NO20160386A1 - Aquaculture cages for fish, as well as a method for debugging in a fish farm - Google Patents

Abstract

Fish farming farm (10), comprising a float collar (12) floating in the water surface, a groove (14) attached to the float collar (12) to accommodate the farmed fish, wherein the groove (14) is also attached to a bottom ring (24) down in the water, as well as a skirt (16) surrounding the groove (14) and extending into the water to an area above the bottom ring (24), comprising several streamers (30) positioned upright in the groove (14), where 30) comprises an elongated vertical suction pipe (36) with a lower inlet (32) for suction of water and an upper, substantially horizontal outlet (34) for distributing the water in the upper water mass of the groove (14) and for setting the upper water masses in rotation. Also disclosed is a method of debugging in a farmed cage as indicated.

Description

Field of the invention

The present invention relates to a breeding cage for breeding fish, comprising a floating collar which floats on the surface of the water, a groove attached to the floating collar to accommodate the farmed fish, where the groove is also attached to a bottom ring down in the water, as well as a skirt which surrounds the groove and which extends descend into the water to an area above the bottom ring.

A procedure for de-linting a breeding pen as indicated is also discussed.

The background of the invention.

Today, there is a growing problem with resistant lice and escape of fish as a result of de-lice removal, as well as disease that spreads in the upper water layer.

Today, several methods are known for combating, among other things, lice in the farming industry. The industry is still dependent on medicinal methods where chemicals are used which create resistance and which kill the fish during complicated de-lice operations, and because the fish during de-lice operations must be displaced in order for an entire tarpaulin to be drawn around the entire cage. This is a very cumbersome and expensive operation that requires large resources and several workboats

In many cases, the lice simply fall off and do not die, so that they can reproduce or float with currents on the surface of the neighboring plant and infect it with lice. In this way, the problem will escalate, and as a result a higher and higher number of lice in the environment and on the fish in the cages. Today, demands have been written for more and more facilities about the forced slaughter of the fish due to too high lice allowances.

Discussion of prior art.

It is also known that the cages are equipped with a skirt that is pulled outside the billet and out past the float collar. This reduces the lice infestation somewhat, but it does not solve the problem anywhere near as the lice skirt can only be pulled down in an area where there are still lice and because too little oxygen-rich water layer where the lice skirt is enclosed. With this method, only current from the aquatic environment outside the cage is distributed in the cage, which in turn provides too little oxygen available for the fish.

As the lice skirt cannot be extended far enough down into the water layer, this can still result in large lice infestations as well as a lack of oxygen for the fish, which in turn affects growth and fish welfare. It also leads to a reduced flow rate inside the cage, which in turn reduces the quality of the fish meat and creates a fish with little resistance, which easily picks up infection and dies.

During de-lice removal today, the bottom ring, which keeps the nits out, is pulled up almost to the surface at a shallow depth. A tarpaulin is then pulled under and around the entire remaining volume in the cage. Next, toxins are sprayed out to ensure that the lice are removed from the fish. This creates stress for the fish and poor fish welfare, and is an expensive operation. Firstly, there are expensive drugs and secondly, there is a great risk of tearing a hole in the groove during the operation itself and thirdly, the operation requires several workboats and people to carry it out. There is now also a threat that the lice will become resistant to these drugs.

There are also several other methods that are used, e.g. thermal desalination, where the fish is pumped out and through a piping system with hot water. This is also stressful for the fish and it can again lead to illness and mortality due to this. With this de-lice method, it is necessary to take the fish out of the cage and then pump it back in. This is labor-intensive and also requires expensive equipment such as rafts and cranes. In addition, a lot of labor is needed to implement this.

There are also known methods for combating salmon lice such as lasers, where one lowers one or more laser units into the cage and which shoots lice that pass the laser unit. This has not been a success yet as it requires a large amount of data to shoot many lice as well as a large density of fish in front of the laser, and this becomes unnatural as the fish want to move as homogeneously as possible in the cage. The result is that one must have several units per cages and that even then cannot keep up with an escalation of lice in the cages. It is also expensive and demanding to have service and follow-up of this method.

There is also a known solution using a compressed air-driven or electrically driven pump that brings water from deep to the surface in the cage, considering that infectious lice larvae are carried out of the cage to keep the water masses in the upper layer approximately lice-free. This solution does not create a homogenous steady flow in a larger area of the cage and is not effective as a current source and agitator for oxygen and thus will not improve the welfare of the animals to a significant extent. The aim here is to operate the pump function with compressed air or as a mammoth pump. This is very risky as the fish can be exposed to nitrogen oversaturation and die. How electrical operation will be solved is not known, but in any case this creates no rotational current in the area of the cage where most of the fish stay.

