NO20171340A1 - FARMING DEVICE - Google Patents

Abstract

Breeding facility (100) comprising a fish tank (1), an outlet pot (2) arranged in a bottom (1a) of the fish tank (1), where the outlet pot (2) has a recess (3) which forms a fluid channel (3') and a outlet (4) arranged at a downstream end of the fluid channel (3).

Description

DEVICE AT BREEDING FACILITIES

The present invention relates to a device at a breeding facility, more specifically a breeding facility for breeding marine organisms such as fish.

BACKGROUND

Aquaculture as an industry has grown significantly in recent years, and there is potential and political will for continued growth in this industry. In aquaculture facilities, it is important to keep control of the water quality in the facility, both with regard to fish welfare, disease prevention and production efficiency. There is therefore a continuous need for new and improved solutions for water control, water purification and the like for aquaculture facilities.

Examples of prior art that may be useful for understanding the background include US 2017/071142 A, US 2010/031893 A, US 2012/125940 A, WO 03/086066 A1 and US 2005/120970 A.

The purpose of the present invention is to provide a breeding facility that exhibits advantages over prior art in at least one of the above-mentioned areas.

SUMMARY

The invention provides a breeding facility comprising a fish tank, an outlet pot arranged in a bottom of the fish tank, where the outlet pot has a depression which forms a fluid channel and an outlet arranged in a downstream end of the fluid channel. The outlet can be arranged between a first wall and a second wall, where the first and second walls define the fluid channel. The fluid channel (3') can be curved. In one embodiment of the invention, the fluid channel has a lower wall which extends with a gradually decreasing height in relation to the bottom towards the outlet.

In one embodiment of the invention, the breeding facility comprises a fluid regulation unit arranged to regulate a fluid flow through the outlet. The fluid control unit can be arranged upstream of the outlet or downstream of the outlet.

In one embodiment of the invention, the breeding facility comprises a strainer arranged between the fish tank and the recess or in the recess. The strainer is at least partly flush with the bottom. The strainer has a pocket, the pocket may be arranged at least partially in the recess.

In one embodiment of the invention, the fluid regulation unit is a hatch or valve arranged in the strainer. The hatch or valve may be arranged in the pocket.

In one embodiment of the invention, the outlet is a first outlet, and where the outlet pot further comprises a second outlet. The fluid channel partially or completely encloses the second outlet. A valve unit is provided in the second outlet.

In one embodiment of the invention, the breeding facility comprises a pusher unit arranged above the outlet pot, where the pusher unit comprises at least one paddle and is rotatably arranged to guide particles on the bottom towards the depression. At least one paddle is driven around by the water rotation in the fish tank. In one embodiment, at least one vane is driven around by a motor.

In one embodiment of the invention, the breeding facility comprises a sensor arranged to identify and give a signal indicating a quantity of dead fish in or near the outlet pot. In one embodiment of the invention, the breeding facility comprises an actuator arranged to control the fluid regulation unit based on the signal.

BRIEF DESCRIPTION OF THE DRAWINGS

Examples of embodiments of the invention will now be described with reference to the attached drawings, where

Figures 1 and 2 show a breeding facility according to one embodiment, and

Figure 2-10 shows details around breeding facilities according to embodiments of the invention.

DETAILED DESCRIPTION

Figures 1 and 2 show a breeding facility 100 according to one embodiment. The breeding facility 100 comprises a fish tank 1. An outlet pot 2 is arranged in a bottom 1a of the fish tank 1. In this embodiment, the outlet pot 2 is arranged centrally in an essentially circular fish tank 1, but the outlet pot 2 can also be arranged in another position or the may be arranged more than one outlet pot 2 in a given fish tank 1. A walkway 37 is arranged above the fish tank 1, for example for an operator to inspect from above the fish tank 1 itself and the fish in the fish tank 1.

From the outlet pot 2, a first drain pipe 38 runs under the fish tank 1 and to a process unit 40. The process unit 40 can be a so-called "dead fish box" or drain box for treating waste water containing pollutants and/or dead fish. The first drain pipe 38 can thus be used for extracting water with particle content from the fish tank 1 (for cleaning) and/or extracting dead fish. In this embodiment, a second drain pipe 39 also leads from the outlet pot 2. The second drain pipe 39 can, for example, be arranged for the removal of live fish for transfer to a well boat.

Figure 3 illustrates the outlet pot 2 in more detail. The outlet pot 2 has a recess 3 which forms a fluid channel 3', and an outlet 4 arranged at a downstream end of the fluid channel 3'. The outlet 4 is connected to the first drain pipe 38. A first wall 5 and a second wall 6, together with a lower wall 7, define the fluid channel 3'. In this embodiment, the lower wall 7 extends with a gradually decreasing height in relation to the bottom 1a towards the outlet 4. The lower wall 7 can for this purpose follow an inclined and/or spiral path. Alternatively, the wall 7 can follow a different path, for example, the wall 7 can be arranged with gradually decreasing height.

