Lumnia

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The science behind Lumnia fly killers

There are many claims being made about the efficacy of electric fly killers and it can be difficult for customers to determine which is the best fly trap for any given situation.

The quicker flies are eliminated from an environment, the lower the risk of fly-borne diseases like Shigellosis or Salmonellosis.

Our scientific research and analysis concludes that the use of LED technology in fly killers has a significant impact on the efficacy of a single unit.

LED technology offers:

  • reduced power consumption
  • a maintained catch rate

It also removes the need to replace phosphor lamps each year.

Rentokil fly killer research

Investigating how to trap and kill flies most efficiently has been the basis of numerous studies by our team of science experts at Rentokil’s Global Technical Centre.

The two key areas of research are:

  1. Understanding the physics of how light impacts the biological attraction of flies to a trap
  2. Fly killer testing based on a standard Half-Life measure

This research has helped us develop our new range of Lumnia fly killers using LED technology — proven to be the most efficient at attracting flies to a fly trap.

LED lights for flies

LEDs produce intense beams of UV-A light that penetrate further into the surrounding environment and appears more attractive to certain insects, like house flies, than the light traditional phosphor lamps produce.

The house fly is attracted to UV-A as their eyes are sensitive to light at that wavelength.

Wavelengths of light which fall outside the visible light range are more attractive to house flies than those that fall within it.

Why are flies attracted to light?

A phenomenon known as phototaxis describes how insects respond to light.

Certain insects, such as cockroaches or earthworms, have negative phototaxis, meaning they are repelled by an exposure to light. Moths, flies and many other flying insects have positive phototaxis so are naturally attracted to it.

While there is no single scientific explanation for flies’ attraction to light, there are several theories for why this happens.

Light used for safety

For some insects, a bright light source may be seen as a safety signal. Light sources are generally positioned on higher ground, so instinctively heading towards light helps to keep insects away from hazards near the ground.

Light used for navigation

Another popular theory is that insects use light as a navigational aid.

An insect flying north, for example, is able to judge its direction by keeping a natural source of light, such as the sun or moon, on its right.

This method works well as long as the source of light remains both constant and at a distance.

If an insect encounters another light source, such as a round incandescent porch light, it becomes confused. This explains why a moth may continuously encircle a light -as it instinctively wants to keep the light on a certain side of its body to help it navigate its route.

Artificial vs. natural light

There is some debate in the scientific community over why a positively phototactic insect will continue to hover around an artificial light source even when natural light becomes available.

Some believe that the insect is not attracted to the light itself, but the darkness surrounding it.

Others suggest the insect’s eyes, which often contain multiple lenses, struggle to adjust from light to dark. This leaves the insect night-blind and vulnerable to predators, so the insect may find it safer to remain in the light rather than fly away.

Fly killer testing

Since 2008, Rentokil's Global Technical Centre has dedicated two purpose-built rooms to testing fly killers. Units are compared using a standard performance test called the half-life measure.

All of our fly killers have been subjected to the same rigorous testing ever since, including the new Lumnia fly killer range.

Half-life measure

To prove the efficacy of fly killers we devised a standard half-life measure test to scientifically measure performance, allowing customers to directly compare products.

Graph 1: Half-life in minutes for a range of products

Graph 1 indicates half-life catch rates, with the Lumnia unit (red) catching flies in the fastest time.

Graph 2: Half-life value explanation

Rather than reading the percentage catch directly (blue), Graph 2 indicates how the half-life value (red) is a measure of flies caught in the fastest time.

The Rentokil test is based on releasing 100 house flies (Musca domestica) in a standard test room with the product/ unit installed, and counting the number of flies captured at regular intervals over a seven hour period.

  • This process is repeated at least six times to ensure a fair reflection of performance over time
  • The half-life measure represents the time taken to eliminate 50% of the flies released in the test chamber
  • The lower the half-life measure, the more effective the unit
Contact us today for effective fly control with Lumnia