So finally, wrasse is used as a non-medicinal method against salmon lice. This is also an expensive and risky method, primarily because many wrasse die and the wrasse can cause the spread of infection in the cage. In addition, only one in three wrasse eat lice and they bite the seine instead if it is not completely clean. In addition, the wrasse requires hiding and its own lining, which is a cost driver. Finally, it can also be mentioned that most of the wrasse are not sufficient to keep the lice levels down, and that by lice treatment of the cage most are killed and new wrasse must be ordered. When using wrasse, there will be a latent possible outbreak of a virus that can suddenly break out and lead to large losses of fish.

In the industry today, there is no requirement for the collection of waste. This will happen sooner or later and it is then important to be able to document that you have a standard that collects the sludge from the cages. The sludge can also be a resource such as biogas, artificial fertilizer and as sustainable fuel for, for example, the cement industry. This also gives the opportunity to control the lining in the cage, as surplus pellets are collected that the fish do not eat together with the sludge.

Purpose of the present invention.

With the present invention, the aim is to solve the challenges the farming industry struggles with regarding lice, escape and fish welfare in the cages and at the same time, according to the invention, the aim is to be able to collect waste from the cages.

With the solution according to the invention, you also secure against escape by having a double groove.

Summary of the invention

The above-mentioned purpose is achieved with a breeding cage for breeding fish, comprising a floating collar that floats on the surface of the water, a groove attached to the floating collar to accommodate the farmed fish, where the groove is also attached to a bottom ring down in the water, as well as a skirt that surrounds the groove and which extends descend into the water to an area above the bottom ring, characterized by the fact that several power setters are placed upright in the groove, where the respective power setter comprises an elongated, vertical suction pipe with a lower inlet for the intake of water and an upper, mainly horizontal outlet for distributing the water in the upper water masses of the note and to set the upper water masses in rotation.

The outlet is preferably located in an area below the water surface in the upper bodies of water.

Furthermore, the inlet to the current setters is preferably located in an area adjacent to the bottom ring, and/or located in an area below the skirt's lower skirt edge.

The current setters can be equipped with a floating collar, which floating collars of respective current setters are connected to each other via stiffeners to produce a rigid structure to absorb the forces arising from the outlet.

The flotation collars of the power setters, and/or possibly the stiffeners, can be anchored to the flotation collar of the rearing pen.

In a particular embodiment, three current setters can be mounted in the rearing cage, so that their location forms an equilateral triangle.

The outlet can be rotatably mounted to the suction pipe, both horizontally and vertically.

The float collar of the respective power setter may be hinged to the braces, and a motor may be mounted to the float collar to tilt the power setters to a substantially horizontal position. This will be an advantageous position during deworming.

Under the groove, or in the area under the bottom ring, there can be a collection funnel that runs down into the water and meets in a central mud funnel, from which a mud line runs up to the float collar.

In an alternative design, the outlet of the current setter can be equipped with one or more nozzle tubes.

On the outside of the net that holds the fish to be reared, an extra net or canvas can be arranged that is impervious to lice, as the extra net is suspended in the skirt, or in the floating collar of the rearing cage.

The power setters can also include equipment for adding oxygen by injecting oxygen into the suction tube.

The above-mentioned purpose is also achieved with a method for removing lice in a rearing cage for raising fish, where the rearing cage comprises a floating collar that floats on the surface of the water, a groove attached to the floating collar to accommodate the fish to be reared, where the groove is also attached to a bottom ring down in the water , a skirt surrounding the seine and extending down into the water to an area above the bottom ring, and a collection funnel suspended below the seine or bottom ring, the method comprising raising the collection funnel and the bottom ring up to a skirt edge of the skirt to seal the cage, followed by de-littering in a commonly known manner.

During raising of the collector hopper, the skirt edge can be lowered until the skirt connects to the collector hopper.

Furthermore, lice removed from the fish can be collected in the collection funnel and sucked up to a destruction unit.

The rearing cage can comprise a number of vertically arranged current setters in the groove, which can be tilted up during raising of the collecting funnel.

Description of figures

Preferred embodiments of the invention will be described in more detail below with reference to the accompanying figures, in which:

Figure 1 shows a rearing pen according to the invention, seen in side view.

Figure 2 shows the corresponding rearing pen according to the invention during de-lice removal.

Figure 3 shows the corresponding rearing pen according to the invention.

