basic principles of uv disinfectionbasic principles of uv disinfection dr michael templeton...
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![Page 1: Basic Principles of UV DisinfectionBasic Principles of UV Disinfection Dr Michael Templeton Department of Civil and Environmental Engineering, Imperial College London IUVA Vice-President](https://reader030.vdocument.in/reader030/viewer/2022041013/5ec1200c92b0e9266477b257/html5/thumbnails/1.jpg)
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Basic Principles of UV Disinfection
Dr Michael Templeton Department of Civil and Environmental Engineering, Imperial College London IUVA Vice-President for Europe, Middle East and Africa region [email protected]
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Gamma Xrays UV Visible Infrared Microwave Wavelength (nm) 1 10 340 760 106
vacuum UV UVC UVB UVA Wavelength (nm) 200 280 315
germicidal sunburn tan
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• In order to inactivate microorganisms, UV energy must be absorbed somehow
• DNA & RNA happens to absorb light in the UVC range emitted by UV lamps
• DNA & RNA are the master instructions for the cell
• UV damages these nucleic acids and prevents cell replication
Microbial Inactivation by UV Light
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Dose = Intensity x Time
Fluence = Fluence rate x Time
• J/m2, mJ/cm2, mW·sec/cm2 are commonly used units
• 10 J/m2 = 1 mW·sec/cm2 = 1 mJ/cm2
• So, 400 J/m2 is the same as 40 mJ/cm2
UV Dose Terminology
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Con
c. o
f Org
anis
ms
UV Dose (mJ/cm2)
106
105
104
103
102
1-log inactivation
2-log inactivation
Log Inactivation
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UV dose (mJ/cm2) required for 4-log inactivation
0
20
40
60
80
100
120
140
Cryptosp
oridium parv
um
Giardia
lamblia
cysts
Vibrio ch
olerae
Shigella d
ysen
teriae
E.coli O
157:H
7
Salmonell
a typ
hi
Shigella s
onnei
Salmonell
a enter
itidis
Legionell
a pneu
mophila
Hepati
tis A vi
rus
Poliovir
us Typ
e 1
Coxsac
kievir
us B5
Rotaviru
s SA11
Adenovir
us 40
Typical UV dose = 40 mJ/cm2
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Protozoa (Crypto, Giardia)
Viruses
(Adenovirus)
Bacteria (E. coli)
Cl2
Harder to inactivate
Easier to inactivate
Viruses (Adenovirus)
Bacteria (E. coli)
Protozoa
(Crypto, Giardia)
UV
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• ‘Light’ and ‘dark’ repair mechanisms exist, but likely not a drinking water concern
• If you apply enough UV, you destroy the ability to repair
• UV doses in the 40+ mJ/cm2 range are thought to be easily high enough to prevent repair
A Note about DNA Repair
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Where Do You Get UV?
Humour Credit: Ron Hofmann
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water
lamp
quartz sleeve air gap
UV Reactors
mercury drop
electrode reactor vessel
connected to ballast sensor
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UV Lamps
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0
20
40
60
80
100
150 200 250 300 350 400
Wavelength (nm)
Rel
ativ
e O
utpu
t (%
)
Low pressure
Medium pressure
Note: The y-axis scale is different for LP and MP lamps on this graph. MP lamps emit MUCH MORE energy than LP lamps.
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0
1
2
3
200 220 240 260 280 300 320
Wavelength (nm)
Abs
orba
nce
(M-1
cm-1
x 1
0-3)
Uracil(in RNA)
Thymine (in DNA)
UV lamp
Abso
rbed
Ene
rgy
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0
20
40
60
80
100
0 2000 4000 6000 8000 10000Time (hours)
Rel
ativ
e O
utpu
tLamps Age and Need Replacing!
Example data
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Other Sources of UV…
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UV Disinfection Benefits
• Cryptosporidium and other pathogens inactivated at relatively low, economical UV doses
• No formation of regulated disinfection by-products at typically applied UV doses for disinfection
• Small space requirements (no contact tank)
• Competitive costs versus alternatives (e.g. ozone, membrane filtration)
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UV Disinfection Limitations
• No taste and odour control (on its own…)
• Does not remove colour (on its own…)
• No iron, manganese oxidation
• No residual disinfecting capabilities
Design and operation of UV reactors must take into account relevant water quality factors and include a dose validation/monitoring strategy
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Water Quality Considerations
Relevant water quality parameters:
• UV Transmittance (UVT)
• Fouling
• Turbidity
Note: pH, temperature have no major direct impact on UV performance
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UV Transmittance (UVT)
• Definition of %UVT: Percent of light emitted (254 nm) that passes through 1 cm of water
Light source 1 cm Detector
100% 95% 95% UVT
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UV Transmittance (UVT)
• Arguably the most important water quality parameter
• Clean source water: > 90% UVT
• Wastewaters: often 30% to 50%
• Can vary seasonally for surface waters; often more stable for groundwaters
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• UVT affected by dissolved and particulate matter; best to apply UV post-filter in a conventional treatment works
• Can always design a powerful enough UV system to handle any UVT
• UV reactor design should consider lowest expected UVT
• Rough rule of thumb: For every 5% decrease in UVT, 50% reduction in UV dose (i.e. Need to build 2X the UV system!)
UV Transmittance (UVT)
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0102030405060708090
100
0 5 10 15 20 25Distance from lamp (cm)
% T
rans
mis
sion
97% UVT per cm
87% UVT per cm
71% UVT per cm
UV Transmittance (UVT)
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From Jim Malley, IUVA website
Fouling
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Fouling
• Caused by minerals that accumulate on quartz sleeve (i.e. hard waters have greater fouling potential)
• Blocks the light
• Will occur in any water
• Hardness < 100 mg/L as CaCO3 = “slow” fouling
• Iron can be a problem (e.g. 0.5 mg/L iron may require chemical cleaning every few days)
• Good news: Can always be controlled using existing lamp cleaning technology (mechanical/chemical)
• (Clean the sensors too…)
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Turbidity • No direct correlation with UV effectiveness in the
drinking water context • Turbidity = scattering. Scattered light can still disinfect • Turbidity = particle enmeshed organisms • To forbid UV for turbid waters implies another
disinfectant works better with turbidity - No good data substantiating this
• Turbid waters may be most in need of multi-barrier disinfection (e.g. some form of filtration before UV)
• Turbidity does affect UVT, which should be accounted for in the design (by measuring UVT)
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UV Basics: ‘Take-Home Messages’
• UV is a very effective disinfectant, but not a panacea • UV handles protozoa and bacteria easily at typically
applied doses; some viruses may require higher doses • UV is not an ‘install and forget’ technology • Water quality matters • Pre- and post-treatment may be necessary