NO20172057A1 - System and procedure - Google Patents

Description

The present invention relates to a system for the treatment of fish, and more particularly the present invention relates to a system for the removal of parasites on fish, especially salmon lice on salmon fish.

Parasites on farmed fish in general and salmonids in particular have been recognized as a serious problem in the farming industry for decades. Today, the parasite Lepeotheirus salmonis (L. salmonis) costs the global farming industry several billion kroner each year, with costs steadily increasing due to direct losses, expenses for chemical use and higher treatment frequencies, extra work in connection with de-lice, weight loss in fish due to stress , possible loss of fish, etc.

Salmon lice belong to the crayfish family, and are found naturally in all sea areas in the northern hemisphere. Salmon lice cause damage to salmon by feeding on mucus, skin and blood. This results in poor welfare and opens the door to other infections from bacteria and fungi.

An important factor in why salmon lice have become such a big problem is the great spread potential this type of parasite has. Salmon lice have planktonic larvae that can be transported over great distances, but how far is e.g. a. depending on current conditions and sea temperature. Open cages mean that the copepod has free access to a large number of hosts all year round along large parts of the Norwegian coast.

The salmon lice problem is currently handled by treating infected fish, and

in recent years, synthetic pyrethroids have been mainly used against salmon lice in bathing treatments, or emamectin via the feed. Experience from other use of this type of medication means that one can probably develop resistance sooner or later. Although there are alternatives to pyrethroids today, these are expensive to use on large fish. If, in the future, similar facilities are used to farm the marine species, there is good reason to assume that you may see similar problems with caligid jumping crayfish on these as you currently have with salmon lice and salmon. In 2002, emamectin, deltamethrin and cypermethrin were most commonly used. In the last three years, there has been a decline in consumption of cypermethrin, while emamectin has shown an increase. There has also been a trend where larger fish are treated with emamectin.

One of the major dangers with the current treatment regime against lice is the development of resistance. The drugs used against salmon lice today have all been used in the fight against harmful insects and resistance to all the most commonly used drugs has been seen. A bioassay has been developed to measure resistance/sensitivity to the most common de-lice agents. Resistance to organophosphates has been demonstrated in Norway, but so far there have been no findings indicating resistance to emamectins.

Cleaner fish eat lice that live on farmed fish. It is most effective on smaller salmon and when the water is not too cold. The cages must be clean otherwise the wrasse will eat the growth from the nuts instead.

Mechanical treatment has become more and more common in recent years because the salmon lice have developed resistance to the drugs. Examples of such new treatment methods are laser, scrubbing or brushing and rinsing with fresh or warm water.

In addition, lice skirts are used as a preventive measure.

NO 340713 B1 relates to a cleaning system for the removal of multicellular ectoparasites from fish, where a stream of cleaning water is directed towards the surface of the fish.

Gas bubbles are provided and distributed in the cleaning water stream so that a mixture is formed between the gas bubbles and at least some parts of the water from the fish surface by establishing contact between the mixture and the multicellular ectoparasites that are on the surface of the fish. The invention also relates to an application of a mixture that results from gas bubbles being provided and distributed in at least some parts of the water in a cleaning water stream, as well as a method for removing multicellular ectoparasites from the surface of the fish.

NO 340218 B1 relates to a system for removing parasites flowing in a transport pipe from an inlet to an outlet, the system comprising a main pump, at least one treatment chamber, a separation unit which is in fluid communication with a filter device and an intermediate pipeline, which intermediate pipeline is arranged between the treatment chamber and the separation unit, the treatment chamber comprising at least one outlet for draining fluid and at least one inlet for injection of fluid, where the inlet is arranged downstream of the outlet.

The separation unit is further placed in a first plane and the at least one treatment chamber is placed in a second plane, which first plane is higher than the second plane, so that the intermediate pipeline has a slope in a downstream direction. The invention also relates to a system for removing parasites on fish with a supply unit designed with a plurality of slot openings arranged in at least two slot paths which are arranged around a circumference of the supply unit, where said slot openings are offset relative to each other in the circular transverse direction.

