NO344590B1 - Lusefelle - Google Patents

Description

The present invention relates to a device for capturing parasites in anadromous fish, as appears from the introductory part of patent claim 1.

Background

Salmon louse is a crustacean that lives as a marine parasite on salmon fish. Salmon lice feed on the mucus, skin and blood of the fish and consequently take nourishment from the fish and inflict wounds which can cause infections and problems with the salt balance.

Salmon lice are found on fish in farms and on wild salmon and sea trout. When wild fish enter the fjords to spawn in rivers, the lice follow, but escape when they come into contact with fresh water in the rivers.

The farming industry has a strong focus on keeping the level of salmon lice in the farming facilities as low as possible. Consequently, a number of attempts have been made to keep the level of salmon lice in check. One alternative is the addition of chemicals to inhibit the synthesis of chitin in salmon lice and thus stop shell change. Another option is preventive medication, but this has led to increasing resistance in salmon lice and the release of medications and chemicals into the environment. This typically applies to hydrogen peroxide (H2O2). Another approach has been the use of wrasse that eat salmon lice on the farmed fish.

It is known that farms located in fjords with a large supply of fresh water have had few salmon lice and that in periods of reduced supply of fresh water, these have experienced an increased amount of salmon lice for various reasons. A well boat is also used where fish are transferred from cages to the well boat where the fish are exposed for a period to fresh water to remove salmon lice.

It should be mentioned that there are other parasites and microorganisms that are also relevant in the context of the present invention, for example Neoparamoeba perurans. This parasite is the cause of amoebic gill disease (AGD) in marine fish, which can lead to reduced performance and high mortality. This parasite can also be removed by treating the fish with fresh water.

GB 2286756 B describes a trap for catching fish lice. In one embodiment, a light surface is placed inside a sphere or container that forms a decoy surface. A volume of water immediately outside the lure surface forms a capture zone when placed in the sea and illuminated by the light surface. To fix fish lice, it is suggested to impregnate or supply the surface with chemicals that can attack the lice's filaments. Furthermore, it is proposed to use a device to cut or crush the louse and thus remove, kill or trap it. In a second embodiment, it is proposed to illuminate one side of a decoy surface in the form of a square surface to form a capture zone in the sea between the light source and the decoy surface driven by light reflected by the decoy surface. On the other side of the bait surface, a second capture zone is formed where fish lice are lured towards the bait surface by light released through the bait surface. It is proposed to remove fish lice using netting, filtering and separation, pumping or lifting etc. However, it is unclear how fish lice are effectively isolated and removed from the bait zone.

NO 337292 B1 describes a device for collecting lice in water. A submerged body is provided with brushes against which the fish can scrub to remove lice, which are then sucked into the body with the help of a pump and taken to a collection tank.

NO 20140640 A1 describes a device for neutralizing, among other things, salmon lice. The device features a body with a lure light to attract salmon lice. The device is further arranged with a current-conducting surface which can send out electric current pulses to kill or weaken salmon lice. The publication shows an embodiment in which a plurality of devices are arranged around a rearing cage on the outside of the same to form a barrier against salmon lice.

NO 20161570 describes a device for neutralizing parasites. The device features a submersible container equipped with a decoy light to attract parasites into the container whereupon the parasites are killed with chlorine gas.

The presentation "Luse trap" by Howard I. Browman et al from the Institute of Marine Research (Havforskningsinstituttet) discusses lice traps for the aquaculture industry in the form of containers with decoy lights: http://lusedata.no/wp-content/uploads/2013/03/Lusefelle- Reidun-Bjelland-Marine Research Institute.pdf

The article "Will further develop salmon lice traps" by Magnus Petersen discusses combating salmon lice with a trap equipped with a lure light and bait, such as fish slime, to attract salmon lice and catch them: https://www.kyst.no/article/vil - further develop salmon lice traps/

However, the farming industry has still not found permanently effective methods to combat parasites.

