NO341898B1 - Aquaculture pool with slide for fish farming - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fish farming fish pool, wherein the fish farming pool comprises two circular ends connected to long sides, the elements, when assembled, forming an elongated fish farming pool. A dividing wall is further arranged in or near a center plane extending over the longitudinal length of the fish pool, so as to form a continuous pool channel in the fish pool, where there is on and around an inside of the circular ends, long sides and on and around an outside of the dividing wall. arranged rails for continuous guiding of at least one sliding bulkhead arranged in the continuous pool channel.

Description

The present invention relates to a breeding pool for breeding fish and the like as stated in the preamble to the independent claim 1.

In connection with the farming and transport of live fish, there is often a need to crowd the fish together in a part of the tank, breeding pool or cage where the fish are located. Such compression is needed, for example, in connection with sorting the fish or because the fish is to be pumped into another pool or other cage.

A number of different marine installations for the farming of fish and shellfish are known. The most well-known installations are breeding cages, where these are designed with floating elements at the top, to which floating elements flexible side walls are connected and where a bottom is attached to the side walls. Often the bottom is also made of a flexible material. Different ways of keeping the cage tensioned are known. The most common is to use a bottom ring, and to keep the lower end of the side walls open with this.

The bottom ring is connected to the floating elements through a chain or similar. When a breeding pen is to be emptied, for example because the fish or shellfish are to be slaughtered, this can be done in several known ways. It is usual to raise the bottom of the cage gradually, as this will concentrate the fish within a smaller volume, resulting in the emptying of the cage going faster, while at the same time it is easier to check that the cage has been emptied. In traditional cages as described above, the volume is reduced by raising the bottom ring with which the lower part of the side walls are connected, while at the same time pulling up the knot line in the side walls. The notline is pulled up manually and is hung in folds on the floating elements. It must be pulled as evenly as possible both in the bottom ring and in the side walls to avoid stretching the knot line, which in turn can lead to holes in the knot. If skewed loads occur, it may cause tension in the knot line and/or the knot line may come into contact with the bottom ring's mooring chains. Contact between the knot line and the mooring chain can lead to wear and holes in the knot line. Raising the bottom is therefore resource-intensive, and requires a lot of manpower and equipment. The biggest problem with known cages is that there is uneven wear, tears and/or holes in the net line in the wall and/or bottom when the bottom ring is raised.

The work of raising the bottom ring is also risky for the crew who are either on the floating elements or in boats that are close to the floating elements. In rough seas, it is also a problem that cage bags/nets move and that the fish come into contact with these. This can result in stressed fish, lower fish welfare and damage to the fish.

NO 336552 describes how two or more sliding bulkheads which can rotate around a central column in a circular cage can be used to crowd the fish together or to sort fish of different sizes. The sliding bulkhead can be rotated by mounting a toothed wheel on the periphery of the sliding bulkhead that runs in a gear ring on the edge of the cage.

NO 315351 describes how a sliding bulkhead in a rectangular pool with water flow can be used to sort fish.

NO 2001 2898 describes how a sliding bulkhead in an essentially rectangular transport pool with double-curved long sides and cross walls at each end is designed to be able to run with an edge close to the frame outline, so that in any intermediate position between a fore and aft bulkhead to complete the cross-sectional area in a well space.

WO 2008/032102 A2 relates to an aquaculture system, where the system comprises a container or tank containing a quantity of a fluid, such as water.

The aquaculture system is designed to form a flow path for the water, where a device is used to provide a flow of water in the container or tank and where deflector devices will exert a force on the fish to direct the fish away from a wall of the container or tank to prevent or reduce damage to the fish.

WO 2004/093534 A1 relates to a land- or sea-based breeding facility for fish, where the breeding facility comprises a breeding pen in the form of a continuous loop of circulating water in a laminar flow. The continuous loop has a cross-sectional profile like an open tube or half-tube, where the cross-sectional profile is substantially constant around the continuous loop. At least the lower part of the cross-sectional profile is designed smooth, without sharp edges or corners. Preferably, each rearing unit comprises two straight, parallel half-pipes and two curved half-pipes which connect the straight, parallel half-pipes.