In this embodiment, the outlet pot 2 has a second outlet 20 connected to the second drain pipe 39. In the embodiment shown in Figure 3, the second outlet 20 is arranged centrally in the outlet pot 2 so that the fluid channel 3' partially or completely encloses the second outlet 20. The second outlet 20 can in normal operation be shut off by a valve unit 21 (see Figures 6 and 7) which can be opened or removed when use of the second outlet 20 is desired, for example when moving fish to a well boat.

Figure 4 shows an alternative embodiment of the outlet pot 2. In this embodiment, the outlet pot 2 does not have a second outlet as described above, and the recess 3 which forms the fluid channel is straight. The recess has a gradually decreasing height towards the outlet 4, in the same way as above. Alternatively (or in addition) the sides 14a,b can be sloping downwards towards the recess 3.

In use, particles, such as feed residues and excrement, as well as dead fish will collect in the bottom 1a of the fish tank 1, and in the outlet pot 2. These can then be removed by setting up a fluid flow through the outlet 4. This fluid flow can be continuous or periodic . An advantage of the solution according to the embodiments described here is that you can achieve a more efficient removal of e.g. particles, at a lower partial flow through the outlet 4. You can then use a side drain or equivalent in the fish tank 1 for the main part of the water exchange. This can be advantageous, for example, due to easier access to the sides of the tank 1, and to be able to better control the water flow so that desired flow conditions are achieved in the tank 1. In a round tank, by setting up a circulating primary flow in the fish tank 1, the water masses will set up a secondary flow that draws particles towards the center of the vessel 1. These will then be able to be captured by the outlet pot 2. Using the fluid channel 3', a relatively small water flow will be necessary to achieve effective removal of particles from the outlet pot 2. For example, 5-20% of the water flow can of the fish tank 1 is taken through the outlet pot 2, while the rest is taken through, for example, a side outlet.

A quick and effective removal of excrement, waste feed, dead fish or other contaminants reduces the need for water purification in facilities with reuse/recycling of water, and the shortest possible residence time in the water for such unwanted components is an advantage for improving the fish's environment and reducing, for example, the risk of infection. The water flow from the outlet pot 2 can be led to a cleaning unit for reuse, or it can be dumped.

In one embodiment, the fluid channel 3' is arranged in a curved, semi-circular or circular design. This offers advantages in that such a shape is complementary to a circulating water flow in the fish tank 1, so that particles etc. settles more effectively in the fluid channel 3'. Alternatively, the fluid channel 3' can have a different shape, for example more or less straight, as illustrated in figure 4.

Figure 5-7 shows an embodiment where a strainer 11 is arranged between the fish tank 1 and the recess 3. Alternatively, the strainer 11 can be arranged (fully or partially) in the recess 3. The strainer 11 is advantageously arranged so that it lies at least partially in flush with the bottom 1a.

The strainer 11 has a pocket 12 which in this embodiment is designed as a recess in the surface of the strainer 11. The recess in the strainer 11 can have completely or partially the same shape and course as the recess 3 in the outlet pot 2, and it can be arranged so that it extends partially down into the recess 3 in the outlet pot 2, as illustrated in Figures 5 and 6.

The strainer 11 means that larger elements, for example dead fish, are stopped by the strainer 11 and collect at a desired location in or around the outlet pot 2, for example for easy and efficient removal of this. A recess / pocket 12 in the strainer 11 can be advantageous for this.

The breeding facility 100 can further comprise a controllable hatch or valve which can adjust/regulate a fluid flow through the outlet 4. The hatch or valve can be arranged upstream of the outlet 4 or downstream of the outlet 4.

In the embodiment shown in Figures 5 and 6, a hatch 10b arranged at the end of the pocket 12 in the strainer 11 is used. Figure 8 shows an alternative embodiment, where a hatch 10a is arranged downstream of the outlet 4, in the first drain pipe 38. The hatch 10a or 10b can be provided with an activation mechanism to control this. The activation mechanism can be an automatic actuator or a manual mechanism for opening/closing the hatch 10a, 10b. Figure 8 illustrates a possible embodiment, where a band 41 is attached to the hatch 10a and extends through the first drain pipe 38 to an operator station (not shown), whereby an operator can open the hatch 10a by pulling the band 41. The hatch 10a can be spring-loaded so that it closes automatically. Alternatively, an actuator can be arranged to activate the hatch 10a via the band 41, or arranged at the hatch 10a to operate it directly, in response to a signal from an operator.

By using such a hatch or valve, the water flow through the outlet pot 2 can be regulated, for example by the flow being closed and only opened periodically, or that the hatch or valve in its basic position allows a given basic flow which can be increased periodically by opening the hatch or valve . In such an embodiment, one can for example use a small, continuous partial flow for removing particles, and a periodic, higher partial flow for removing dead fish or larger elements. This can result in a more efficient removal of dead fish, as a full opening of the valve or the hatch leads to a high flow that pulls dead fish around the outlet pot 2 and/or in the pocket 12 or the recess 3. When the dead fish has been removed, the valve or the hatch is returned to its original position, whereby the water flow is reduced.

