What is UV Transmittance (UVT)?

UVT is short for UV Transmittance, which indicates the UV light transmission factor in a water sample. More specifically, UV Transmittance is a measurement of the amount of ultraviolet light at 254 nanometers (nm) that is able to pass through 10 mm of water. The UVT is expressed as a percentage – %UVT. The amount of light that gets through the water sample is an indicator of the general water quality.

Even though it is not always visible to the human eye, all water is capable of having particles that absorb or deflects UV light. The UVT will vary based on the number of compounds in the water which absorbs the UV light, such as humic acids, iron, colloidal solids, and other material.

To simplify, a water sample with a UVT of 90% is significantly clearer than one with a UVT of 10%, as more light is able to pass through the sample.

Why is UV Transmittance important?

UV Transmittance is essential to know as it helps us identify how clean the water is, resulting in great conditions to ensure proper water disinfection. By knowing the UVT of the water to be disinfected, it becomes possible to properly size the UV system for optimal disinfection.

Microorganism inactivation can be achieved at UV wavelengths ranging from 100 to 400 nm, although a wavelength of 254 nm is proven to be the most effective. Due to this, the UV lamps of almost any UV treatment solution operate at this wavelength, which then becomes the point of reference. This will result in accurate sizing of the UV treatment solution, as UV lamps operate at the same wavelength as used throughout the initial UVT identification phase.

An important note here is that for disinfection purposes, the UVT can never be 0%, as the lamps will then not be able to penetrate through the water. The UV rays of the UV disinfection system must be capable of “reaching” all pathogens in the water in order to be effective. In general, the lower the UVT, the more UV light is needed, resulting in a higher operating cost due to the required power consumption.

The image above is a particle tracing simulation, showing UV dose exposure of the particles throughout the UV reactor.

How to calculate UV Transmission (UVT)

In the ULTRAAQUA laboratory, we follow this specific procedure, to size UV systems:

Firstly, a water sample is sent to our laboratory, which is being carefully handled by our specialists.

Secondly, The amount of light able to pass through the water is calculated through a UVT probe system, where the UVT is being determined (0-100%). Distilled 100% UVT water is used in comparison as the benchmark.

The water is then tested for UVT values in intervals, by retaining the water sample in a UV system. The values derived over time are now plotted into a graph, showing how the UVT changes in relation to the retention time in the UV system.

The graph generated from this process makes it possible to choose the exact required UV system setup, depending on how big a UVT improvement the client wishes.

So what UV intensity is needed to kill bacteria and viruses? The UV intensity requirements vary a lot, based on factors such as industry and application. These are the average values:

  • Coliform bacteria, legionella, fecal bacteria, streptococci, nematodes (eelworms) and yeasts, etc. – 3 – 40 (mJ/cm²)
  • Pathogenic fungi, such as fusarium, pithium, phytophtora, etc. – 30 – 120 (mJ/cm²)
  • Viruses such as cucumber virus, olpidium, cholera, etc. – 60 – 250 (mJ/cm²)

Sizing the right UV system for the measured UVT

As mentioned, it is essential to know the UV transmittance when sizing a UV system for any given case. By determining the UVT in advance, it becomes possible to identify the right UV system with the appropriate number of lamps, power consumption, additional features etc., which is required to ensure the desired purity of the water. In this way, the optimal operating cost can be achieved, while living up to the defined disinfection requirements.

As different pathogens require different UV doses to be inactivated, it must be clear which pathogens are to be inactivated in any given case. Additionally, it is important to note that the relationship between the dose and log removal is not linear. It takes a much higher dose to achieve log-4 removal compared to log-2 removal.

There are a lot of factors to be assessed in order to select the best suited UV systems, such as location, application, flow rate, UVT and targeted bacteria. ULTRAAQUA is always available to assist in assessing all relevant factors including the UV transmission and UV dose, to ensure that the optimal UV system is selected. By sending a water sample from your site to our headquarters in Denmark, our scientists are able to assess the bacteria to be targeted in our state-of-the-art laboratory, as well as determining the desired log reduction and/or pre-filtration.

Specific Power Consumption of different UV transmissions of the ULTRAAQUA UV System – MR3-220SSV.

ULTRAAQUA offers multiple UV system series for low-UVT environments, providing excellent disinfection under cost-efficient conditions. In environments with very low UVT, normal UV systems are not able to eliminate pathogenic microorganisms due to the low transmission of UV light. UV systems such as the LUVT has CFD optimized lamp positioning, which offers maximum hydraulic efficiency with minimum head loss, eliminating any chance of ‘dark areas’ with untreated microorganisms.