GB 1,592,085 A and GB 1,567,171 A relate to a breeding facility comprising an elongated tank, where the ends of the tank are rounded and where a central dividing wall runs along the interior of the tank so as to form an oval pond. The middle partition comprises an inner chamber which functions as an air chamber.

For pools or cages that are not circular or rectangular, one or more nets are usually used that are pulled along the edges of the pool to crowd the fish together, or that the cage is designed as a groove so that the entire net can be raised and that the fish are thereby crowded together.

There is thus a need for alternatives to current methods for designing a marine installation for fish farming, or at least supplementary alternatives.

The purpose of the present invention is to provide a breeding pool for breeding fish and for handling fish.

A further object according to the present invention is to provide a breeding pool for breeding fish which is easy to use and to maintain and which is cost-saving.

These purposes are achieved according to the present invention with a breeding pool for breeding fish as defined in the independent claim. Further embodiments of the invention are defined in the independent claims.

As the term "continuous" is used in the present application, this is to be understood as something arranged in a closed or endless configuration. A continuous channel according to the present invention will then be a channel that begins and ends at the same point. Correspondingly, a continuous rail will then be a rail that begins and ends at the same point.

The present invention relates to a rearing basin for raising fish, where the rearing basin comprises two curved ends which are connected by long sides, thus forming an elongated rearing basin. A dividing wall can also be arranged in a central plane which extends over the longitudinal length of the breeding basin. Alternatively, the partition wall can be arranged around an inner periphery of the breeding pool, and parallel to the inner periphery, in a closed configuration, where the partition wall will then be arranged at a distance from the center plane that extends over the longitudinal length of the breeding pool.

The arrangement of the partition wall within the rearing basin will result in the formation of a division of an internal volume of the rearing basin, where this division results in the formation of a continuous channel in the rearing basin.

There is further arranged on and around an inside of the curved ends and long sides at least one rail, where the at least one rail will extend around the entire inner periphery of the rearing pool to form a continuous rail. Correspondingly, at least one rail will be arranged on and around an outer periphery of the partition wall, where the at least one rail will extend around the entire outer circumference of the partition wall to form a continuous rail. The rails around the inner periphery of the rearing pool and the outer periphery of the partition wall will enable at least one sliding bulkhead which is arranged in the continuous channel, i.e. between the inside of the rearing pool and the partition wall, to be able to be continuously moved around in

the breeding pool.

The breeding pool can be made of concrete, steel, composite or a combination of these. The breeding pool can further be in one unit, or it can also be made of several sections which are then assembled into the breeding pool.

In one embodiment, the dividing wall can be arranged in the central plane that runs through the breeding facility, where the dividing wall can then at least have the same length as the long sides.

In another embodiment, the partition wall may comprise two curved ends and two long sides which are assembled to form a closed configuration of the partition wall, where the partition wall will then extend around and parallel to the inner circumference of the buoyancy basin. The long sides of the closed dividing wall will then be arranged on either side of the center plane that runs through the breeding pool, at a distance from the center plane.

The at least one sliding bulkhead which is arranged in the continuous channel, i.e. between the inside of the rearing pool and the partition wall, is connected to the rails arranged on the inside of the rearing facility and around the partition wall through at least one fastening device.

One or more struts can be arranged over the length of the breeding pool's long sides, where the struts are arranged across the length of the breeding pool and extend from long side to long side. The transverse struts can then be connected in a suitable way to the dividing wall which runs in the longitudinal direction of the breeding pool, in order to stiffen the dividing wall.

The breeding pool for breeding fish according to the present invention can be used both onshore and offshore.

If the breeding pool is used offshore, one or more sets of buoyancy elements can be arranged around an outer circumference of the breeding pool, in order to keep the breeding pool afloat. It is also conceivable that one or more ballast elements can be used, in order to be able to regulate the depth of the breeding pool in the water.

