NO343380B1 - Improved closed fish farming tank - Google Patents

Abstract

The invention is a fish farming tank comprising the following features: - an ovoid shell (1) having a substantially vertical long axis and gradually tapering towards its upwardly pointing top portion (4); - wherein the shell (1) forms a substantially rigid, closed tank; - wherein the shell (1) has one or more main water inlets (11) to a fish volume (0) and one or more water outlets (16) from the fish volume (0), - wherein the egg-shaped shell (1) is arranged to hold air in its upper tip portion (4) and water in a fish volume (0) down to a ballast (7) in its lower, but end portion (5), - an axially directed central hollow column (2) extending from the upper tip portion ( 4) of the ovoid shell (1) to the lower, but end portion (5); - where the main water inlet (11) is arranged near the bottom (51) of the lower end portion (5), and where the water outlet (16) is at the upper, inner surface of the water in the fish volume (0), - and where the main water inlets (11) is approximately horizontal, tangentially directed so as to establish circular main flow from below and upward through the fish volume (0), - characterized by - a water inlet (10) arranged through the lower portion of the central column (2); and - pumps (12) arranged within the central column (2) and arranged to supply the main water inlet (11) to the fish volume (0).

Description

Improved closed fish farming tank

Introduction

The present invention relates to a fish breeding tank comprising an egg-shaped shell (1) with a mainly vertical long axis and a gradually tapered shape towards its upwardly pointing tip part (4). More specifically, it relates to such an egg-shaped tank with an axially directed, substantially vertical, central tube column extending from the upper tip portion of the egg-shaped shell to a lower, wider end portion of the egg-shaped shell. There is arranged a main water inlet to a rearing volume to the rearing volume near the bottom of the lower end part, in or just above the ballast, and where the water outlet from the rearing volume is at the upper, inner surface of the watered rearing volume, and where the main water inlets (11) are approximately horizontally, tangentially directed so that a circular main flow is established from below upwards through the farming volume. Pumps are preferably arranged close to but below the water surface, inside the tubular vertical column so that one has close access to them from above. In one embodiment of the invention, an integrated purification system for the outlet water from the rearing volume is arranged, for example, as rotating filter drums, alternatively as cyclone separators, placed in the floating ring around the tip of the egg's shell.

Background technology

Fish farming is usually carried out with the fish enclosed in cages comprising a float ring and a closed groove hanging down from the float ring. The fish are fed inside the cage and water flows quite freely through, depending on the natural current in the sea. Salmon farming is significantly and increasingly affected by salmon lice, for many reasons, among other things due to the increasing amount of available salmon in cages, as well as the salmon lice's adaptability and increasing drug resistance, as well as infection between cages and fish farming facilities. The salmon louse's Latin name is Lepeophtheirus salmonis. There are also other types of lice that can eat the salmon, such as lice. the so-called Scot louse Caligus elongatus. Incidentally, there are many subspecies. Typical of Lepeophtheirus is that the infective stage of the louse, the louse larvae, is found in the upper 20 meters of the sea. Of this, a water intake of less than 25 meters will eliminate almost all infection. In contrast, barnacle lice and salmon lice in Chile can be found deeper and can enter below 25 metres. Everywhere, lice are an important carrier of viruses and other pathogens. It is therefore incredibly important to keep this out.

JP patent publication JP06276887 Riichi filed 25/03/1993 describes a balloon that constitutes a sealed, inflated, submerged soft-shell fish farming container. It is kept stretched out due to its internal air pressure at the top, and the internal water surface is thus lower than the sea surface. It drains from the bottom out via an outlet hose and has a floating top, as well as a separate water treatment plant.