NO 332298 B1 relates to a lice treatment system for marine organisms, where the system is a closed system comprising an inlet for fish to be treated, a first separator for separating fish and water, and which is arranged after the inlet, a pipeline for transporting the fish, in which at least part of the pipeline constitutes a liquid bath for the fish, and which is arranged for receiving treatment liquid, a second separator for separating fish and treatment liquid, an outlet for discharge of treated fish, and which is arranged after the second separator, and a circulation pump for circulation of treatment liquid in the closed system. The part of the pipeline that makes up the liquid bath is designed with a U-shape, so that a liquid bath is formed with respective liquid surfaces. At the end of the treatment, it may happen that some fish may remain in the liquid bath. For this reason, a hatch or similar may have been created in the part of the pipeline that makes up the liquid bath, so that fish can be taken out manually. In an alternative embodiment, a compressed air system can be produced which blows out the fish. A further alternative is for the circulation pump to supply a sufficient amount of liquid for the fish to be rinsed out. The fish is thus transported through the pipeline due to the liquid flow of treatment liquid supplied by the circulation pump, and by the fish flow into the other end.

There is thus a need for an alternative to the current methods for removing parasites from fish, or at least supplementary procedures, where processing time and fish density through the system are significantly more predictable.

The purpose of the present invention is to provide a system for the removal of parasites from fish, where the treatment will result, by exposing the fish to less stress during treatment and where mortality during treatment is reduced, that fish welfare is safeguarded and that the quality of the fish is improved.

These purposes are achieved according to the present invention with a system and a method for the treatment and removal of parasites on fish as defined in the independent claims 1 and 20. Further embodiments of the invention are defined in the independent claims.

According to the present invention, the statement that a pipeline has a gradient is to be understood as meaning that the pipeline in some designs has a downward slope from an inlet and towards an outlet, or an upward slope from an inlet and towards an outlet. The gradient in these embodiments can either vary between zero and negative between inlet and outlet, or vary between zero and positive between inlet and outlet. A pipeline in a system according to the above-mentioned embodiments will thus not be able to have a gradient that varies and/or shifts between positive and negative between inlet and outlet.

In an alternative embodiment according to the present invention, the pipeline will be able to be pressurized, whereby the pipeline in this case will be able to have a gradient that varies between negative and positive between an inlet and an outlet.

The present invention relates to a system for the treatment and removal of parasites, such as salmon lice, on fish, where the system according to a first embodiment can comprise a pipeline that is used for the transfer of fish, where an inlet for fish is arranged at one end of the pipeline and a outlet for fish is arranged at an opposite end of the pipeline, and where at least a pump for circulation of treatment water and a collection tank for treatment water through at least one pipe are connected to the pipeline to form a closed system, where the pipeline has a gradient that varies between zero and negative from the pipeline's inlet to outlet, where a compellingly high speed of the treatment water from inlet to outlet provides a desired treatment time for fish through the system, where the treatment water is further continuously flowing from inlet to outlet, and where the treatment water is supplied to the pipeline in the inlet for fish .

As fish will seek to swim against a current of water, at least one pump for circulation of the treatment water in the system will be used to supply the treatment water at the inlet for fish with a flow rate of the treatment water that is greater than a maximum speed at which fish can swim against a current of water, so that the fish are forced along by the treatment water through the pipeline, from inlet to outlet, in order to provide a predictable and essentially equal treatment time for all fish that are brought through the pipeline.

An expert in the field will know that the flow rate of the treatment water will be able to be varied in relation to the gradient of the pipeline, the degree of filling of the pipeline etc., whereby this is not described further here.

According to a second embodiment, the system for treating and removing parasites on fish may comprise a pipeline used for the transfer of fish, where an inlet for fish is arranged at one end of the pipeline and an outlet for fish is arranged at an opposite end of the pipeline , and where at least one pump for circulation of treatment water and a collection tank for treatment water through at least one pipe are connected to the pipeline to form a closed system, where the pipeline further has a gradient varying between zero and positive from the pipeline inlet to the outlet, where an imperatively high speed of the treatment water from inlet to outlet provides a desired treatment time for fish through the system, where the treatment water is further continuously flowing from inlet to outlet, and where the treatment water is supplied to the pipeline in the inlet for fish.