The breeding basin can also be designed with a number of intakes for water, so that water can be supplied to the breeding facility. The intakes can be connected to devices for filtering water, supplying oxygen or similar. Alternatively, pumps etc. can be used to supply water to the breeding pool. In a similar way, the breeding pool can be designed with one or more outlets for water, separate outlets for contaminated water, where these can further be connected to various purification devices etc. Alternatively, a purification plant can be connected to the breeding pool, so that the water in the breeding pool is cleaned and returned back to the breeding pool.

The fastening devices used to connect the smallest one sliding bulkhead to the rails arranged on the inside of the rearing pool and around the perimeter of the partition may comprise one or more devices in the form of a slide, one or more wheels, gears or similar, where the devices by means of at least one arm is connected to each sliding bulkhead used. The rails can then be designed with a holding and guiding device for the fastening devices. The holding and guiding devices can also be designed with a groove or a slot that runs over the entire length of the rail. Through the design of the fastening devices and the rails, the device of the fastening device can be received in the rails' holding and guiding device, whereby this will mean that the sliding bulkheads arranged in the breeding pool can be guided around the entire continuous channel in the breeding pool.

The fastening device can further comprise a motor which is electrically, hydraulically or pneumatically driven.

The sliding bulkhead can be designed with an outer rigid frame, where a grating is releasably connected to the outer rigid frame. The grid can be made of metal or also made up of a notlin. The grid is also designed with mesh sizes that allow water to flow through the grid, but prevent fish from escaping.

If fish in the breeding pool are to be sorted, the grating can easily be replaced with another grating designed with larger or smaller openings, which will allow fish below a certain size to escape through the grating when the sliding bulkhead or bulkheads are moved around the breeding pool.

Around the outer rigid frame there can also be arranged brushes or similar, where the brushes are designed to be able to be brought into contact with internal surfaces of the rearing pool, and around the entire circumference of the rearing pool. When the sliding bulkhead or sliding bulkheads are moved, the brushes will coat and scrub the inside of the pool channel, so that growth will be loosened and removed. In addition, the brushes will be able to carry away dead fish and any objects lying on the bottom of the breeding pool, as the dead fish will follow the movement of the sliding bulkhead.

In order to reduce the load on fastening devices and rails, an upper edge of the sliding bulkhead can be connected to buoyancy bodies, so that the sliding bulkhead essentially hangs down from the buoyancy bodies, thereby reducing the load on the fastening devices and rails.

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 breeding pool according to the present invention, seen from above,

Figure 2 shows a second embodiment of a breeding pool according to the present invention, seen from above,

Figure 3 shows a transverse cross-section of the breeding basin according to Figure 1,

Figure 4 shows a further embodiment of a breeding pool according to the present invention, seen from above,

Figure 5 shows sliding bulkheads arranged in the breeding pool according to Figure 1, seen from above,

Figure 6 shows a transverse cross-section of the breeding basin according to Figure 1, with sliding bulkheads,

Figures 7 and 8 show a first embodiment of a fastening device for sliding bulkheads according to the present invention, seen in cross section from the front and from the side,

Figures 9 and 10 show a second embodiment of a fastening device for a sliding bulkhead according to the present invention, seen from the side and in cross-section from the front,

Figure 11 further an embodiment of a fastening device for sliding bulkheads according to the present invention, seen in cross-section from the front,

Figures 12 and 13 show a further embodiment of a fastening device for sliding bulkheads according to the present invention, seen in cross-section from the front,

Figures 14 and 15 show a sliding bulkhead and details thereof, and

Figures 16A-16E show an embodiment of a breeding pool according to the present invention.

Figure 1 shows a first embodiment of a breeding pool B according to the present invention, where the breeding pool B comprises two curved ends 1, 2, which are connected in a suitable manner with long sides 3, 4, thus forming an elongated breeding pool B. A partition wall 5 is further arranged in a central plane which runs through the length of the breeding basin B, where the dividing wall 5 has at least the same length as the long sides 3, 4.

