UltraViolet Systems Overview

1. UV Technology Overview Disinfection History

2. Disinfection Techniques

3. The UV Process

4. UV Dose

5. Various Types of Microorganisms

6. Drinking Water Regulations

7. Advantages of UV Disinfection

8. Water Quality Effects

9. Installation TipsDisinfection History After the turn of the century, chlorine started to be used as a disinfectant in water supplies to combat the 3 most common water borne bacterial diseasesTyphoid FeverAsiatic choleraBacillary dysentery UV disinfection was first applied in early 1900’s for disinfection of industrial process waters

10. By mid 1980’s UV became the BAT for wastewater

11. By the 1990’s the USEPA begin to consider UV disinfection as a primary disinfectant for municipal drinking water

12. Late 1990’s UV was considered BAT for both Cryptosporidium & Giardia2003 UV disinfection was written into both USEPA drinking water regulations & Health Canada guidelines

13. Disinfection Techniques There are two types of disinfection, physical & chemical

14. Chemical disinfection is when a chemical agent must be added to the water for disinfection and the water undergoes chemical changes (i.e.. Chlorine, iodine, ozone)

15. Physical disinfection is a physical means of inactivating or removing bacteria (i.e. boiling, filtration, UV light)

16. UV disinfection does not change the water – it smells the same, it tastes the same, the pH has not changed – it’s only target is the bacteria

17. It is important to remember the definition of disinfection: To cleanse so as to destroy or prevent the growth of disease carrying microorganisms

18. Disinfection TechniquesSANITIZATIONdefined as a 2-log reduction or 50 - 99% reductionDISINFECTIONdefined as a 4-log reduction or 99.99% reductionSTERILIZATIONdefined as a 6-log reduction or 99.9999% reductionReduction Levels:3 log = 1 in 1,0004 log = 1 in 10,0006 log = 1 in 1,000,000

19. UV Process The UV treatment process is an extremely rapid physical process, that causes a molecular rearrangement of the genetic material, known as the DNA, of the microorganism

20. DNA is the main constituent of all chromosomes of all organisms, known as deoxyribonucleic acid, and is self replicating

21. This blocks the microorganism’s ability to replicate itself, and consequently its ability to breed colonies

22. Due to individual cell makeup, different microorganisms require different levels of UV energy for their destruction

23. This energy level is known as dosageUV Process

24. UV ProcessElectromagnetic Spectrum:

25. UV ProcessWavelengths of Light:UVC light is not visible light; therefore you cannot see UVC light with the naked eye (254 nm)

26. Exposing skin &/or eyes to UVC light can cause damage

27. UV lamps will glow a nice blue-violet color for much longer than the recommended life of the lamp but THIS DOES NOT MEAN that lamp is still giving off UVC germicidal light

28. UV Dose UV Dose is the product of UV light intensity and time Dose is sometimes referred to as fluenceDOSE = INTENSITY x TIME = millijoules/(sec)(cm2) x time = mJ/cm2NOTE: 10 J/m2 = 1,000 microWsec/cm2 = 1 mJ/cm2

29. UV DoseWhat Dose is Required?30 mJ/cm2 Industry Standard40 mJ/cm2 NSF 55 Class A Requirement

30. UV DoseMicroorganism Destruction Chart:PATHOGENIC BACTERIA (to achieve 4-log inactivation)Cholera 6.5 mJ/cm2(6,500 microWs/cm2 )Dysentery 4.2 mJ/cm2(4,200 microWs/cm2 ) E. coli 6.6 mJ/cm2(6,600 microWs/cm2 )Legionella 3.8 mJ/cm2(3,800 microWs/cm2 )Salmonella 10 mJ/cm2(10,000 microWs/cm2)PATHOGENIC VIRUSES (to achieve 4-log inactivation)Poliovirus 7 mJ/cm2(7,000 microWs/cm2 )Hepatitis A 8 mJ/cm2(8,000 microWs/cm2 )PROTOZOAN CYSTS (to achieve 4-log inactivation)Giardia lamblia 10 mJ/cm2(10,000 microWs/cm2 )Cryptosporidium <10 mJ/cm2(<10,000 microWs/cm2 )