According to a further embodiment, the system for the treatment and removal of parasites on fish may comprise a pipeline used for the transfer of fish, where an inlet for fish is arranged at one end of the pipeline and an outlet for fish is arranged at an opposite end of the pipeline, and where at least one pump for circulation of treatment water and a collection tank for treatment water through at least one pipe are connected to the pipeline to form a closed system, where the pipeline has a gradient that varies between negative and positive from the pipeline inlet to the outlet, where a compellingly high speed of the treatment water from inlet to outlet provides a desired treatment time for fish through the system, where the treatment water is further continuously flowing from inlet to outlet, and where the treatment water is supplied to the pipeline at the fish inlet. By supplying air under pressure to the system, an air lock can be formed in the pipeline, which means that the pipeline can be pressurized.

The system for the treatment and removal of parasites on fish can, for example, be used when infected fish in a breeding cage are to be treated, or when fish are to be transported from a breeding facility to a slaughter facility which may be on board a vessel or on land. The system for treating and removing parasites on fish can then be arranged on a vessel, such as a well boat or on a barge. Fish will then be collected or squeezed together in a breeding cage and then pumped with the help of one or more pumps to the inlet of the pipeline and then parasites, such as salmon lice, will be removed from the fish by forcing the fish through the pipeline, after which the fish will be taken to a new breeding farm or also to a vessel that will slaughter the fish or transport the fish to a slaughter plant on land.

The pipeline can be connected to a raising and lowering device, so that the gradient of the pipeline can be regulated. Furthermore, the pipeline can have a closed or partially closed cross-section.

The treatment water that is circulated through the system can be fresh water which can preferably be heated, for example to a temperature of 20<0>C – 40<0>C, more preferably to a temperature of 25<0>C – 35<0>C , most preferably at a temperature of around 30<0>C, as salmon lice do not thrive in fresh water and/or heated water, after which the salmon lice will release the fish after a given exposure time in the treatment water. The exposure time can be, for example, 15 s - 50 s, more preferably 20 s - 40 s, most preferably 30 s.

According to the present invention, chemicals and/or treatment agents can also be added to the treatment water, which chemicals and/or treatment agents will also be able to contribute to the removal of salmon lice from the fish transported through the pipeline. Chemicals and/or treatment agents can, for example, be added to the treatment water in or at the inlet of the pipeline, or also in the collection tank for treatment water. Suitable devices can be used to control and possibly add further addition of chemicals and/or treatment agents.

In an embodiment of the system for the removal of parasites on fish, the system may comprise a first separator which is arranged adjacent to the inlet for fish, where the separator will separate fish and water, so that only fish are fed into the pipeline - via the treatment water which from the start has a speed that the fish is unable to swim against - which is used for the transfer and processing of fish. Such a separator can, in its simplest form, be a container designed with a grate through which the fish is passed, where the water will be filtered through the grate. A person skilled in the art will know how such a separator can be designed, and it is thus not described further here. The system can also include a second separator to separate fish and treatment water, where the second separator can be rotatably connected to the outlet for fish.

The second separator can in one embodiment be connected to a raising and lowering device, where the raising and lowering device can be used to raise and/or lower the second separator in relation to the outlet for fish, so that the angle between the second separator and the outlet for fish changes.

The second separator can also be suitably connected to the collection tank, so that treatment water that is filtered in the separator is collected in the collection tank and returned to the inlet through the at least one pump.

In one embodiment of the system, a further pump for circulation of treatment water can be connected to the collection tank. Such an arrangement will mean that the pumps can be operated together to circulate treatment water around the closed system, where the pumps can then be operated independently of each other, or that one pump is used as a redundant solution.

At least one heating and filter unit can further be connected to the at least one pipe that forms the closed circuit in the system, where the at least one heating and filter unit in one embodiment can be arranged between each pump for circulation of treatment water and the inlet for fish, as that the treatment water is filtered and, if necessary, can be heated before it is supplied to the pipeline. The salmon lice that escape and fall off the salmon during treatment in the pipeline will then be collected in the heating and filter unit.