The placement of the dividing wall 5 in a central plane will result in the formation of a continuous channel in the breeding basin B.

A lower end of the partition wall 5 is connected in a suitable way to a bottom in the breeding basin B, while an upper end of the partition wall 5 is connected to three transverse struts 4A, 4B, 4C, where the transverse struts 4A, 4B, 4C are arranged in a distance from each other. The transverse struts 4A, 4B, 4C are arranged such that the transverse strut 4A is arranged in the transition between the circular end 1 and the long sides 3, 4, while the transverse strut 4C is arranged in the transition between the long sides 3, 4 and the circular end 1 .

The last transverse strut 4B is arranged in the middle of the length of the long sides 3, 4, i.e. half the length of the long sides 3, 4. The transverse struts 4A, 4B, 4C will run from one long side 3 and over to the opposite long side 4, where each end of each transverse strut 4A, 4B, 4C is suitably connected to its long side 3, 4.

The connection of the ends of the partition wall 5 to the bottom of the rearing basin B and to the transverse struts 4A, 4B, 4C will result in the partition wall 5 being "stiffened".

Figure 2 shows another embodiment of a rearing basin B according to the present invention, where the rearing basin B also in this embodiment comprises two curved ends 1, 2, which are connected in a suitable manner with long sides 3, 4, thus forming an elongated rearing basin B.

The rearing basin B further comprises a partition wall 6, where the partition wall 6 is designed to have the same start and end point. A delimited volume V will then be formed within the partition 6, where this delimited volume can be used for drug treatment of fish, deworming of fish, etc.

Alternatively, the rearing basin B can be designed open in this area, where the rearing basin B in this case will comprise the volume delimited by an inside of the long sides 3, 4, and the curved ends 1,2 and an outside of the continuous partition wall 6.

Two transverse struts 4A, 4C are used to stiffen the partition wall 6, as an upper end of the partition wall will then be connected to the respective transverse struts 4A, 4C, while a lower end of the partition wall 6 will then be connected to an inside of the rearing basin B.

The different elements in the rearing basin B can be made of different materials, for example only concrete, only steel, only composites, or a combination of these.

Figure 3 shows a transverse cross-section of the design of the breeding basin B according to Figure 1, where it can be seen that several sets of buoyancy and/or ballast elements 49 are arranged around an outer circumference of the breeding basin B, so that the position of the buoyancy basin B in the sea can be controlled.

An alternative embodiment of the rearing basin B is shown in Figure 4, where the rearing basin B in this case only comprises two curved ends 1, 2. A dividing wall 6 is designed to have the same starting and ending point. A delimited volume V will then be formed within the partition 6, where this delimited volume can be used for medicinal treatment of fish, deworming of fish, etc.

Alternatively, the rearing basin B can be designed open in this area, where the rearing basin B in this case will comprise the volume delimited by an inside of the curved ends 1, 2 and an outside of the continuous partition wall 6. One transverse strut 4A is used to stiffen the partition wall 6, as an upper end of the partition wall 6 will then be connected to the transverse strut 4A, while a lower end of the partition wall 6 will be connected to an inside of the rearing basin B.

Figure 5 shows the breeding basin B according to Figure 1, whereby the design of the breeding basin B is not repeated herein. In this embodiment, a sliding bulkhead 7 is arranged between the partition wall 5 and an inside of the long wall 3. The sliding bulkhead 7 can be used to squeeze fish together within a part of the breeding pool B, for example to sort fish, to transfer fish to a new breeding pool (not shown), or also when slaughtering fish. The sliding bulkhead 7 can then be used with one or more nets (not shown) which are lowered into the rearing pool B.

In order to be able to move the sliding bulkhead 7 around the entire circumference of the rearing pool B, a continuous rail 9 is arranged on the inside of the curved ends 1, 2 and the long sides 3, 4, while corresponding continuous rails 8, 13 are arranged around the entire outer circumference of the partition wall 5, where a continuous rail 8 is arranged at an upper end of the partition wall 5 and a continuous rail 13 is arranged at a lower end of the partition wall 5.