Purpose

The purpose of the invention is to provide a device for reducing the amount of parasites and microorganisms in a farming environment in the sea.

The invention

This purpose is achieved with a device according to the characterizing part of patent claim 1. Further advantageous features appear from the independent patent claims.

The present invention is based on an observation that the inventor of the present invention has made from experiments that fish lice and other parasites are attracted to light. Based on this, the invention prescribes a device in the form of a light-tight container with openings that can emit light from a light source inside the container and in this way lure fish lice and other parasites into the container and keep them there until they are removed mechanically or with suction. In a first aspect, the present invention provides a device for trapping parasites in anadromous fish in a breeding cage, in particular salmon lice, using at least one light source, which device is arranged to be anchored in the sea inside the breeding cage at a depth in the lice belt. According to the invention, the device comprises a light-tight container with an upper end and a lower end and side walls, which are hereinafter referred to as container walls. At least one opening is formed in the container wall connected to a funnel-shaped bag with a mouth inside the container with a cross-section smaller than the smallest cross-section of fish caught inside the rearing cage. The light source is arranged inside the container in a position aligned with the mouth, so that light can escape to the surroundings through the opening in the wall of the container and lure parasites and plankton into the interior of the container. An upper and/or lower anchoring line is connected to the container at the respective upper and/or lower attachment point and extending up to an anchoring point at the surface and/or down to an anchoring point at the bottom of the rearing cage.

The container is preferably formed by a frame in the form of interconnected coils, for example of a rigid plastic material or of aluminium, enclosed by a light-opaque polymer material, such as PVC.

In one embodiment, the container is provided with only a lower mooring line, arranged to be attached to the bottom of the rearing cage, in which the container exhibits a buoyancy body with sufficient buoyancy to keep the device afloat in the sea.

In a preferred embodiment, the bottom of the interior of the container has a light-reflecting surface to lure fish lice into the deadly water environment in the lower part of the container. The light-reflecting surface can, for example, be colored white or can consist of a plate of aluminum or stainless steel, or a mirror.

The light source advantageously comprises a two-part LED source with a first light source part arranged to emit RGB light with varying strength and/or color composition, and a second light source part arranged to emit light with a specific colour. The light source preferably has an output in the range from 1 to 10,000 W and arranged to emit light with varying wavelengths in the range from 265 nm to 1100 nm.

The lower part of the container is provided with means for the automatic supply of supersalted water, in particular water with a salinity of 32-80 per thousand, regulated by salinity sensors in the container. In this embodiment, the lower part of the container can be provided with flow barriers to prevent water with high salinity in the lower part of the container from mixing with water of lower salinity in the upper part of the container. The flow barriers may be vertically oriented radially projecting mutually spaced baffles, with a lower end of the baffles spaced above the bottom of the container to allow light to diffuse. A vertically projecting opening is advantageously arranged between the guide plates to allow light from the light source down to the bottom of the container.

A source of laser light or low-frequency UV light can be arranged to illuminate and kill fish lice. The interior of the container may be provided with one or more suction hoses leading up to the surface, arranged to suck up water samples for analysis. The interior of the container can further have means for supplying organic material, in particular blood plasma tablets, arranged to attract fish lice.

The container can further be provided with a suction for removing fish lice from the container to the surface, arranged at the lower part of the container near the bottom thereof.

For further details refer to the detailed description below.

Figures

The invention is subsequently described in more detail with reference to figures, where

Figure 1 shows a side view of the device according to the invention,

Figure 2 shows a cross-section through the device according to the invention,

Figure 3 shows a flow barrier for use in the device according to the invention in perspective, and

Figure 4 shows an arrangement with several lice traps in a breeding cage.