WO2017026899 belonging to the applicant himself describes the problems surrounding salmon lice in detail and presents a solution to many problems by proposing a fish breeding tank comprising the following features:

- an egg-shaped shell (1) with a mainly vertical long axis and a gradually tapering shape towards its upwardly pointing tip part (4);

- where the shell forms an essentially rigid, closed tank

- where the shell has one or more water inlets and one or more water outlets,

- where the egg-shaped shell is arranged to hold a volume of water in its lower, wide volume portion and air in its upper volume portion at the tip;

- an axially directed central tube column extending from the upper tip portion of the egg-shaped shell to a lower, wider end portion of the egg-shaped shell, for guiding a vertically running dividing strip; - where at least one main water inlet to a rearing volume is arranged near the bottom of the lower end part directly through the shell (1) wall, and where the water outlet (16) from the rearing volume (0) is at the upper, inner surface of the watered rearing volume ( 0),

- and where the main water inlets (11) are approximately horizontally, tangentially directed

so that a circular main flow is established from below upwards through the farming volume.

In the described patent, the fresh water main intake pumps are arranged directly as separate sections on deep-plunging main intake pipes extending downward from a radially positioned bend to each of their horizontal, tangential main water inlet pipes. The main intake pumps are arranged directly as an integral section on these vertical main intake pipes. The main intake pipes thus extend out through separate openings in the shell and are axis parallel, and not arranged axially. Such an arrangement has several disadvantages: firstly, it may cause an increased moment of rolling inertia in the attachment through the opening of the shell due to the mass of the engine, and may be vulnerable when rolling, secondly, it entails additional passages through the shell for each main intake pipe, and for that third, there is no access from the surface to the pumps in the event of a need for repair, maintenance or replacement of the pumps, and will thus require docking of the entire shell.

The same applies to water intake filters on the main intake pipes.

Brief summary of the invention

The invention is a fish breeding tank comprising the following features:

- an egg-shaped shell (1) with a mainly vertical long axis and gradually tapering shape towards its upwardly pointing tip part (4);

- where the shell (1) forms a substantially rigid, closed tank;

- where the shell (1) has one or more main water inlets (11) and one or more water outlets (16),

- where the egg-shaped shell (1) is arranged to hold air in its upper tip part (4) and water in a rearing volume (0) down to a ballast (7) at the bottom (51) at its lower, blunt end part ( 5), - an axially directed central hollow column (2) extending mainly from the tip part (4) of the egg-shaped shell (1) to the lower blunt end part (5);

- where the main water inlet (11) of a rearing volume (0) is arranged near the bottom of the lower end part (5), and where the water outlet (16) from the rearing volume (0) is at the upper, inner surface of the watered rearing volume (0),

- and where the main water inlets (11) are approximately horizontally, tangentially directed

so that a circular main flow is established from below upwards through the farming volume (0), - characterized by

- a water intake (10) arranged through the lower part of the central column (2);

- pumps (12) arranged inside the central column (2) and arranged to supply water to the main water inlet (11) of the rearing volume (0)

- where the pumps (12) are driven by motors (123) arranged dry above the water surface and its level inside the central column (2).

Put another way, the invention is a fish breeding tank with a rigid, closed egg-shaped shell (1) with an upwardly pointing tip part (4) and with a blunt lower end part, and with tangential main water inlets (11) to the rearing volume, where circulation takes place via a water inlet ( 10) arranged through the lower part of an open, axially directed central hollow column (2) which extends from through the tip part (4) to through the lower blunt end part (5), and where the shell (1) having peripheral water outlets ( 16) from the rearing volume (0) out through the shell (1) at the upper, inner surface of the water in the rearing volume (0), so that a mainly helical main flow is established from below upwards through the rearing volume (0), and where pumps (12) arranged inside the central column (2) and arranged to supply water to the main water inlet (11) of the rearing volume (0), and where there is access from above through the central hollow column at least to the pumps (12) and an intake water filter (9 ).

