Sarmah(2014CEV2092) Surya Sujathan(2014CEV2094) Madhur Chachondia(2014CEV2586) Ganga water facing water quality deterioration: ◦ River’s importance in Indian culture ◦ dense population residing at its banks ◦ faces several forced and unforced human activities In the sites it was observed that the TVC values were relatively higher in holy places (Sood et al., 2008) In this review paper, effectiveness of Ultraviolet irradiation on coliform bacteria inactivation in the Ganga water is reviewed. Germicidal action mainly due to UV-C light on microorganisms. Consists of UV reactors that efficiently delivers the required dose for microbial inactivation. The microbial response is given by the 1st order kinetic Equation as shown below: Where N0 = Concentration of infectious microorganisms before exposure to UV light N = Concentration of infectious microorganisms after exposure to UV light UV reactors made of open/closed channel vessels containing: ◦ UV lamps ◦ lamp sleeves ◦ UV sensors ◦ temperature sensors Figure1: Example of UV Disinfection Equipment (USEPA, 2006, UV Disinfection Guidance Manual; Severn Trent Services) Parameters Various option from different journals UV Light Generation UV-LEDs, and Propagation high-pressure mercury vapor lamp with side glowing optical fiber, LP, MP, PUV with pulsed xenon source UV Dose-Response UV-LEDs with 10.8, 13.8, 56.9 mJ/cm2, High-pressure mercury vapor lamp with 17.2 mW/cm2, PUV with 3 mJ/cm2 Wavelength 265nm, 280nm, 310 nm, 254 nm, 200nm, 270 nm Turbidity 14 NTU, 0.67 NTU, 10 NTU, 0 NTU, 2.2 NTU, 6.5 NTU, 10.2 NTU Best option(log reduction up to 4) PUV with pulsed xenon source with side glowing optical fibre Challenge Pre treatment PUV with 3 mJ/cm2 Costly Sedimentation, Filtration 254 nm Difficult to maintain Sedimentation, Filtration 0-10 NTU Water should be filtered Sedimentation, until getting the Filtration required standard Costly than other Sedimentation, methods. Maintenance Filtration is difficult Our sample where E coli was present in maximum quantity of about 27CFU if we apply all the best options we may get up to 4 log reduction. To achieve better disinfection following may can be adopted: ◦ Optical fibre can be used to ensure uniform distribution within the UV reactor. ◦ Pre treatment such as coagulation, sedimentation and filtration can be adopted to reduce high turbidity and organic matter present in Ganga water. ◦ UV reactors can be improved to make process more economical so as to improve its popularity compared to chlorine disinfection. Ample quantitative information is needed to study the effect of microorganism-related factors like : ◦ Different environmental species encountered in water ◦ DNA repair mechanism ◦ Differences in spectral sensitivity in various micro-organisms Further research is required in accurate analysis of water flows and UV intensity over UV reactors, using CFD so as to achieve simple, reliable and cheap in situ process control systems. Further research can be done on the optimum use of optical fibre to achieve more economy. ► UV disinfection is best method for disinfection as it requires no chemical consumption thus: o o o ► ► ► ► Saves large scale storage space Transportation and managing cost Safety hazards related issues High removal of 99.99% can be attained if used under optimum operational conditions. Does not give toxic byproducts such as trihalomethanes. But it is not very cost effective compared to chlorine disinfection . It cannot give any residual because of which it is more popular only for POU systems. AnchalSood, Kamal Deep Singh, PiyushPandey, Shivesh Sharma, 2008, “Assessment of bacterial indicators and physicochemical parameters to investigate pollution status of Gangetic river system of Uttarakhand (India)”, Ecological Indicators 8 ( 2008 ) 709 – 717 Andreza B. Silva, Nelson M. Lima Filho, Maria A.P.F. Palha, Sandra M. Sarmento, 2012, “Kinetics of water disinfection using UV-C radiation”, Fuel 110 (2013) 114–123 BrahmiMounaouer, HassenAbdennaceur; “Ultraviolet Radiation for Microorganism Inactivation in Wastewater”, 2011, Journal of Environmental Protection, 2012, 3, 194-202. Dunn, J., Ott, W., Clark, W., 1995. Pulsed-light treatment of food and packaging. Food Technol.49, 95–98. 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Comparative effectiveness of UV wavelengths for the inactivation of Cryptosporidium parvum oocysts in water.Water Sci. Technol.43, 171–174. REFERENCES contd.. Meulemans, C.C.E. 1986. The basic principles of UV-sterilization of water. In: Ozone +Ultraviolet Water Treatment, Aquatec Amsterdam, Paris: International OzoneAssociation. Miller, R., Jeffrey, W., Mitchell, D., Elasri, M., 1999. Bacterial responses to ultraviolet light.Am. Soc.Microbi ol.65, 535– 541. Oguma, K., Katayama, H., Ohgaki, S., 2002. Photoreactivation of Escherichia coli after low- or medium-pressure UV disinfection determined by an endonuclease sensitive site assay. Appl. Environ. Microbiol. 68, 6029–6035. Parker, J.A., and J.L. Darby. 1995. Particle-associated coliform in secondary effluents: Shielding from ultraviolet light disinfection. Water Environment Research 67:1065–1075. 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Woolsey, 2005, “Pulsed ultra-violet inactivation spectrum of Escherichia coli”, The Robertson Trust Laboratory for Electronic Sterilisation Technologies, University of Strathclyde, Royal College, 204 George Street, Glasgow G1 1XW, UK USEPA, 2006, “Ultraviolet Disinfection Guidance Manual for the final long term 2 enhanced surface water treatment rule”, Office of Water (4601), EPA 815-R-06-007 W.A.M. Hijnen, E.F. Beerendonk, G.J. Medema, 2005, “Inactivation credit of UV radiation for viruses, bacteria and protozoan (oo)cysts in water: A review”, Kiwa Water Research Ltd., P.O. Box 1072, 3430 BB Nieuwegein, The Netherlands.