Figure 4 shows the corresponding rearing pen according to the invention, where part of the groove and the skirt have been removed. Figure 5 shows the corresponding rearing pen according to the invention, seen in top view. Figure 6 shows the corresponding rearing cage according to the invention, seen in top view. Figure 7 shows a current setter which is included in the breeding pen according to the invention. Figure 8 shows the corresponding current setter which is included in the rearing pen according to the invention. Figure 9 shows the power setter which is included in the breeding cage according to the invention, seen in top view. Figure 10 shows the power set included in the breeding cage according to the invention, seen in a raised position in the cage.

Description of preferred embodiments of the invention.

In principle, a cage for fish farming is described consisting of a float collar, a groove with a bottom ring, a tight skirt which preferably goes outside the float collar and the groove, a collection of current setters attached to the float collar, as well as a collection funnel which is enclosed by the groove and the bottom ring and which ends in a funnel which opens into an outlet at the bottom of the collection funnel and which is connected via a hose to a sludge pump.

The collection funnel can be connected to the float collar via the skirt and can be moved up and down in the cage partly by means of a buoyancy ring at the top of the collection funnel and via rope integrated in the skirt.

The flow setters can consist of a vertical suction pipe stem, a buoyancy body and a distributor which aims to lift water from deeper layers and distribute this in the upper level of the cage by setting the upper water masses in rotation.

In the design example in the figures, a rearing net 10 is shown with a floating collar 12 equipped with a notch 14 and a lice skirt 16 which encloses the notch 14 and which extends downwards in the water column towards an area where there are few or no lice. The skirt 16 can be made either in flexible, solid material or stiffened flexible material.

The skirt 16 can protrude significantly further down than a normal skirt used today, and thus have a greater effect in that there are fewer lice inside the rearing cage 10, but which at the same time can cause a reduction in water flow and oxygen in the groove 14 and which again can lead to lower growth and poorer fish welfare. According to the invention, this is solved by water masses being retrieved from a lower layer and preferably below the skirt edge 16a, but inside the groove 14. For this, a number of current setters 30 placed in the groove 14 can be used, the further functions of which will be described later, and which are equipped with a vertical suction pipe 36 which preferably extends down past the skirt edge 16a. The suction pipe 36 is equipped in the lower part with an inlet 32 and in the upper part with an outlet 34, where the outlet is preferably located below the water surface 26 in the cage. Between the outlet 34 and the inlet 32 is a propeller 38, water jet or similar placed to suck up the water and send it out through the outlet 34.

The current setters 30 have one or more outlets 34 preferably in an upper layer inside the rearing cage 10 and whose outlet 34 can be controlled to set a rotating current in the groove 14 throughout the water layer and which causes an annular chamber-like current that rotates and establishes an oxygen-rich environment with a lot current which the fish benefit from and which means that there are few lice inside the groove 14, while the deep skirt 16 will reduce the risk of escape by having a groove and a solid wall outside as a double safeguard. The power setting is illustrated with the arrows in figures 5 and 6.

The current is preferably established by several current setters 30 which are interconnected with each other to absorb reaction forces that occur and where the collection of current setters 30 can form a connection or assembly of all the current setters via pipes or stiffeners 42 which lie in or above the surface and which can create buoyancy for the current setters 30 and thus be able to relieve the float collar 12, in that the assembly of the current setters or the entire flow system is attached directly to this and that the forces caused by the flow do not significantly affect the float collar.

As mentioned, the power setters 30 are assembled as vertical suction pipes 36 including a power propeller 38 or similar in the pipe with a suction nozzle/inlet 32 at the bottom equipped, for example, with a grate and groove, and the upper outlet 34 equipped with a pipe bend that can be rotated in the horizontal plane in the water layer in the upper layer of the cage 14 well above the lower edge of the lice trap 16 and which can possibly be controlled from the float collar 12 to the desired flow direction. However, the outlet 34 can also be rotated or rotated about the horizontal plane, i.e. also tilted up and down.

Figures 7 and 8 show in more detail an example of a current setter 30. In addition to the previously mentioned construction features, the current setter 30 can include an inclined wall 46 in the pipe bend, which is preferably held in place by a stand or frame 48 under a lid 50 in the upper part of the suction pipe 36. The suction means, for example the propeller 38, can be suspended in said stand 48, where the stand 48, wall 46 and propeller 38 can easily be raised or lowered in the suction pipe 36, as shown in Figure 8.