Example description

The device according to the invention, also referred to as a lice trap, comprises a container 10 with at least one translucent opening 14 in the container wall connected to a funnel-shaped bag 16 with an open end, which serves as a transport route for lice from the sea into the container and as an opening for the emission of light as described in more detail below. The container 10 can be designed in various ways, for example with the shape of a box or with a barrel shape. In a preferred embodiment, the container 10 is a frame (not shown) enclosed by a light-proof polymer material, such as PVC. The frame can advantageously be a slatted structure (not shown) of rigid plastic material or aluminum enclosed by a plastic sheet. In use, the container 10 is submerged in the louse belt inside a breeding cage, that is at depths from the surface down to approximately 10 metres.

The openings 14 in the container wall 13 are formed of bag-shaped, preferably light-opaque material with a largest (outer) opening in the container wall and a smallest (inner) opening 17 at the end of the bag 16 inside the cage 10. A bag 16 of a light-opaque material will make fish lice is focused towards the inner opening. The diameter of the inner opening 17 is, however, smaller than the cross-section of the smallest fish in the cage, but sufficiently large for lice to migrate into the interior of the container and for sufficient light to escape into the rearing cage.

The container 10 further has an upper end 11 connected to an upper anchoring point 18 or the like via a cable or equivalent leading up to an anchoring point at the surface, and a lower end 12 optionally connected to a lower anchoring line 30 arranged to be attached to the bottom of a breeding farm. Two anchoring points 18, 19 will stabilize the container better than with only one upper or lower anchoring points 18 and 19, respectively. However, the device can also be anchored in only one lower anchoring point 19 to the bottom of the breeding cage. In this embodiment, the container is provided with a buoyancy body 31. The axis between the upper end 11 and the lower end 12 of the container 10 defines a mainly vertical longitudinal axis. At least one light source 15 is arranged inside the container 10 at the same height along the vertical longitudinal axis as the inner bag openings 17, so that light can shine out through the openings 17 and 14 and out into the surrounding sea to entice fish lice and other parasites to swim into through the opening 14 in the container wall 13, the bag 14 and the inner opening 17, and is caught inside the container 10. The light source 15 is suspended in and supplied with power by a wire 28. The bag 16 with its openings 14 and 17 also serves to prevent backlight from the outside motivating the louse to return from the trap. If desired, the brightness can be increased by making the base 20 in the interior of the container 10 light reflective, for example with a white surface, a plate of aluminum or stainless steel, or a mirror.

In a preferred embodiment, the light source 15 is a two-part LED source with an output in the range from 1 to 10,000 W with a wavelength in the range from 265 nm to 1100 nm. A first light source emits RGB light, which can be adjusted in strength and color composition. A second light source emits light of a specific color to attract fish lice and other parasites. During the summer months, it has been shown that green light in particular attracts fish lice. In another variant, the light source can be connected to an oscillator and/or rotor (not shown) to set the light source 15 in motion, in order to increase the lure effect in this way.

In a first embodiment, the lice are removed simply by raising the container 10 to the surface where it is emptied of lice. In another embodiment, fish lice and other parasites are removed with a suction (not shown).

In a preferred embodiment, the lower part of the container 10 is supplied with supersalted water with a high content of minerals, such as iron. The supersalted water can, for example, be reject water from a process with reverse osmosis for the production of fresh water. The salt content is advantageously 18 per thousand to 80 per thousand. Fish lice turn out to be attracted to such an aquatic environment and will be able to enhance the lure effect. However, such salinity can also be sufficient to kill the louse. In order to prevent supersalted water from mixing with seawater in the upper part of the container 10 and to reduce the desired high salinity in the lower part of the container 10, flow barriers 21 are advantageously provided in the lower part of the container 10, such as a set of vertically aligned radially projecting mutually spaced baffles 22 along the periphery of the container 10, with a lower end of the baffles 22 arranged at a distance above the bottom 20 of the container 10 to allow the dispersion of light. The flow barrier is shown separately in Figure 4. The seawater's salinity can be checked by extracting water samples through a hose from the interior of the container 10 to the surface, or with the help of sensors (not shown) which can send measurement data to the surface. The container can also be fitted with a camera that makes it possible to record lice activity inside the container.

