RU2760773C2 - Fish hatchery and method for air supply and water circulation in fish hatchery - Google Patents

Abstract

FIELD: fish farming.

SUBSTANCE: fish hatchery (10) includes floating hoop (12) with net (14), wherein the upper section of net (14) is closed by gate (16) against lice that passes partially downward along net (14). A method includes stages, at which compressed air is supplied to the lower part of net (14), ascending water flow is formed of air bubbles (30) and water from net (14), as well as water sucked into net (14) from the surrounding sea, wherein water is sucked in net (14) from the surrounding sea in a passage section under gate (16) against lice. The supply of compressed air to the lower part of net (14) is carried out in a section adjacent to lower ring (22) and remote from the center of net (14). Water release to the surrounding sea is carried out in a section above gate (16) against lice, wherein water is released to the surrounding sea through slit (20) between gate (16) against lice and floating hoop (12).

EFFECT: group of inventions provides for the prevention of louse penetration to fish hatchery.

17 cl, 3 dwg

Description

The technical field to which the invention relates

The present invention relates to a fish cage and a method for supplying air and circulating water in a fish cage, said fish cage comprising a floating hoop with a net, the upper section of the net being closed by a lice fence that extends partially downwardly along the net. In addition, the fish tank contains an air supply device installed to supply compressed air to the lower part of the network, while the ascending water flow consists of air bubbles and water from the network, as well as water sucked into the network from the surrounding sea, and water is sucked into net from the surrounding sea in a passageway under a lice fence.

Background for the invention

There are a number of issues in the fish farming industry that include lice, spills, environmental emissions, sediment, copper, mortality, land use, HS and operating costs to name just a few.

In addition, in stagnant fjords, the lack of circulation can lead to a lack of oxygen in the water in the fish cage. Sludge from faeces and food debris collect under the unit and it becomes necessary to move the unit.

Lice are a constant problem, especially at high water levels. Lice are most common in the upper layers of water, and the number of lice decreases with increasing depth.

State of the art

JP H03154698 A shows that it is known to form an updraft by supplying a gas containing oxygen to the bottom of a fish cage. The water will be supplied with oxygen and circulated in the hatchery.

US Pat. No. 4,798,168 A discloses a closed fish tank from which it is known to remove excess water through the top of the closed fish tank.

From NO 340270 B1, a method and apparatus is known for changing the top layer of water in fish cages equipped with means to prevent water contaminated with lice from entering the net chamber, for example in fish cages with lice barriers.

The method includes removing water from the upper layers of water using at least one device equipped with a water-repellent device installed in the fish cage, and wherein the removed water is replaced with fresh water that enters the fish cage through or from the lower side of the lice fence.

Document NO 20160386 A1 (corresponds to WO2017155414 A1) discloses a fish culture cage containing a floating hoop that floats on the surface of the water, a net attached to a floating hoop to hold the fish being raised, the net also being attached to a lower ring lowered into the water, and a fence that surrounds the net and that extends down into the water to the area above the lower ring. Several tiltable flow regulators equipped with a floating hoop are rigidly connected to each other and installed within the network, and the corresponding flow regulators comprise an elongated vertical suction pipe with a lower inlet located in the area below the lower edge of the barrier for water intake, and the upper, essentially, a horizontal outlet for distributing water in the upper part of the water body of the network and for circulating the upper part of the water body.

Objectives of the present invention

The present invention provides a semi-closed fish tank with an air system incorporated in the bottom of the fish tank that generates an upward flow. A fish tank may have a closed side and bottom, but has a large opening on the bottom that sucks in water below the typical lice habitat.

The top of the hatchery can have an adjustable narrow slit that lets water in and that can be completely closed from the side exposed to the currents and wind. The entire gap or parts of it can be closed automatically based on the prevailing wind and current conditions. The resulting channel effect effectively creates an upward vertical flow that sucks in fresh water at the bottom and releases water at the top of the hatchery.

An object of the present invention is to provide a fish cage and a method for supplying air and circulating water in a semi-enclosed fish cage to prevent lice from entering the fish cage.

In this way, new fish breeding sites could be found that were not suitable with the existing technical solutions.

The main reason for the supply of air is the formation of circulation with a secondary effect in which some of the oxygen from the air is dissolved in the water. According to the present invention, it is also possible to supply additional oxygen to the air or to use pure oxygen.

Disclosure of the essence of the invention

A preferred embodiment of the method according to the present invention is set forth in the independent claim in which the method is claimed, while alternative embodiments are set forth in the corresponding dependent claims.