Advantages of the invention

A significant advantage of the invention is that central elements and functions of the breeding tank, such as pumps, inlet channels, pump channels, filters, drainage pipes, anchor lines and disinfection equipment, can be gathered in the axially directed central hollow column, in a manner similar to the way must settle in a petroleum well. Access to these elements can thus take place via the top of the tubular central column (2), either by an external crane or by means of internal winches or hoist arrangements. There are several advantages to collecting central elements and functions inside the column (2) is the crane access from above; you can produce the shell (1) and the column (2) separately from the innards in the column (2), and assemble the innards as a complement at an outfitting yard. The feed in the column (2) can consist of individual components attached separately to the inner wall of the column (2) or in a casing with the necessary recesses and seats/flanges in the column (2). In one embodiment of the invention, components such as pumps, inlet filters, inlet pipes, valves, windlass, etc., can be mounted in one or more completion sleeves which are locked in place from above through the upper opening (201). Regardless of the design, replacement or repair of parts of the innards in the column can easily be carried out via the column (2) without having to make major interventions in the shell (1). Furthermore, a large number of ports and penetrations in the shell (1) can be avoided, which would otherwise require openings and reinforcements of the edges of the shell around the openings, flanges, pipe ends and gaskets. A further advantage of having the entire water supply collected through the central column and in vertical pipes inside this column is that cleaning of mussel and macroalgae fouling in the water supply is simplified: a washing robot can operate in the vertical direction and have essentially the same cross-section of the column ( 2) to clean in its entire height below the waterline. In an embodiment of the invention, such a washing robot can be arranged to be lowered through the opening in the plate (129) for the filter (9) after the filter has been removed, and winched down while it cleans the walls of the column (2) and the pipes (121 ) by flushing or scraping or a combination of these. Such a washing robot can also be lowered all the way down to a bottom filter at the bottom of the column (2) and clean this.

Figure explanation

Embodiments of the invention are illustrated in the attached drawings.

Fig.1 is a drawing and vertical section through an embodiment of the invention. See the location of the vertical section in AA in the horizontal section in Fig.4. A main inlet (10) for fresh water is shown at the base of a vertical, tubular axial column which extends vertically, axially throughout the shell (1) of the fish farming tank, which is egg-shaped. At least pumps (12), water intake filter (9) and supply channels (121) are arranged inside this central axial column (2). the supply channels (121) are connected to tangential main water inlets (11) at the bottom of the rearing volume (0) within the shell (1) and by pumping the water we establish and maintain a helix-shaped upward main circulation of water around the column (2) in the rearing volume (shown by upward helix arrows in the figure), and with water outlet via ports (16) which determine the inner surface inside the shell. The pump pressure contributes to the internal water level being above the level of the sea surface. Thus, the water flows out of the shell to a treatment plant that utilizes the fall of the water for its water transport. A problem with large tanks and vessels for farming is that the water near the center can have a long residence time and thus can accumulate infectious and waste substances and become oxygen-poor. The water is not replaced to the same extent as the surrounding water. In the present invention, the helical flow around the center column will not allow water to remain in the center, but that the circulation is led around the column at a more uniform flow rate than without a center column. In one embodiment of the invention, auxiliary water inlets can be arranged at one or more heights of the supply pipes (121) out through the wall of the center column (2). The water supply through these auxiliary water inlets can be e.g. up to 10% of the total water supply to the farming volume (0) and help prevent the formation of backwaters in the circulating flow through the farming volume. Water level in the lake (Swl), Internal water level (Iwl) and dynamic water level (Diwl) column102 are indicated in the figure.

In one embodiment of the invention, a vertically running and adjustable dividing strip (not shown) is arranged which runs on the outer wall of the vertical column (2) and which is equipped with wings which are arranged to run along the inner wall of the rearing volume (0).

Fig.1b is a perspective drawing and section corresponding to the design in Fig.1 and shows the water flow in through the water intake (10) through the lower end of the tubular column (2), up through the water intake filter (9), out to the water above the pumps (12 ), and down through the half pipes (121) (which are closed at the bottom) and with openings out to the channels through the ballast to the tangential main water inlets (11) to the rearing volume (0).

Fig.2 is another view and vertical section through BB, see Fig.4. an embodiment of the invention, where the cut is 45 degrees to the cut in Fig.1. See the location of the vertical section in the horizontal section in Fig.4. The section shows the liquid outlets via the ports (16) through the shell out to an annular channel (31) to a purification plant (160) placed on a floating ring (3). Sludge tanks for separated solids and any ballast can be arranged in the floating ring (3); purified or filtered water is led to the sea via an outlet (29).