The at least one heating and filter unit can also be thought of as being arranged between the collection tank and each pump for circulation of treatment water.

In an alternative embodiment, the heating and filter unit can be two separate and distinct units, where the separate filter unit can for example be arranged after the collection tank, while the separate collection unit can for example be arranged after the pump for circulation of treatment water.

Each heating and filter unit may comprise one or more heating elements and one or more filters. A person skilled in the art will know how such a unit should be designed, whereby this is not described further here.

In connection with the closed system, the system may include meters and equipment to monitor the temperature of treatment water and the amount of treatment water circulating in the system.

According to the present invention, the system for removing parasites on fish can also include an inspection device that enables an inspection and/or monitoring of fish that are in the pipeline, where such an inspection device can include a glass hatch, camera or similar that is designed in the pipeline, or be a pipeline segment designed with glass or transparent plastic around all or part of the pipeline segment's circumference. Alternatively, the pipeline segment may be partially open.

Correspondingly, the system can comprise at least one counting device for fish, where the counting device can be arranged at the inlet for fish. It is also conceivable that a further counting device for fish can be arranged at the outlet for fish, so that a check can be made on how many fish are in the pipeline at any given time.

The present invention also relates to a method for the treatment and removal of parasites on fish in a system as stated above, where the method may include the following steps:

a) to feed a pipeline of fish continuously at an inlet,

b) supplying the pipeline with purified treatment water at a speed and a volume that results in a continuous flow of treatment water from inlet to outlet, where the treatment water is supplied at a speed greater than a maximum speed at which fish can swim against a stream of water, so that the fish are forced with the treatment water through the pipeline, from inlet to outlet, in order to provide a predictable and essentially equal treatment time for fish that is carried through the pipeline,

c) to separate fish and treatment water, after an outlet, over a second separator and to collect treatment water in a collection tank,

d) to use at least one pump to pump treatment water from the collection tank to a heating and filter unit,

e) to heat and purify the treatment water to a desired temperature and purity in the heating and filter unit, and

f) to return and supply purified treatment water to the pipeline (2).

The method can further before step a) include a step of using a raising and lowering device connected to the pipeline to raise or lower the pipeline to a desired gradient.

Other advantages and distinctive features of the invention will be clear from the following detailed description, the attached drawings and subsequent claims, where

Figure 1 shows a first embodiment of a system for the treatment and removal of parasites on fish according to the present invention,

Figure 2 shows a second embodiment of a system for the treatment and removal of parasites on fish according to the present invention, and

Figure 3 shows an alternative embodiment of a system for the treatment and removal of parasites on fish according to Figure 2, and

Figure 4 shows a third embodiment of a system for the treatment and removal of parasites on fish according to the present invention.

Figure 1 shows a principle sketch of a first embodiment of a system 1 for the treatment and removal of parasites on fish, where the system 1 for the treatment and removal of parasites on fish comprises a pipeline 2 for the transfer and treatment of fish, where an inlet 3 for fish is arranged at one end of the pipeline 2 and an outlet 3 for fish is arranged at an opposite end of the pipeline 2. A pump 5 for circulation of treatment water and a collection tank 6 for treatment water are connected to the pipeline 2 through a pipe 7, so that a closed circulation system is formed in system 1 for the treatment and removal of parasites on fish.

According to the present invention, the pipeline 2 will have a gradient that is negative from inlet 3 to outlet 4, and through the closed circulation system will mainly be filled with continuously flowing treatment water from inlet 3 to outlet 4, where the treatment water is fed into inlet 3 for fish. However, it should be understood that pipeline 2 can also be half full of treatment water.

Adjacent to the inlet 3 for fish, a first separator 8 is arranged to separate fish and seawater, the first separator 8 being connected with a hose (not shown) or pipe which extends down into, for example, a breeding cage (not shown) which contains fish to be processed. The hose (not shown) or pipe is connected to a pump device (not shown), so that fish and seawater are pumped up from the rearing cage and over to the first separator 8 for filtering out seawater.