In a preferred embodiment, a vertically projecting opening 23 is provided between the guide plates 22 to let light from the light source down to the bottom of the container 10, particularly with a light-reflecting bottom 20, in order to lure the lice down to the zone of lethal salinity. Alternatively, the container 10 can be supplied with laser light (not shown) or low-frequency UV light (not shown) to kill the lice. In order to further increase the lure effect, organic material can be deployed down in the bottom area of the container 10, such as blood plasma tablets.

The container 10 can also be provided with a liquid line 24 with valve 25 and a diffuser 26 at the lower end of the liquid line 24 inside the container 10 for removing (dead) fish lice and conveying the material up to a reception at the surface. In the event that the lower part of the container 10 is to maintain a lethal salinity, the amount of extracted water must be balanced with the supply of super-salted water to the lower part of the container 10. This can be done with the same liquid line 24. The super-salted water that is supplied to the container 10 can with it is advantageous to have added attractant materials for fish lice, such as hydrogen sulphide and minerals.

Figure 4 shows an arrangement with a number of lice traps 10 moored in respective lower anchoring wires 30 attached to a bottom line 32. Reference number 29 refers to a power supply line, optionally provided with respective lines for removing trapped fish lice.

Claims (9)

Patent claims 1. Device for trapping parasites in anadromous fish in a breeding cage, in particular salmon lice, using at least one light source (15), which device is arranged to be anchored in the sea inside the breeding cage at a depth in the lice belt, in which the device comprises a light seal container (10) with an upper end (11) and a lower end (12) and a container wall (13), in which at least one opening (14) connected to a funnel-shaped bag (16) with a mouth is formed in the container wall (13) (17) inside the container (10) with a cross-section smaller than the smallest cross-section of fish caught inside the rearing cage, in which said at least one light source (15) is arranged inside the container (10) in a position aligned with the mouth (17), so that light can escape to the surroundings through opening (14) and lure parasites and plankton into the interior of the container (10), and in which an upper and/or lower anchor line (29, 30) is connected to the container (10) in the respective upper and/or or lower attachment point (18, 19) and extending up to an anchor point point at the surface and/or down to an anchoring point at the bottom of the rearing cage, characterized in that the lower part of the container (10) is arranged with means for the automatic supply of supersalted water, in particular water with a salinity of 32-80 per thousand, regulated by salinity sensors in the container. 2. Device according to claim 1, in which the means for automatic supply of supersalted water have a liquid line (24) with valve (25) and a diffuser (26) at the lower end of the liquid line (24) inside the container (10). 3. Device according to claim 1 or 2, in which the lower part of the container (10) is provided with flow barriers (21) to prevent water with high salinity in the lower part of the container (10) from mixing with water of lower salinity in the upper part of the container (10). 4. Device according to claim 3, wherein the flow barriers (21) are vertically aligned radially projecting mutually spaced baffles (22), with a lower end of the baffles (22) arranged at a distance above the bottom (20) of the container (10) to allow scattering of light. 5. Device according to claim 4, in which a vertically projecting opening (23) is arranged between the guide plates (22) to allow light from the light source (15) down to the bottom (20) of the container (10). 6. Device according to one of the preceding claims, in which the container (10) has a source for laser light or low-frequency UV light, arranged to illuminate and kill fish lice. 7. Device according to one of the preceding claims, in which the interior of the container (10) is provided with one or more suction hoses leading up to the surface, arranged to suck up water samples for analysis. 8. Device according to one of the preceding claims, in which the interior of the container (10) has means for supplying organic material, in particular blood plasma tablets, arranged to attract fish lice. 9. Device according to one of the preceding claims, in which a suction for removing fish lice from the container (10) to the surface is arranged at the lower part of the container (10) near the bottom (20) thereof.