The figure shows a section through the vertical column with the drainage pipe from the sump, and the rotating filter drums after the outlet from the farming volume. The working deck around the column hangs in braces from the roof, which in turn hangs in an inner ring at the tip of the egg.

Fig.3 is a drawing and section through the horizontal plane CC from Fig.1. It shows the ring and struts from which the inner working deck hangs, and provides a top view of a plate (129) below the inner water surface of the tubular column (2) with openings for the centrally located water intake filter (9) and pumps (12). The wing-shaped lobes on the right and left sides around the tip part (4) of the egg are ports through the shell (1) from the deck on the floating ring (3) to the inner working deck which leads on to ports in the tubular column (2). The plate (129) as well as all other objects between the plate (129) and the upper opening (201) in the column's bore are, in one embodiment of the invention, removable so that free access down through the column (2) at least down to the pumps is ensured.

Fig.4 is a horizontal section and outline of the rearing tank from Fig.1 under line D-D. This drawing and section shows the same ports and section of the column (2) and the filter (9) and the pumps (12), as well as a top view of drum filters (162) in the purification plant in the floating ring (3). Here, there is therefore free crane access through the top opening (201) down to the innards in the column (2). The section lines BB for Fig.1 and AA for Fig.2 are also shown here.

Fig.5 is a drawing and section through the horizontal plane DD in Fig.1 and just below the plane CC from Fig.3. This drawing and section shows the same ports and section of the column (2) and filter (9) and pumps (12), as well as horizontal sections through drum filters (162) in the treatment plant. Also shown here is a working deck (40) which hangs from struts and which extends between the ports of the deck on the floating ring (3). There is an inner ring of the working deck in direct connection around the column (2), an annular observation opening, an outer ring of the working deck, as well as an annular outer observation opening down to the farming volume (0).

Fig.6 is a top view of the top of the ballast sections with the ballast and the main water inlets (11) in section EE in the blunt lower part of the egg-shaped shell (1) of an embodiment of the fish farming tank according to the invention. Also shown is the section of the vertical half-pipe profiles of the pipes (121) which extend from the pumps (12) down to the outlets through the wall of the column (2) to the radial inlet channels (11a) to the tangential inlets (11) of the breeding volume (0 ). One of the sections (7c) in the ballast room is shown filled with sand or cement. One or more of the sections can also be ballast water tanks that can be regulated as needed in the event of changed buoyancy conditions. The stronger rotation arrows show water set in rotation during supply.

Fig.7 is a vertical section through part of the upper part of the central tubular column (2) at the level of the working deck with the pumps' motors arranged dry in the working deck level and shows a section through the pumps and motors at the working deck. Above is the part for 201: passage/hatch in top pipe 2.

Fig.8 shows a vertical section and outline corresponding to Fig.1, and here shows an embodiment of the invention equipped with one or more approximately vertically running anchor lines (chain, wire, rope, elastic anchor line) which extends from an anchor windlass (6), preferably with a heave compensator (arranged internally in the upper part of the column (2)), down through the central column (2), here through in one of the channels (121) among what are otherwise the pump channels (121) and equipped with a flush (121B) ) as reinforcement at least in the lower end of the pipe channel (121) around the outlet of the anchor line. The windlass (6) shown in this embodiment is arranged inside the column (2), and the pipe channel (121) is extended up to above the internal water level in the column (2). At the very bottom of the figure, a dashed line is indicated against a single mooring point.

Fig.9 shows a vertical section and outline of an embodiment of the invention with anchor lines down

through the central column (2); the windlass arranged in the tip part (4) outside the pillar (2). In this embodiment, the anchor line runs down through a separate pipe channel (121A) which is in addition to the channels (121) belonging to the pumps (12), inside the column (2).

Fig.10 shows a perspective drawing and section of the same design.

Fig. 11 shows an embodiment of the invention as in Fig. 8, where a simplified diagram shows the cleat (121B) for the anchor line in one of the pump channels (121). In addition, the execution of the alternative design with a separate tube (121A) for the anchor line is shown as in Fig.9 and 10.