Furthermore, the power sets 30 can be connected further down towards the suction nozzle 32 with a rope, wire chain or pipe (not shown). In this way, you can achieve and get a collection of current sources in the cage that push the lice-free and oxygen-rich water that is collected from a lower water layer into the cage in the desired direction and which can in turn be controlled and which creates an injector effect in addition to the main flow itself out of the pipe outlets 34. It is appropriate to have a groove or similar on the outlet 34 so that fish cannot swim into the pipe.

Under the notch 14 itself, there is a collecting funnel 18 which is conical and which, when removing lice in the cage, can easily be lifted up via the vertical folds of the louse skirt 16 and join the lower edge 16a of the skirt so that you have a closed unit, as shown in fig. 2. In this way, you do not need to carry out an expensive and extensive de-lice removal which is normally required and according to the invention you save effort, while at the same time eliminating the risk of escape and stress on the fish. The collecting funnel 18 can be connected to the float collar 12 via the skirt 16, or directly via ropes or cables, and can be moved up and down in the cage partly by means of a buoyancy ring at the top of the collecting funnel and via ropes integrated in the skirt.

The collection hopper 18 can meet in a centrally mounted mud hopper 20, so that collected mud, scum, residues, etc., can be collected and transported to the surface via a mud line 22.

In the design example, three current setters 30 are used. It is natural that fewer or more can be used than what is shown. However, Figure 5 shows an example of the layout of the current setters 30 where they are placed in a triangular shape, suitably as an equilateral triangle so that the forces are taken up equally. The braces 42 run, as shown, between the respective flow collars 40 of the respective current setters 30, and where said float collars can further be anchored to the float collar 12 of the rearing pen 10 via cables or ropes 44. The current setters 30 can then be placed in an outer periphery of the groove 14, i.e. relatively close to the groove wall. Such a triangular arrangement of the current setters and intake of water as far out towards the groove wall as possible can result in a greater oxygen content in the water masses that are brought to the upper water layer.

Oxygen addition can be done by injecting oxygen into the current setters 30, both upstream of the propeller 38 and/or downstream of the propeller, then you get a nice oxygen addition and distribution of oxygen in the cage, as oxygen is dissolved in the fresh water from the nozzles in the outlet 34 without the fish being stressed due to displacement, and at the same time you save a lot of oxygen, as the more stress, the more oxygen is consumed. As oxygen is expensive, this will overall be a much less expensive de-worming than what is done today.

In order for it to still be possible to carry out a lice removal, an exemplary embodiment is shown in figure 10, a version with only a lice skirt and a groove in the rearing cage 10. The power setters 30 can be tilted and pulled inward into the brace frame and fixed in an approximately horizontal position by using drive motor 52 or push cylinder. The current setters 30 can therefore be stored via a hinge 54 so that the suction tube 36 can be lifted up and into a position so that the bottom ring 24 of the note can be raised up as it is common to do with a tarpaulin removal today.

According to the invention, the collecting funnel 18 makes it possible to de-lice without the use of external help other than raising the collecting funnel 18, and possibly lowering the skirt, so that it rests against the skirt 16 and seals the cage and de-lice can start from there and lice that are freed from the fish can be collected in the collection funnel 18 and sucked up to a destruction unit that is not shown in the figures. Alternatively, as mentioned, the skirt edge 16a can be lowered to the collecting funnel 18. Oxygen can be added by external oxygen supply.

In order to raise the collecting funnel 18 and possibly the bottom ring 24, the floating collar 12 of the rearing cage 10 can include equipment in the form of winches or the like.

In another embodiment, as shown in Figure 6, the current setter 30 is placed in the approximate center of the groove 14 with distribution of the water out through one or more nozzle tubes 60 attached to the suction tube 36, possibly to the respective outlet 34, and which are preferably directed outwards in an angle that creates a current that in turn creates an oxygen-rich and lice-free environment in the cage. The current setter 30 can via cables or ropes 44 be anchored to the floating collar 12 of the rearing pen 10. In the embodiment shown, three nozzle tubes 60 are placed to the suction tube 36, where the nozzle tubes are placed with each other and preferably at the same distance in terms of circumference. The nozzle tubes 60 shown can also be used with the solution discussed and shown in the other figures.

Figure 3 shows a further embodiment of the breeding pen 10 according to the invention. In addition to other construction features mentioned, it can comprise an extra groove 28 placed outside the first groove 14. The extra groove 28 can be fixed in the skirt 16, for example in the skirt edge 16a, and extend down to the bottom ring 24. Alternatively, the extra skirt can be attached to the floating collar 12 of the rearing cage 10, and correspondingly extend down to the bottom ring 24. The additional groove 28 can be designed similarly to a regular groove or a groove designed as a plankton cloth, i.e. very finely meshed, so that lice do not escape and into the rearing cage 10. Due to the size of the rearing facilities, there will still be sufficient water flow into the groove 14 even if the additional cloth 28 is very finely meshed. In addition to preventing the entry of lice, the extra cloth will also provide a double wall that can protect against escape if a hole occurs in groove 14.