31. MicroorganismsCryptosporidiumcyanobacteriabacillusPolioShigellaE. coli

32. MicroorganismsBacteria Structure:

33. Both Cryptosporidium & Giardia are very sensitive to UV

34. UV has been deemed the BAT for inactivation of these cysts

35. When UV was first proposed for Crypto & Giardia research showed that UV was ineffective against both cysts

36. However original excystation tests merely determined the response to external stimuli & not the ability to cause an infection in a susceptible host

37. New tests used live animal infectivity tests to prove new findingsMicroorganismsProtozoan Cysts:Cryptosporidium parvumDose required for 4-loginactivation: < 10 mJ/cm2Giardia lambliaDose required for 4-loginactivation: 6-10 mJ/cm2

38. MicroorganismsEffects of UV on Microorganisms:Once microorganisms are exposed to UV light they are rendered ‘inactive’ and can no longer replicate – meaning they can no longer produce coloniesIn the above picture on the left an agar plate is smeared with an untreated water sample, incubated & analyzed for colony growthThe agar plate on the right has been smeared with a water sample that has been exposed to UV treatment – no colony growth occurred following incubation

39. MicroorganismsMicrobiological Analyses:2. Plating of sampleusing membranefilter technique1. Sample Collection4. Total coliformgrowth following incubation period3. Membrane filteris removed fromapparatus & placedon agar plate for incubation

40. Drinking Water Regulations UV disinfection is accepted by the Canada Health drinking water guidelines as well as the USEPA drinking water regulations (as of 2003) however the equipment must have proof of performance (i.e. NSF 55)

41. Private homes do not fall under either of the regulations/guidelines therefore do not require validated systemsSpecific markets that do require validated UV equipment are ones that serve water to the public SchoolsHospitalsApartment complexesChurches

42. Advantages of UV Disinfection No need to handle dangerous toxic or corrosive chemicals

43. No chemicals being added to the water

44. Cost effective

45. Simple maintenance

46. No moving parts to wear out or break

47. Immediate disinfection

48. Proven & trustedWater Quality Effects A common misconception is the following ‘I have bacteria so I’ll install a UV system and my problem is resolved’ – not true

49. Water quality is the most important aspect when considering a UV disinfection system

50. UV can only be effective if it is absorbed by it’s target, the microorganism

51. The main concerns are:HardnessIronTanninsTurbidityWater Temperature

52. Water Quality EffectsUV Application Guidelines:Iron: < 0.3 ppm (0.3 mg/L)

53. Manganese: < 0.05 ppm (0.05 mg/L)

54. Turbidity: < 1 NTU

55. Hardness: < 7 gpg (120 mg/L)

56. Tannins: < 0.1 ppm (0.1 mg/L)

57. UV Transmittance: > 75% Water Quality EffectsFate of UV Light in Water:

58. Installation Tips Never undersize a UV system

59. Install UV as the last piece of treatment equipment

60. Test water first (UVT as well as other recommended parameters)

61. Shock system & check for for ‘dead spots’

62. Install system vertically with connector at top of reactor or horizontally with ports pointing up

63. Consider installing a sampling port (especially if at a site where regular sampling needs to occur)Installation Upon installation of the POE system the water lines must be disinfected using chlorine

64. The first step is to ensure that the UV system is ON

65. Add chlorine bleach to one of the filter sumps (after removing the filter cartridge) and turn the water ON

66. Ensure that chlorine can be detected (by smell) at each faucet in order to ensure that all lines are being exposed to the chlorine

67. Leave sit for approximately 30 minutes & then flush all chlorine out of the water lines until it can no longer be detectedInstallationPoint of Entry Example:

68. Installation

69. WaterFilters.NET offers a huge selection of UV systems. Our technical support is ready to help you select the right system to meet your unique needs.See our entire selection of UV systems here.

UltraViolet Systems Overview

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