Fig. 12a is a horizontal section and view through the tip part (4) in an embodiment of the invention with the float ring (3) showing the main arrangement of the purification plant (160).

Fig.12b is a vertical section through one of the drum filters (162) and an annular drainage channel (31) which leads between the outlets (16) of the drum filters (162).

Fig.12c shows a more detailed top view and section of the drum filter (162) in a section with an outlet for purified water

Fig.12d shows an enlarged section of the sludge belt separator (164).

Fig. 13a and 13b show a partially transparent perspective view of an embodiment of the water intake filter (9).

Detailed description of embodiments of the invention

In what follows, a description of the invention and embodiments of the invention will be given with reference to the attached drawings.

The invention is a fish breeding tank. It includes:

- an egg-shaped shell (1) with a mainly vertical long axis and gradually tapering shape towards its upwardly pointing tip part (4);

- where the shell (1) forms a substantially rigid, closed tank;

- where the shell (1) has one or more main water inlets (11) to a farming volume (0) and one or more water outlets (16),

- where the egg-shaped shell (1) is arranged to contain air in its upper tip part (4) and to hold water in the rearing volume (0) which extends down to a ballast (7) at the bottom (51) in its lower, blunt end part (5),

- an axially directed central hollow column (2) extending from the upper tip part (4) of the egg-shaped shell (1) down through the lower blunt end part (5);

- where the main water inlet (11) to the farming volume (0) is arranged in or near the bottom of the lower, blunt end part (5), and where the water outlet (16) out through the shell (1) from the farming volume (0) is arranged at the upper, the inner surface of the water in the rearing volume (0), and

- where the main water inlets (11) are approximately horizontally, tangentially directed into the farming volume (0) so that a circular main flow is established from below upwards through the farming volume (0), and with

- a water intake (10) arranged through the lower part of the central column (2); and

- pumps (12) arranged inside the central column (2) and arranged to supply the main water inlet (11) to the rearing volume (0).

The central, hollow column (2) is therefore open and thus extends axially through both ends of the egg's shell (1). A lid can be arranged which can be opened over the upper end of the column (2). There will thus be free access, e.g. for crane through the upper opening (201) of the column (2) as shown in Fig.1 but an alternative is internal crane access in addition to the upper opening (201), by a light running crane on a rail that extends through ports in the wall of the column (2) as shown in Fig.7.

In embodiments of the invention, the breeding volume in the shell (1) is between 4500 m3 and 22000 m3 or more. The height of the shell (1) shown in Fig.1 is 26 metres. Other embodiments of the invention can have a height of the egg-shaped shell (1) of between 8 and 60 meters or more. The shell (1) can be made of fibre-reinforced plastic, steel, rotationally wound, or slip-cast concrete.

The water intake (10) via the lower end of the tubular column (2), see Fig.1b, Fig.2 and Fig.6, will in an embodiment of the invention have a continuous water connection up through the central part of the column (10) up to a plate (129) with an opening for the water filter (9) between the pumps (12). Thus, all water that passes in must run via the water filter and out over the pumps.

A tank which in the invention can have a height from tip to blunt end of approx. 26 m as shown in the embodiment in Fig. 1, but in larger embodiments can be 46 m high or more than this. The diameter of the central column is in preferred embodiments between 2.0 and 5.0 m, and in an even more preferred embodiment between 3 and 3.5 m, depending on the size of the shell (1). In the design shown in Figure 1, below the waterline, essentially only the lower passage for the column (2) occurs through the shell (1), which simplifies the process and reduces the time for building the shell (1). A significant advantage of the invention is that central elements and functions of the breeding tank, such as pumps, inlet channels, pump channels, filters, drainage pipes, anchor lines, disinfection equipment can be gathered in the axially aligned central hollow column. Passages for liquid flow are easier to carry out in and out through the wall of the column (2) than through the egg-shaped shell (1) which requires a more complex shape for any passthrough and which would otherwise weaken and weigh down the shell or complicate its production. Access to these elements can thus take place via the top of the tubular central column (2), either by an external crane or by means of internal winches or hoist arrangements. There are several advantages to collecting central elements and functions inside the column (2) is the crane access from above; you can produce the shell (1) and the column (2) separately from the innards in the column (2), and assemble the innards as a complement at an outfitting yard. The inside of the column (2) can consist of individual components attached separately to the inner wall of the column (2). In one embodiment of the invention, components such as pumps, inlet filters, inlet pipes, valves, windlass, can be mounted in one or more completion sleeves which are locked in place from above through the upper opening (201) and fixed at the desired level inside the column (2). In such designs, replacement, maintenance or repair of parts of the innards in the column can easily be carried out via the column (2) without having to make major interventions in the shell (1). Furthermore, a large number of ports and penetrations in the shell (1) can be avoided, which would otherwise require openings and reinforcements of the edges of the shell around the openings, flanges, pipe ends and gaskets. In Figure 1, below the waterline, essentially only the lower penetration of the column (2) through the shell (1) occurs.