A second separator 9 for separating fish and treatment water is rotatably connected to the outlet 4 for fish. A raising and lowering device (not shown) will be connected to the second separator 9, where the raising and lowering device is used to raise or lower the second separator in relation to the outlet 4 for fish.

Figure 1 also shows that a pump 5 is used for circulation of treatment water in the closed circulation system.

Between the pump 5 and the pipeline 2 for transferring and processing fish, a heating and filter unit 10 is arranged, where the heating and filter unit 10 is used to remove parasites such as salmon lice that have fallen off the fish during processing and that have been collected in the collection tank 6, so that the treatment water supplied to the pipeline 2 is free of parasites. The heating and filter unit 10 will also, if necessary, be used to heat the treatment water before the treatment water is supplied to the pipeline 2.

Figure 2 shows a principle sketch of a second embodiment of a system 1 for the treatment and removal of parasites on fish, where the system 1 for the treatment and removal of parasites on fish comprises a pipeline 2 for the transfer and treatment of fish, where an inlet 3 for fish is arranged at one end of the pipeline 2 and an outlet 3 for fish is arranged at an opposite end of the pipeline 2. Two pumps 5 for circulation of treatment water and a collection tank 6 for treatment water are connected to the pipeline 2 through at least one pipe 7, so that a closed circulation system is formed in system 1 for the removal of parasites on fish.

According to the present invention, the pipeline 2 will have a gradient which is negative from inlet 3 to outlet 4, and through the closed circulation system will mainly be filled with constantly flowing treatment water from inlet 3 to outlet 4, where the treatment water is fed into inlet 3 for fish. However, it should be understood that pipeline 2 can also be half full of treatment water.

Adjacent to the inlet 3 for fish, a first separator 8 is arranged to separate fish and seawater, the first separator 8 being connected with a hose (not shown) or pipe that extends down into, for example, a breeding cage containing fish to be processed . The hose (not shown) or pipe is connected to a pump device (not shown), so that fish and seawater are pumped up from the rearing cage and over to the first separator 8 for filtering out seawater.

A second separator 9 for separating fish and treatment water is rotatably connected to the outlet 4 for fish. A raising and lowering device (not shown) will be connected to the second separator 9, where the raising and lowering device is used to raise or lower the second separator in relation to the outlet 4 for fish.

The pumps 5 can be run together to circulate treatment water, or separately. The arrangement will thus be designed so that the pumps 5 can be used independently of each other.

Between the pumps 5 and the pipeline 2 for the transfer and processing of fish, a heating and filter unit 10 is arranged adjacent to each pump 5, where the heating and filter unit 10 is used to remove parasites that have fallen off the fish during processing and that have been collected in the collection tank 6, so that the treatment water supplied to the pipeline 2 is clean of parasites. Each heating and filter unit 10 will also, if necessary, be used to heat up the treatment water before the treatment water is supplied to the pipeline 2 in or at the inlet 3. The heating and filter units 10 can also be connected to each other, so that they can be operated independently of each other or in dependence on each other.

Figure 3 shows an alternative embodiment of a system 1 for the treatment and removal of parasites on fish according to Figure 2, where the pipeline 2 in this case also has a gradient that is negative from inlet 3 to outlet 4, but where the pipeline 2 is additionally arranged to have a meander shape. Pipeline 2 is further filled with constant continuous flowing treatment water from inlet 3 to outlet 4, and where the treatment water is fed into inlet 3 for fish. The system 1 for treatment and removal of parasites further comprises a first separator 8, a second separator 9, two pumps 5 for circulation of treatment water, a collection tank 6 for treatment water and two heating and filter units 10, where the placement of the above-mentioned elements essentially is the same as described in relation to system 1 for the treatment and removal of parasites on fish according to figure 2.

Figure 4 shows a principle sketch of a third embodiment of a system 1 for the treatment and removal of parasites on fish according to the present invention, where the system 1 comprises a pipeline 2 for the transfer and treatment of fish, where an inlet 3 for fish is arranged near one end of the pipeline 2 and an outlet 4 for fish are arranged at an opposite end of the pipeline 2. The pipeline 2 will be designed to have a negative gradient in an area at the inlet 3, after which the pipeline 3 will be designed to have a positive gradient to the outlet 4. Through the design of the pipeline 2, an air lock will form in the pipeline, which means that the pipeline 2 will be able to be pressurized.