The sliding bulkhead 7 will then be designed with three fastening devices 10, 11, 12, which fastening devices are used to connect the sliding bulkhead 7 to the continuous rails 8, 9.

Figure 6 shows a cross-section of the breeding pool B according to Figure 5, where it can be seen that the continuous rail 9 is arranged in an upper area of the curved ends 1, 2 and the long sides 3, 4. A continuous rail 8 is similarly arranged in a upper area of the partition wall 5, while a further continuous rail 13 is arranged in a lower area of the partition wall 5. The sliding bulkhead 7 will then be designed with fastening devices 10, 12 in its upper area and a fastening device 11 in its lower area. The fastening devices 10, 11, 12 are arranged essentially flush with the rails 8, 9, 13, so that the sliding bulkhead 7 can be connected to the breeding pool B through the fastening devices 10, 11, 12 and the rails 8, 9.

The fastening devices 10, 11, 12 can have a number of alternative designs, but all are designed so that the fastening devices 10, 11, 12 can be displaced in the longitudinal direction of the continuous rails 8, 9, 13 while at the same time being held firmly in the continuous rails 8, 9 on across the longitudinal direction of the continuous rails 8, 9, 13, both in sections which are straight and in sections which are curved.

Although it is not shown in figures, it is to be understood that the breeding basin is designed with a number of intakes for water, so that water can be supplied to the breeding basin. The intakes are then connected to devices for filtering water, supplying oxygen or similar. Alternatively, pumps etc. can be used to supply water to the breeding pool. In a similar way, the breeding pond could be designed with one or more outlets for water, separate outlets for contaminated water, where these can further be connected to various cleaning devices etc. Alternatively, a purification plant could be connected to the breeding pond, so that the water in the breeding pond is cleaned and is returned back to the breeding pool. A professional will know how this can be done and it is therefore not described further here.

A first embodiment of fastening devices 10, 11, 12 and rails 8, 9, 13 is shown in Figure 7, in a cross-section, where a fastening device 10, 11, 12 comprises a slide 14 which is connected to an arm 16. The arm 16 can in a suitable way is connected to the sliding bulkhead 7, for example through a plurality of bolts and nuts, screws etc. This is not described further here, as a person skilled in the art will know how this should be done.

The rail 8, 9, 13 comprises a holding and guiding device 15 for the slide 14, where the holding and guiding device 15 is designed with a groove or slot 18 that runs over the entire length of the rail 8, 9, so that the arm of the fastening devices 10, 11, 12 16 and slide 14 can be moved freely in the longitudinal direction of the rail 8, 9.

The rail 8, 9, 13's holding and guiding device 15 is further connected to an arm 15A designed with a flange, so that the rail 8, 9, 13 can be connected to an inside of the curved ends 1, 2 by means of a number of brackets 17 and to the long sides 3, 4, and to an outside of the partition wall 5. The brackets 17 are arranged at a distance from each other and are attached to the curved ends, long sides and partition wall by means of screws, bolts and nuts or equivalent.

Figure 8 shows a longitudinal section of a rail 8, 9, 13 which is connected to a fastening device 10, 11, 12 as described above.

Figures 9 and 10 show an alternative embodiment of a rail 8, 9, 13 and fastening devices 10, 11, 12 which are connected to the rail 8, 9, where Figure 9 is a longitudinal section of the rail 8, 9, 13 and fastening devices 10, 11 , 12, seen from the side, and figure 10 is a longitudinal section of the rail 8, 9 and fastening devices 10, 11, 12, seen from above.

In this embodiment of rail 8, 9, 13 and fastening device 10, 11, 12, the fastening device 10, 11, 12 comprises two horizontal wheels 19 which roll horizontally inside the rail 8, 9. The two horizontal wheels 19 are connected to an axle 22, where the shaft 22 is further connected in a suitable way to an arm 21. The arm 21 can be connected in a suitable way to the sliding bulkhead 7, for example through a plurality of bolts and nuts, screws etc. This is not described further here, as a person skilled in the art will know how this must be done.