According to the present invention, there is provided a method for supplying oxygen and circulating water in a fish cage, wherein said fish cage comprises a floating hoop with a net, the upper section of the net being closed by a lice fence that extends partially downward along the net, the method comprising the steps of: compressed air is supplied to the lower part of the network; form an ascending water stream with air bubbles and water from the network, as well as water sucked into the network from the surrounding sea; moreover, water is sucked into the net from the surrounding sea in a passageway under a lice fence. In addition, the method includes supplying compressed air to the lower part of the network in an area adjacent to the lower ring and distant from the center of the network, and the method also includes releasing water into the surrounding sea in an area above a lice fence, the water being discharged into the surrounding sea through a gap between the lice fence and the floating hoop.

The slot can extend around the hatchery and under the floating hoop, the portion of the slot exposed to the prevailing wind and current conditions being closed.

In order to close the portion of the slot that is subject to the prevailing wind and current conditions, the slot barrage can be raised or lowered.

In an alternative embodiment, to cover the portion of the slot that is exposed to the prevailing wind and current conditions, the slot barrage may be horizontally displaced.

In an alternative embodiment, water can be discharged into the surrounding sea through one or more outlet pipes located below or in a floating hoop. The specified outlet pipes can be opened or closed depending on the prevailing wind and current conditions.

The supply of compressed air to the lower part of the network can be provided by an air supply device in the form of one or more perforated pipes, hoses or plates, which are connected to the air compressor so that ascending air bubbles are formed.

The air supply device can be located at a distance from the center of the network.

The air supply device can be placed near the wall of the network.

In addition, the air supply device can be located near the bottom ring attached to the bottom of the net.

It is preferable that the bottom of the network is covered.

The water flow in the fish tank can be controlled by changing the air supply and / or the slot at the top of the fish tank.

According to a further embodiment, the height of the open section of the net area under the lice fence through which water can flow can be adjusted, and the depth can be selected for sucking water into the net from the surrounding sea.

A preferred embodiment of a fish cage according to the present invention is set forth in the independent claim in which the apparatus is claimed, while alternative embodiments are set forth in the corresponding dependent claims.

According to the present invention, there is also provided a fish cage comprising a floating hoop with a net, the lower part of which is attached to the lower ring, and the lower part of the net is covered by a funnel-shaped part, and the upper part of the net is closed by a lice fence that extends partly downward along the net. In addition, the fish tank contains an air supply device located in a section adjacent to the lower ring and distant from the center of the network, and the air supply device is configured to supply compressed air to the lower part of the network, while the ascending water flow from air bubbles and water from the net, as well as water drawn into the net from the surrounding sea, water being sucked into the net from the surrounding sea in a passageway under the lice fence, and one or more openings to drain water into the surrounding sea in the area above the lice fence.

The air supply device can be one or more perforated tubes, tubes or plates connected to the air compressor to form ascending air bubbles.

The portion of the slot that is exposed to the prevailing wind and current conditions can be closed by raising or lowering the slotted fence relative to the fish cage.

In an alternative embodiment, the portion of the slot that is exposed to the prevailing wind and current conditions can be closed by horizontal displacement of the slot fence around the fish cage.

In addition, the fish tank may contain a water flow sensor and a wind sensor configured to automatically adjust the slotted fence.

The fish cage may also contain a number of sensors in the form of temperature sensors installed outside and / or inside the fish cage, said sensors being configured to regulate the pumping of water into the fish cage.

Brief Description of Drawings

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

Figure 1 depicts a section of a fish farm according to the present invention as viewed from the inside of the fish farm.

Figures 2 and 3 depict a fish cage according to the present invention in an open and partially open position, respectively.

Description of preferred embodiments of the invention

In the present invention, a fish tank is provided in which air enters the bottom and in which an upward flow of water is formed. Water is passed from the side under a traditional lice fence, possibly at the bottom if there is no fixed bottom, and the water is discharged at the top. The lice barrier creates a channel effect that activates the flow of water and prevents lice from entering from the top and sides.

Figure 1 depicts a substantially conventional fish cage 10 with a floating hoop 12 in which a net 14 is hung for raising preferably fish. A lice barrier 16 is positioned around the top of the net 14 to prevent the passage of water that may contain lice. The lower part of the net 14 may be provided with a lower ring 22 and be funnel-shaped 28 which has an outlet 24 for retaining waste.

Lice barrier 16 means a barrier or cover that surrounds and closes the top of the net 14 to prevent water from passing through, or the lice barrier 16 is the closed top of the net 14 to prevent water from passing through.