As shown in Figure 4, the current setters 30, or preferably the current setter's floating collars 40, can be equipped with an upper stand 56 which supports a bird net 58.

Claims (17)

1. Farming cage (10) for raising fish, comprising a floating collar (12) which floats on the surface of the water, a groove (14) attached to the floating collar (12) to accommodate the farmed fish, where the groove (14) is also attached to a bottom ring ( 24) down in the water, as well as a skirt (16) which surrounds the groove (14) and which extends down into the water to an area above the bottom ring (24), characterized in that several current setters (30) are placed upright in the groove (14), where the respective current setter (30) comprises an elongated, vertical suction pipe (36) with a lower inlet (32) for the intake of water and an upper, mainly horizontal outlet (34) to distribute the water in the groove's (14) upper water masses and to set the upper water masses in rotation. 2. Breeding cage in accordance with claim 1, characterized in that the outlet (34) is located below the water surface (26) in the upper bodies of water. 3. Breeding cage in accordance with claim 1, characterized in that the inlet (32) to the current setters (30) is located in an area adjacent to the bottom ring (24). 4. Breeding cage in accordance with claim 1, characterized in that the inlet (32) to the current setters (30) is located in an area below the lower skirt edge (16a) of the skirt (16). 5. Breeding pen in accordance with claim 1, characterized in that said power setters (30) are equipped with a float collar (40), which float collars (40) of respective power setters (30) are connected to each other via stiffeners (42) to produce a rigid construction to absorb the forces arising from the outlet (34). 6. Breeding pen in accordance with claim 5, characterized in that the float collars (40) of the current setters (30), and/or possibly the stiffeners (42), are anchored to the breeding pen's float collar (12). 7. Breeding pen in accordance with claim 1, characterized in that three current setters (30) are mounted in the breeding pen, so that their location forms an equilateral triangle. 8. Breeding cage in accordance with claim 1, characterized in that the outlet (34) is rotatably mounted to the suction tube (36). 9. Breeding cage in accordance with claim 1, characterized in that the floating collar (40) of the respective current setter (30) is connected to the braces (42), and that a motor (52) is mounted to the floating collar (40) to tilt up and pull the current setters (30) to a substantially horizontal position. 10. Breeding cage in accordance with claim 1, characterized by the fact that under the groove (14) or in the area under the bottom ring (24) a collection funnel (18) is arranged which runs downwards into the water and which meets in a central sludge funnel (20), from which a sludge line (22) runs up to the float collar (12). 11. Breeding cage in accordance with claim 1, characterized in that the outlet (34) of the current setter (30) is equipped with one or more nozzle tubes (60). 12. Breeding cage in accordance with claim 1, characterized in that an extra groove or cloth (28) is arranged on the outside of the groove (14) that accommodates the fish to be reared, which is impervious to lice, as the extra groove (28) is suspended in the skirt (16), or in the float collar (12). 13. Breeding pen in accordance with claim 1, characterized in that the current setters (30) include equipment for adding oxygen by injecting oxygen into the suction tube (36). 14. Procedure for removing lice in a breeding cage (10) for raising fish, where the breeding cage (10) comprises a floating collar (12) which floats on the surface of the water, a groove (14) attached to the floating collar (12) to accommodate the fish to be reared , where the groove (14) is also attached to a bottom ring (24) down in the water, a skirt (16) which surrounds the groove (14) and which extends down into the water to an area above the bottom ring (24), and a collection funnel ( 18) suspended under the groove (14) or bottom ring (24), characterized in that the method comprises: raising the collecting funnel (18) and the bottom ring (24) up to a skirt edge (16a) of the skirt (16) to seal the cage (10), followed by de-lices in a commonly known manner. 15. Method in accordance with claim 14, characterized in that during raising of the collecting funnel the skirt edge (16a) is lowered until the skirt connects to the collecting funnel (18). 16. Method in accordance with claim 14, characterized in that lice removed from the fish are collected in the collection funnel (18) and sucked up to a destruction unit. 17. Method in accordance with claim 14, characterized in that the rearing cage (10) comprises a number of vertically arranged current setters (30) in the groove, and which are tilted and pulled up during raising of the collecting funnel (18).