The rail 8, 9, 13 comprises a holding and guiding device 20 for the two horizontal wheels 19, where the holding and guiding device 20 is designed with a groove or slot 23 that runs over the entire length of the rail 8, 9, so that the fastening devices 10, 11 , 21 arm 16 and two horizontal wheels 19 can be freely moved in the longitudinal direction of the rail 8, 9. The arm 21 will then extend from the holding and guiding device 20 through the slot or slot 23.

A further alternative embodiment of a rail 8, 9 and fastening devices 10, 11, 12 which are connected to the rail 8, 9 is shown in Figure 11, where the fastening device 10, 11, 12 comprises two vertical wheels 24, 25 which ensure that the fastening device 10 .

A horizontal wheel 27 will then ensure that the fastening device 10, 11, 12 cannot be pulled out of the holding and guiding device 26 when the sliding bulkhead 7 is moved in the longitudinal direction of the rail 8, 9.

A motor 28 is also mounted on the fastening device 10, 11, 12 which will drive a gear wheel 29 which is designed to cooperate with a rack 30 which is connected on an upper side of the holding and guiding device 26. Between the motor 28 and the gear wheel there is arranged a vertical wheel 25, where a shaft connecting motor 28 and gear 29 will run through the wheel 25. The wheel 25 will not be driven by the shaft, but is allowed to roll freely.

The motor 28 can be hydraulically, electrically or pneumatically driven.

Another embodiment of rails 8, 9 and fastening devices 10, 11, 12 which are connected to the rail 8, 9 is shown in Figures 12 and 13, where the fastening devices 10, 11, 12 also in this embodiment comprise a motor 28. Figure 12 shows a cross-section seen from the front, while figure 13 shows a longitudinal section of the rail 8, 9 and fastening devices 10, 11, 12, seen from the side.

The motor 28 will be connected to a gear wheel 29 through a shaft.

The gear wheel 29 rests against the rack 30. The gear wheel 29 is held in position by the fact that guide plates 37 are mounted on each side of the gear wheel 29 and by the fact that the weight of the sliding bulkhead 7 is carried in whole or in part by the gear wheel 29 which rests on the rack 30. The guide plates 37 have a diameter significantly larger than the toothed wheel 29 to ensure that this is not displaced horizontally out of the rack 30.

The motor 28 can be hydraulically, electrically or pneumatically driven.

Figures 14 and 15 show designs for the sliding bulkhead 7, where the sliding bulkhead 7 is shown without the fastening devices 10, 11, 12 for the sake of simplicity. The sliding bulkhead 7 comprises an outer rigid frame 31, where a latticework 32 made of metal or a notlin. The grating 32 is designed with such small openings that fish cannot penetrate, while water is allowed to flow freely through.

The rigid frame 31 is designed so that the grating 32 can easily be replaced with another grating which is designed with larger or smaller openings, whereby the sliding bulkhead 7 can be used for sorting fish.

Figure 15 shows that brushes can be connected to the parts of the sliding bulkhead 7 that are under water when the sliding bulkhead 7 is connected to the rails 8, 9 in the rearing pool B, where the brushes 33 are designed to be brought into contact with the inner surfaces of the rearing pool B. The brushes 33 will, by moving the sliding bulkhead 7, coat and scrub the inside of the pool channel. By pulling the sliding bulkhead 7 around the entire pool channel, the brushes 33 will loosen growth that can settle on the sides.