The anti-lice fence 16 is arranged so that the upper edge lies mainly in the same plane or close to the water surface of the surrounding sea water, and a gap 20 or hole is formed between the anti-lice fence 16 and the floating hoop 12. The net 14 is not covered between the lower part of the lice barrier 16 and the lower ring 22 to form a water passage.

In an area, preferably located below the area through which water can pass, between the lice barrier 16 and the bottom ring 22 is an air supply device 18 in the form of one or more perforated pipes, hoses or plates adapted to discharge compressed air. The pipe or hose may be annular or contain sections that are distributed across the bottom of the fish tank. The air supply device 18 is located off-center of the network, but preferably in a region near or adjacent to the lower ring 22, i.e. also near the network wall 14.

The air supply device 18 is connected to an air compressor, which can, for example, supply compressed air at a pressure of 2-8 bar depending on the depth of the water.

By supplying compressed air to the lower part of the network 14 by means of an air supply device 18, an upward flow of water and air bubbles 30 is provided, as well as water from the network 14 and water that is sucked into the network 14 from the surrounding sea. Air bubbles 30 move through the water as it rises. Water will also be sucked into the net 14 from the surrounding sea in the passage under the lice fence 16 and will help increase the updraft as shown by arrow A in FIG. 1, and then the water will be released into the surrounding sea at the area above the lice fence 16 as shown arrow B in figure 1. This creates a channel effect through which water flows out of the hatchery 10.

The gap formed between the lower part of the lice fence 16 and the lower open part of the net 14, if necessary, can be adjusted so that the depth at which water will be sucked into the net 14 can be selected. lice barriers 16 or other fabric (not shown) is attached to a rope that is lowered into the sea from a floating hoop 12. Using a winch and the specified rope, the lower part of the lice barriers 16 or the fabric can be raised or lowered. If a separate fabric is used, the fabric may be a fully covering fabric, or, alternatively, the fabric that can be raised and lowered may have an annular groove or slit with a hole for water to pass through.

Due to the pressure in the fish cage 10, which is generated by the supplied compressed air and the rising water flow, the surface of the fish cage water will be significantly higher than the surrounding seawater, as a result, the water in the fish cage will overflow and flow out through the slot 20.

The water flow can be adjusted by changing the air supply and / or slot 20 at the top of the fish tank.

On the side of the hatchery 10, which is exposed to the prevailing wind and current conditions, there may be a risk of water entering through the slot 20 from the surrounding sea. Consequently, the slot 20 can be closed to protect against the prevailing wind and current conditions. This can be done, for example, by means of a slotted barrier 26, which is attached to the floating hoop 12 and which can be raised and lowered. The slotted fence 26 may contain several sections that can automatically move up or down to close the slot 20 in the desired area. Alternatively, it is provided that the slotted fence 26 hangs from the floating hoop 12 and can be automatically displaced horizontally so that it covers parts of the slot 20 if necessary, i. E. preferably that part which is subject to prevailing wind and current conditions. The adjustment of the slit can be automatic, in which case the water flow sensor and the wind sensor determine on which side of the fish cage the open slit is located.

By a crevice is meant a cover or cover that can close the crevice 20 if necessary. The fence 26 can be a fabric, a strip of cloth, or rigid plate material positioned to be on the outside, on the inside, or on both sides of the fence 16.

In an alternative embodiment (not shown) a lice barrier 16 may be positioned such that the top edge is attached to a floating hoop 12. Beneath the lice barrier 16 and between the bottom ring 22, the net 14 is open to form an area through which water can flow. To discharge water from the upper part of the fish cage 10, several outlet pipes are located in the floating hoop 12 or under it. If the wind and current conditions are stable enough, it should be considered that only one outlet pipe can be used, but in practice it will be more practical to place several outlet pipes at a distance from each other around the fish cage and they can be opened or closed based on the prevailing wind conditions and currents. Otherwise, the principle of operation and method will be the same as described above.

In addition, the fish tank 10 may contain means for regulating the temperature of the water in the fish tank. For example, sensors in the form of temperature sensors installed outside and / or inside the fish tank 10 can be used to control the injection of water into the fish tank. In summer, the surface water can be too warm, therefore cold water can be pumped from the depths. Regulation can be done by pumping colder water as well as by adjusting the depth for pumping water. In winter, surface water may be too cold and warmer water may be pumped from deep within. Regulation can be done by pumping warmer water as well as by adjusting the depth of water pumping. Such regulation improves the conditions for keeping fish and their growth conditions throughout the year at the highest possible optimum temperature.