At least one pump 5 for circulation of treatment water and a collection tank 6 for treatment water are connected to the pipeline 2 through at least one pipe 7, so that a closed circulation system is formed in the system 1 for treatment and removal of parasites on fish.

The pipeline 2 will, through the closed circulation system, be mainly completely filled with continuously flowing treatment water from the inlet 3 to the outlet 4, where the treatment water with a given pressure is supplied to the pipeline 2 at the inlet 3 for fish.

Adjacent to the part of the pipeline 2 which is designed to have a negative gradient, a first separator 8 is arranged to separate fish and seawater. The first separator 8 is connected to a hose (not shown) or pipe which extends down into a rearing cage (not shown) containing fish to be treated. The hose or pipe is connected to a pump device, so that fish and seawater can be pumped up from the rearing cage and over to the first separator 8 for filtering out seawater. The first separator 8 is further connected through a line 11 to an air source (not shown) or similar and a compressor, pump or similar, in order to be able to supply pressurized air to the first separator 8, so that an air lock is formed in the pipeline, so that the pipeline can be pressurized and filled essentially completely with treatment water to be able to move the fish to the outlet 4. The first separator 8 will then be designed to be able to maintain a certain pressure on the inside.

A second separator 9 for separating fish and treatment water is arranged at and connected to the outlet 4 for fish.

Between the pump 5 for circulation of treatment water and the pipeline 2, a heating and filter unit 10 is arranged, where the heating and filter unit 10 is used to remove salmon lice that have fallen off the fish during treatment in the pipeline 2 and which have been collected in the collection tank 6 for treatment water, so that the treatment water supplied to pipeline 2 is clean for salmon lice. The heating and filter unit 10 will, if necessary, be used to heat up the treatment water before the treatment water is supplied to the pipeline 2.

The present invention also relates to a method for the treatment and removal of parasites on fish in a system as stated above, where the method comprises the following steps: to supply fish continuously to a pipeline 2 at the pipeline's inlet 3, to supply the pipeline 2 with purified treatment water at a rate and a volume that causes a continuous flow of treatment water between the inlet 3 and outlet 4 of the pipeline 2, where the treatment water is supplied at a speed that is greater than a maximum speed fish can swim against a stream of water, so that the fish are forced along by the treatment water through the pipeline 2 , from inlet 3 to outlet 4, so as to provide a predictable and essentially equal treatment time for fish through the pipeline 2, to separate fish and treatment water after outlet 4 and over a second separator 9 and to collect the desilted treatment water in a collection tank 6 for treatment water, to use at least one pump to pump treatment water from the sump the ling tank 6 to at least one heating and filter unit 10, if necessary to remove parasites from the heating and filter unit 10 and to heat the treatment water to a desired temperature and to return and supply purified treatment water to the pipeline 2.

The method can further, before the step of supplying fish continuously to the pipeline 2 at the pipeline 2 inlet 3, if necessary, include a step of using a raising and lowering device connected to the pipeline 2 to raise or lower the pipeline 2 to a desired gradient.

The method can also include a step of pressurizing the treatment water before it is supplied to the pipeline 2.

The invention is now explained with several non-limiting examples. A person skilled in the art will understand that a number of variations and modifications can be made to the system for treating parasitic fish as described within the scope of the invention as defined in the appended claims.

Claims (22)