In this way, the pool channel will be kept clean. In order to reduce the load on the fastening devices 10, 11, 12 as described in connection with figures 5 and 6, an upper edge of the sliding bulkhead 7 can be equipped with buoyancy bodies 34 so that the sliding bulkhead 7 essentially hangs down from these buoyancy bodies 34 and reduces the load on the fastening devices 10 , 11, 12 and rails 8, 9 and 10

Figures 16A-16E show an embodiment of the breeding pool B according to the present invention, where two sliding bulkheads 7, 35 are arranged in the breeding pool B. The sliding bulkheads 7, 35 can be used to squeeze fish together in a pool channel as described in relation to Figure 1. Figure 16A shows the location of the sliding bulkheads 7, 35 close to each other in a freely chosen position along the continuous pool channel. The sliding bulkhead 7 is fixed while the other sliding bulkhead 35 is pulled between the pool channel walls 3 and 4 around the entire length of the pool channel. Figure 16B shows the position of the sliding bulkheads 7, 35 when sliding bulkheads 35 are pulled around a 180 degree arc in the pool channel. The further figures 16C-16E show the position of the sliding bulkhead 35 as it is moved around in the pool channel, resulting in the fish being displaced in front of the sliding bulkhead 35 and gradually squeezed more against the sliding bulkhead 7 which is in a fixed position during the operation. In Figure 16E, the sliding bulkhead 35 has been guided around the entire pool channel and has squeezed the fish together into a small area located between the two bulkheads 7, 35. The fish can now be picked up for sorting, moving etc.

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 breeding pool for breeding fish as described within the scope of the invention as defined in the appended claims.

Claims (9)

PATENT CLAIMS 1. Breeding basin (B) for breeding fish, where on the inside of the breeding basin (B) there is arranged at least one rail (9) continuously around the entire inner periphery of the breeding basin (B), thus forming a continuous rail for at least one sliding bulkhead (7, 35), characterized in that the rearing basin (B) comprises two curved ends (1, 2) connected by long sides (3, 4), where the curved ends (1, 2) are designed as a double curve and the long sides (3, 4), when assembled/assembled, has a mainly U-shaped cross-section, thus forming an elongated breeding basin (B), where a dividing wall (5) is arranged in or near a center plane that extends over the breeding basin (B) longitudinal length, forms a continuous pool channel in the rearing pool (B), where further on and around an outside of the partition wall (5) is arranged at least one rail (8) for guiding the at least one sliding bulkhead (7, 35), where the at least one sliding bulkhead (7, 35) comprises fastening devices (10, 11, 12) and the rails (8, 9) comprise a holding and guiding device (15), so that they can be connected to each other, which fastening devices (10, 12) comprise two wheels (24, 25) and the holding and guiding device (15) includes a track that runs over the entire length of the rail (8, 9), where the smallest one sliding bulkhead (7, 35), over part of its length, is designed to taper towards one end, thus cooperating with an inside of the rearing basin (B) in order to form a substantially tight connection between the rearing pool (B) and the sliding bulkhead (7, 35) in the continuous pool channel. 2. Breeding pool (B) according to claim 1, characterized in that the dividing wall (5) has at least the same length as the long sides (3, 4). 3. Breeding pool (B) according to claim 1 or 2, characterized in that the dividing wall (5) runs around and parallel to an inner circumference of the breeding pool (B), thus forming a closed configuration of the dividing wall (5). 4. Breeding pool (B) according to one or more of the preceding claims, characterized in that the dividing wall (5) is connected to one or more transverse braces (4A, 4B, 4C), for bracing the dividing wall (5). 5. Breeding basin (B) according to claim 1, characterized in that one or more sets of buoyancy and/or ballast elements (49) are arranged around an outer circumference of the breeding basin (B). 6. Breeding pool (B) according to one or more of the preceding claims, characterized in that the attachment devices (10, 11, 12) further comprise a motor (28) as a hydraulic, electric or pneumatic drive. 7. Breeding pool (B) according to claim one or more of the preceding claims, characterized in that the sliding bulkhead (7, 35) comprises a rigid frame (31), to which rigid frame (31) a grating (32) is connected. 8. Breeding pool (B) according to one or more of the preceding claims, characterized in that brushes (33) are connected to the rigid frame (31) of the sliding bulkhead (7, 35), at least around part of it. 9. Breeding pool (B) according to one or more of the preceding claims, characterized in that one or more buoyancy bodies (34) are connected to an upper edge of the sliding bulkhead (7, 35).