Hey guys some info on uv lighting
I read this and thought it may be of some use.
The first you have to remember is that not all organisms are killed by the same amount of UV; it all depends on the dose rate of UV passing through the water.
To start with, here are the things we need to know to effectively size a UV sterilizer -
1. The organism (or range of organisms) you want to kill or prevent from getting a foothold in your tank.
2. The size of the body of water/tank you have
3. The flow you have in that tank
For example if you had a 4000 liter pond, and a flow rate in that pond of 4000LPH (or more it doesn’t really matter), you would only need to size the UV sterilizer to and Algae and Bacterial flow rate of 30,000 Microwatts and only pass the volume of the pond through the UV over a 4-6 hour period, meaning that you would need a flow rate of between 700 - 1000LPH on a by-pass to the main flow of water.
This would result in around an 18 watt UV sterilizer sized at 30,000 microwatts.
As Algae generally reproduces every 4-6 hours, passing the entire volume of the pond through the UV faster then this will eventually stop the life cycle of the algae and prevent it from growing. Obviously passing more water through a larger UV will get the job done quicker.
The second application is sizing the UV to the aquarium size, generally this size should be calculated by taking the recommended flow of the UV sterilizer at algae and bacterial flow rates and dividing the flow by three (three times per hour turnover rate). Then if you have a higher turnover rate but do not want to size the UV to the flow rate you can just stick to the recommend flow rate and Aquarium size.
Then as a different application say you had a very large tank, Retail tank system, quarantine system etc and you wanted a higher rate of sterilization. You would first find the flow rate of your system, say this was 6000 liters per hour; there are two ways to know size your UV sterilizer in this application.
The first is Bacterial and Algae treatment (at 30,000 microwatts) and will generally kill most types of bacteria and algae. You would pass all of the water through the UV and therefore at a bacterial and algal treatment rate for a flow rate of 6000 LPH the system would require a 50 watt UV sterilizer. By passing all the water through the UV sterilizer from the pump you make sure that all the water going back to tank has been treated by the UV.
Now in most cases I would recommend sizing a UV to the protozoal treatment rate (90,000 microwatts - 3 times bigger) for these sorts of applications.
So if it were the same application as above you would be looking to size a UV between a 120 watt and 150 watt UV.
Now you must keep in mind that not all UV sterilizers are created equal. For instance the Emperor Aquatics UV sterilizers are based on a standard 30,000 microwatt bulb and the flow rates are based on 80% transmissibility through the water (green water/algae and particulate laden water) and a 60% bulb life which is end of bulb life, so when you size a UV you know that you will get that level of sterilization out of the UV even when the bulb is close to the end of its life after 9000 hours continuous operation.
However some bulbs, in fact a vast majority of them are only sized on a 15,000 microwatt bulb, making comparing UV models harder. For instance an 8 watt UV with a 15,000 microwatt bulb is only half as effective an 8 watt UV with a 30,000 microwatt bulb because the dose rate of UV through the water is only half that in 15,000 MW UV.
So in conclusion the effectiveness of a UV depends on:
- The wattage
- The dose rate of UV light in Micro-watts per second per square centimeter (uWS/cm2)
- The flow rate or contact time inside the UV chamber in relation to the two above factors
Several other factors effect the value and effectiveness of the UV such as the way the bulbs are sized (end of bulb life or new bulb), the transmissibility through the water (sized on particulate laden - 80% transmissibility or clear water) and the overall design of the UV itself for instance emperor UV units have the bulb positioned between the inlet and outlet and not beyond these points, so that the water passing through the unit is exposed to the entire length of the UV bulb.
For disease control if you can afford it, go with at least a UV sized to 30,000 MW that will handle the entire flow rate from your return pump. for even better disease control upgrade to a UV that will handle all the flow from your return pump that has an output dose rate of 90,000 MW.
Below is a table that details some different organisms and the relative dose rate of UV needed to kill them/inactivate them.
Microorganism UV Dosage (µW sec/cm2)
Bacteria:
Aeromonas salmonicida 3,620
Bacillus subtilus (vegatative) 11,000
Bacillus subtilus spores 22,000
Bacillus megaterium (vegatative) 2,500
Bacillus megaterium spores 52,000
Bacillus anthracis 8,700
Bacillus paratyphi 6,100
Campylobacter jejuni 4,600
Clostridium tetani 22,000
Corynebacterium diptheriae 6,500
Eberthella typhosa 4,100
Enyerococcus faecalis 10,000
Escherichia coli 6,600
Lactococcus lactis 8,800
Legionella bozemanii 3,500
Legionella dumoffi 5,500
Legionella pneumophila (Legionnaires' disease) 3,800
Legionella gormanii 4,900
Legionella longbeachae 2,900
Legionella micdadai 3,100
Leptospira interrogans 6,000
Mycobacterium tuberculosis 10,000
Neisseria catarrhalis 8,500
Proteus vulgaris 6,600
Pseudomonas aeruginosa 3,900
Rhodospirillum rubrum 6,200
Salmonella 10,000
Salmonella enteritidis 7,600
Salmonella paratyphi (enteric fever) 6,100
Salmonella typhimurium 15,200
Salmonella typhosa (typhoid fever) 7,000
Serratia marcescens 6,200
Shigelia dysenteriae 4,200
Shigelia flexneri 3,400
Shigelia sonnei 7,000
Staphylococcus opidermidis 5,800
Staphylococcus aureus 7,000
Staphylococcus hemolyticus 5,500
Staphylococcus lactis 8,800
Staphylococcus viridans 3,800
Vibrio cholerae 6,500
Algae:
Chlorella vulgaris 22,000
Virus:
Channel Catfish Virus (CCV) 20,000
Chum Salmon Virus (CSV) 100,000
Infectious Hematopoietic Necrosis Virus (CHAB) 20,000
Infectious Hematopoietic Necrosis Virus (RTTO) 30,000
Infectious Pancreatic Necrosis Virus (Buhl) 150,000
Oncorhynchus masou virus 20,000
Bacterilophage 6,600
Hepatitis 6,600
Influenza 6,600
Poliovirus 21,000
Rotavirus 24,000
Tobacco mosaic virus 440,000
Fungi:
Saprolegnia hyphae 10,000
Saprolegnia zoospores 39,600
Mold Spores:
Aspergillus flavus 99,000
Aspergillus glaucus 88,000
Aspergillus niger 330,000
Mucor sp. 35,200
Penicillium sp. 88,000
Penicillium expensum 22,000
Penicillium roqueforti 26,400
Rhizopus sp. 220,000
Protozoa:
Phytomonas tumefaciens 8,500
Paramecium 220,000
Icthyophthirius sp. (tomite) 336,000
Cryptocaryon irritans (white spot disease) 300,000
Cryptosporidium parvum 7,900
Sarcine lutea 26,400
Ceratomyxa shasta 30,000
Costia necatrix 318,000
Myxosoma cerebralis 35,000
Trichodina sp. 35,000
Trichodina nigra 159,000
Pb 8-)