In the embodiment of the invention shown in Fig.1, the pumps (12) and their associated motors (123) are mounted below the inner water surface inside the central tubular column (2). In another embodiment of the invention shown in Fig.7, the pumps (12) driven by motors (123) are arranged dry above the level of the water surface inside the central column (2). Fig.7 shows a section through pumps and motors at the working deck, dry-docked motors arranged above wells with drive shafts to the pumps down through well covers. A significant advantage of dry-mounted pump motors is that they stand dry above the water surface and that they are thus directly accessible for inspection; the engines require a much simpler construction in terms of to prevent water ingress, and there is access with a crane from above so that the motors and pumps are accessible for assembly and replacement, either through the upper end of the column (2), see Fig.1, or with an overhead crane as shown in Fig.7.

In one embodiment of the invention, the pumps (12) are arranged at the top of pressure channels (121) which extend down through the central column (2) and out via openings through the wall of the wall of the column (2) to radial inlet channels (12a) to the tangential inlets (11) to the rearing volume (0). This is shown in vertical sections of the tank in Fig.1 and 2; the sections are shown as AA and BB in Fig.4, which is a horizontal section and view under the deck under line DD from Fig.1. The vertical pressure channels (121) down along the wall in the central column (2) are in one embodiment half-pipes with a transition (121T) from the circular flange at the pump (12) to the semi-circular outline at the top of the pressure channel (121). This gives more space in the central cross-section of the column (2) and less friction for the upward flow of water in the column (2), as well as fewer narrow hooks for fouling inside the column (2).

In one embodiment of the invention, a replaceable intake water filter (9) is arranged between the water intake (10) and the intake of the pumps (12), inside the central column (2). The water filter (9) is in one embodiment cylindrical with intake at its lower end and arranged in a central opening in a plate below the water surface internally in the column (2) and where there are flange openings for the pumps (12) around the central opening. The water filter (9) can have outlet openings in the cylinder wall towards the water above and around the pumps. There should be a minimum of water above the pumps and plate, e.g. 1.5 m.

The intake water filter will be the only passage for water from the surrounding lake to the water that is in the breeding volume (0) inside the tank and if this filter is intact and has a sufficiently low filter opening, it will effectively prevent the intake of parasites such as salmon lice. This is a very big improvement over the known technique such as e.g. uses water-permeable louse skirts, with a mesh size of 350 m, arranged around cages and which are open at the bottom, i.e. that you only reduce the amount of louse infestation, you do not prevent it. It is also a significant improvement over hemispherical shell cages which have no roof, and thus allow salmon lice in via sea spray.

In one embodiment of the invention, the water intake (10) comprises an extension pipe (102), see Fig.1, which extends to a desired depth below the lower end of the central tubular column (2) so that water can be taken in from a further desired depth deeper than the depth of the shell (1), to further avoid unwanted organisms if necessary.