In one embodiment, a sensor 30, illustrated schematically in figure 6, can be arranged to identify and give a signal indicating an amount of dead fish in or near the outlet pot 2, for example in the pocket 12 or in the recess 3 (if strainer 11 does not used). The sensor 30 can give a signal to an operator to activate the hatch 10a, 10b, or be connected to the actuator via a control unit, whereby the control unit automatically controls the hatch 10a, 10b based on the sensor signal. The sensor 30 can be, for example, an IR sensor, camera or any other sensor capable of indicating an amount of dead fish in and around the outlet pot 2.

In one embodiment, illustrated in Figures 9 and 10, a pusher unit 30 is arranged above the outlet pot 2. The pusher unit 30 comprises vanes 31a-d and is rotatably arranged to guide particles on the bottom 1a towards the recess 3. The pusher unit 30 can, for example, be arranged above and/or around the second outlet 20 and the valve unit 21. The sliding unit 30 can be releasably arranged so that it can be removed before the second outlet 20 is to be used, or it can be arranged, for example, around the second outlet 20 so that this is functional also with the slide unit 30 installed. The paddles 31 a-d can, for example, be driven around by the water rotation in the fish tank 1, where a force from the speed of the water acts on the paddles. Alternatively, the vanes 31 a-d can be rotated by a motor.

The push unit 30 can thus "sweep" particles, dead fish or other components towards the outlet pot 2. This ensures that particles etc. are sent out via the outlet pot 2, and can allow an even lower partial flow through the outlet 4 without running the risk of particles etc. being left behind in or around the outlet pot 2 without being dragged out by the water flow.

Claims (20)

CLAIM 1. Farming facility (100) comprising a fish tank (1), an outlet pot (2) arranged in a bottom (1a) of the fish tank (1), where the outlet pot (2) has a recess (3) which forms a fluid channel (3') and an outlet (4) arranged at a downstream end of the fluid channel (3). 2. Breeding facility (100) according to claim 1, where the outlet (4) is arranged between a first wall (5) and a second wall (6), where the first and second walls (5,6) define the fluid channel (3' ). 3. Breeding facility (100) according to one of the preceding claims, where the fluid channel (3') is curved. 4. Farming facility (100) according to one of the preceding claims, where the fluid channel (3') has a lower wall (7) which extends with a gradually decreasing height in relation to the bottom (1a) towards the outlet (4). 5. Farming facility (100) according to one of the preceding claims, comprising a fluid regulation unit (10a, 10b) arranged to regulate a fluid flow through the outlet (4). 6. Farming facility (100) according to the preceding claim, where the fluid regulation unit (10a, 10b) is arranged: upstream of the outlet (4), or downstream of the outlet (4). 7. Farming facility (100) according to one of the preceding claims, comprising a strainer (11) arranged between the fish tank (1) and the recess (3) or in the recess (3). 8. Farming facility (100) according to the preceding claim, where the strainer (11) is at least partially flush with the bottom (1a). 9. Breeding facility (100) according to one of the two preceding claims, where the strainer (11) has a pocket (12). 10. Breeding facility (100) according to the preceding claim, where the pocket (12) is arranged at least partially in the recess (3). 11. Farming facility according to one of the four preceding claims in combination with claim 5, where the fluid regulation unit (10a, 10b) is a hatch or valve arranged in the strainer (11). 12. Farming facility according to claim 5 in combination with claim 9, where the hatch or valve (10a, 10b) is arranged in the pocket (12). 13. Breeding facility (100) according to one of the preceding claims, where the outlet (4) is a first outlet, and where the outlet pot (2) further comprises a second outlet (20). 14. Breeding facility (100) according to the preceding claim, where the fluid channel (3') partially or completely encloses the second outlet (20). 15. Farming facility (100) according to one of the two preceding claims, comprising a valve unit (21) arranged in the second outlet (20). 16. Breeding plant (100) according to one of the preceding claims, comprising a pusher unit (30) arranged above the outlet pot (2), where the pusher unit (30) comprises at least one vane (31a-d) and is rotatably arranged to guide particles on the bottom (1a) against the recess (3). 17. Farming facility (100) according to claim 16, where at least one paddle (31 a-d) is driven around by the water rotation in the fish tank (1). 18. Farming facility (100) according to claim 16, where at least one blade (31 a-d) is driven around by a motor. 19. Farming facility (100) according to one of the preceding claims, comprising a sensor (30) arranged to identify and give a signal indicating an amount of dead fish in or at the outlet pot (2). 20. Farming facility (100) according to the preceding claim in combination with claim 5, 6, 11 or 12, comprising an actuator arranged to control the fluid regulation unit (10a, 10b) based on the signal.