PATENT CLAIMS 1. A system (1) for the treatment and removal of parasites on fish, where the system (1) comprises a pipeline (2) with an inlet (3) for fish and an outlet (3) for fish arranged at opposite ends of the pipeline ( 2), where the pipeline (2) through pipe (7) is in fluid communication with at least one pump (5) for circulation of treatment water and a collection tank (6) for treatment water, thus forming a closed system, characterized in that the treatment water has a flow rate (A ) between inlet (3) and outlet (4) which is greater than a maximum speed (B) fish can swim against a water current, so that fish are forced along by the flow speed (B) of the treatment water and a predictable and essentially equal treatment time is provided for fish between the inlet (3) to the outlet (4), where the treatment water is further continuously flowing from inlet (3) to outlet (4). 2. System according to claim 1, characterized in that the gradient of the pipeline (2) varies between zero and negative from inlet (3) to outlet (4). 3. System according to claim 1, characterized in that the gradient of the pipeline (2) varies between zero and positive from inlet (3) to outlet (4). 4. System according to claim 1, characterized in that the gradient of the pipeline (2) varies between negative and positive from inlet (3) to outlet (4). 5. System according to claim 1, characterized in that the pipeline (2) has a closed or open cross-section. 6. System according to claim 1, characterized in that the pipeline (2) is connected to a raising and lowering device to be able to regulate the gradient of the pipeline (2). 7. System (1) according to claim 1, characterized in that the treatment water supplied to the pipeline (2) is water with a preferred temperature of 20<0>C – 40<0>C, more preferably with a temperature of 25<0>C – 35<0>C, most preferably with a temperature of around 30<0>C. 8. System (1) according to one or more of the preceding claims, characterized in that the treatment water is water with added treatment agents. 9. System (1) according to one or more of the preceding claims, characterized in that the system (1) further comprises a first separator (8) to separate fish and water, arranged adjacent to the inlet (3) for fish. 10. System according to claim 9, characterized in that an air source is connected to the first separator (8) through a pipe (11) or equivalent. 11. System (1) according to one or more of the preceding claims, characterized in that the system (1) further comprises a second separator (9) to separate fish and treatment water, which second separator (9) is rotatably connected to the outlet (4) for fish. 12. System (1) according to claim 5, characterized in that the second separator (9) for separating fish and treatment water is connected to a raising and lowering device (not shown), so as to be able to change an angle the second separator (9) forms with the outlet (4) for fish. 13. System (1) according to one or more of the preceding claims, characterized in that the second separator (9) to separate fish and treatment water is connected to the collection tank (6). 14. System (1) according to one or more of the preceding claims, characterized in that the system (1) further comprises a pump (5), which is connected to the pipeline (2) through at least one pipe (7). 15. System (1) according to one or more of the preceding claims, characterized in that a heating and filter unit (10) is connected to the at least one pipe (7), where the heating and filter unit (10) is arranged between the at least one pump (5) and the pipeline (2). 16. System (1) according to claim 10, characterized in that the heating and filter unit (10) comprises one or more heating elements and one or more filters. 17. System (1) according to one or more of the preceding claims, characterized in that the system (1) further comprises an inspection unit (not shown) to monitor the fish. 18. System (1) according to one or more of the preceding claims, characterized in that the system (1) further comprises a counting device (not shown) 19. System (1) according to one or more of the preceding claims, characterized in that the system (1) further includes meters and equipment to monitor the temperature of the treatment water and the amount of treatment water circulating through the system (1). 20. Procedure for the treatment and removal of parasites on fish in a system according to one or more of claims 1-19, characterized in that the procedure comprises the following steps: a) supplying a pipeline (2) with fish continuously at an inlet (3), b) supplying the pipeline (2) with purified treatment water at a speed and a volume which results in a continuous flow of treatment water from inlet (3) to outlet (4), where the treatment water is supplied at a speed greater than a maximum speed at which fish can swim a flow of water, so that the fish are forced along by the treatment water through the pipeline, from inlet to outlet, so as to provide a predictable and essentially equal treatment time for fish carried through the pipeline, c) to separate fish and treatment water, after an outlet (4), over a second separator (9) and to collect treatment water in a collection tank (6), d) using at least one pump (5) to pump treatment water from the collection tank (6) to a heating and filter unit (10), e) to heat and purify the treatment water to a desired temperature and purity in the heating and filter unit (10), and f) to return and supply purified treatment water to the pipeline (2). 21. Method according to claim 19, characterized in that the method before step a) further comprises a step of using a raising and lowering device connected to the pipeline (2) to raise or lower the pipeline (2) to a desired gradient. 22. Method according to claim 19, characterized in that the method further comprises a step of monitoring or controlling the temperature and/or amount of treatment water between the inlet (3) and the outlet (4).