Claims (25)

1. A method of supplying oxygen and circulating water in a fish cage (10), wherein said fish cage (10) contains a floating hoop (12) with a net (14), and the upper section of the net (14) is closed by a barrier (16) against lice, which runs partially downward along the network (14), while the method includes the stages at which: supply compressed air to the lower part of the network (14), form an ascending water flow from bubbles (30) of air and water from the network (14), as well as water sucked into the network (14) from the surrounding sea, and moreover, water is sucked into the net (14) from the surrounding sea in the passage area under the barrier (16) against lice, characterized in that the supply of compressed air to the lower part of the network (14) is carried out in a section adjacent to the lower ring (22) and remote from the center of the network (14), and the release of water into the surrounding sea is carried out in the area above the barrier (16) against lice, and the water is released into the surrounding sea through the gap (20) between the barrier (16) against the lice and the floating hoop (12). 2. The method according to claim 1, characterized in that the slot (20) runs around the fish cage (10) and under the floating hoop (12), and the part of the slot (20), which is exposed to the prevailing wind and current conditions, is closed ... 3. A method according to claim 1, characterized in that the part of the slot (20), which is exposed to the prevailing wind and current conditions, is closed by raising or lowering the slotted barrier (26). 4. A method according to claim 1, characterized in that the part of the slot (20) that is exposed to the prevailing wind and current conditions is closed by displacing the slot barrier (26) in a horizontal direction around the fish cage (10). 5. The method according to claim 1, characterized in that the supply of compressed air to the lower part of the network (14) is carried out by means of a device (18) for supplying air in the form of one or more of perforated pipes, hoses or plates that are connected to the air compressor, with the formation of ascending air bubbles (30). 6. A method according to claim 5, characterized in that the air supply device (18) is located at a distance from the center of the network (14). 7. The method according to claim 5, characterized in that the device (18) for supplying air is located near the wall of the network (14). 8. A method according to claim 5, characterized in that the air supply device (18) is located near the lower ring (22) connected to the lower part of the network (14). 9. A method according to claim 1, characterized in that the lower part of the network (14) is closed. 10. A method according to claim 1, characterized in that the water flow in the fish cage (10) is controlled by changing the air supply and / or the slot in the upper part of the fish cage (10). 11. The method according to claim 1, characterized in that the height of the open part of the network passage section (14) under the anti-lice fence (16) is adjusted with the possibility of choosing the water depth for sucking water into the network (14) from the surrounding sea. 12. Fish cage (10) containing a floating hoop (12) with a net (14), which is connected in the lower part to the lower ring (22), and the lower part of the net (14) is closed by a funnel-shaped part (28), and the upper part of the net (14) is closed by a barrier (16) against lice, which runs partially downward along the net (14), while the fish cage (10) additionally contains: a device (18) for air supply, configured to supply compressed air to the lower part of the network (14) with the formation of an ascending water flow from bubbles (30) of air and water from the network (14), as well as water sucked into the network ( 14) from the surrounding sea, and water is sucked into the net (14) from the surrounding sea through the passage section of the net (14) under the barrage (16) against lice, characterized in that the device (18) for air supply is located in the area near the lower ring (22) and remote from the center of the network (14), and in the area above the fence (16) against lice, one or more openings (20) are provided for the discharge of water into the surrounding sea, and the specified one or more openings for the water discharge are an annular adjustable slot (20) provided under the floating hoop (12), moreover, at least part of the slot (20), subject to the prevailing wind and current conditions, is configured to be closed. 13. Fish cage (10) according to claim 12, characterized in that the air supply device (18) is one or more perforated pipes, hoses or plates connected to an air compressor to form ascending air bubbles (30). 14. Fish cage (10) according to claim 12, characterized in that the part of the slot (20), which is exposed to the prevailing wind and current conditions, is made with the possibility of closing by raising or lowering the slot barrier (26) relative to the fish cage (10) ... 15. Fish cage (10) according to claim 12, characterized in that the part of the slot (20), which is exposed to the prevailing wind and current conditions, is made with the possibility of closing by displacing the slot barrier (26) in the horizontal direction around the fish cage (10 ). 16. Fish cage (10) according to claim 14 or 15, characterized in that the fish cage (10) contains a water flow sensor and a wind sensor for automatic regulation of the slotted barrier (26). 17. Fish cage (10) according to claim 12, characterized in that the fish cage (10) contains a number of sensors in the form of temperature sensors outside and / or inside the fish cage (10), while said sensors are configured to regulate water injection into fish tank.

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