Method of operation

The water circulation in the breeding tank according to the invention will be as follows:

- the water enters through the main water inlet (10) at the lower end of the tubular central column (2);

- the water rises through the central part of the column (2) and runs through the water filter (9) and out through the cylindrical wall of the water filter;

- an internal water surface is formed inside the column (2) after the water has passed through the water filter (9); If the diameter of the tubular column (2) is sufficient, e.g. here about 3 m, and the filter has little through-flow resistance, the flow resistance for the rising water will not be significant, and the water surface inside the column (2) in a dynamic flow will be almost equal to the sea surface;

- the water will stand above the pumps (12) to the inner water surface in the column (2), see the water surface outlined in Fig.1. The pumps (12) are arranged below the inner water surface in the column (2). In one version, the motors are arranged above the water surface, above well covers with bushings for the drive shafts of the pumps (12). The motors can also be arranged directly on the pumps (12) as shown in Fig.1 and 2.

- the pumps (12) pump the water down through the pressure channels (121) and out through openings in the wall of the column (2) to the radial inlet channels (11a) and out through the tangential inlets (11) to the rearing volume (0);

- the water flowing out from the tangential inlets (11) will thus establish and maintain a circular water flow, (here shown anti-clockwise) around the outside of the central column (2), and mainly run in a helix-shaped water flow throughout the tank's breeding volume around the pump capacity is set to sufficient, and rise up to the outlets (16) out through the shell (1). The pump's (12) pressure will establish and maintain a higher water level inside the shell (1) than the sea surface (given that the ballasting is correct). This achieves a drop height between the internal water level and the sea surface, see also Fig.1, which is sufficient to drive a water flow via the outlets (16) via the water treatment plant with drum filters (162) to the final outlet (29) to the sea.

Fig. 11 shows an embodiment of the invention as in Fig. 8, where a simplified diagram shows the cleat (121B) for the anchor line in one of the pump channels (121). In addition, the execution of the alternative design with a separate tube (121A) for the anchor line is shown as in Fig.9 and 10.

Fig. 12a is a horizontal section and view through the tip part (4) in an embodiment of the invention with the float ring (3) showing the main arrangement of the purification plant (160), comprising drum filters (162) and a belt sludge separator (164).

Fig.12b is a vertical section through one of the drum filters (162) and an annular drainage channel (31) which leads between the outlets (16) of the drum filters (162). There is an overflow pipe as a bypass from the water level of the drainage channel (31) down to the level of purified water after the drum filter, and an overflow pipe for purified water to the outlet (29) to sea.

Fig.12c shows a more detailed top view and section of the drum filter (162) in a section with an outlet for purified water, and an inlet section from the drainage channel (31) with a higher water level. Wet separated sludge is led via pipes to the sludge belt separator (164) and can be temporarily stored in sludge tanks in the floating ring (3). Such drum filters are also commercial goods.

Fig.12d shows an enlarged section of the sludge belt separator (164) which receives wet separated sludge via pipes from the drum filters (162).

Fig. 13a and 13b show a partially transparent perspective view of an embodiment of the water intake filter (9) here divided into two concentric filters (9o, 9i) where the inner filter (9i) is threaded inside the outer filter (9o). Both are arranged to be releasably mounted in the plate (129) which may have a center hole with a flange with a diameter less than or equal to the inner diameter of the inner filter (9i), where the water flows in axially, and where the water runs out radially through both filters. The filters (9, 9i, 9o) are arranged so that the inner or outer filter can be pulled out and changed separately and independently of each other, so that one advantageously does not risk having a filter-free passage through the plate (129). An internal overhead crane is often used to lift the filters out and in. Inside the filter (9) you can lower disinfecting equipment such as UV radiation equipment that kills parasites; microorganisms such as bacteria, phages, viruses, lice and crustaceans even before the passage into the intake water filter.

In one embodiment of the invention, a separator for larger particles, such as precursor particles, is arranged in the channel (31) between the overflows (16) and the drum filters (162).

In an embodiment of the invention shown in Fig.1, Fig.1b, Fig.2, Fig.6, Fig.8 and Fig.11, an annular sump (8) for dead fish and sediment is arranged around the transition between the tubular column (2) outside and the top of the ballast (7), and where a J-shaped drainage suction pipe (81) extends from the sump (8) into the wall of the tubular column and up inside the column (2) to the surface. The top of the ballast sections is slightly conical with a dip towards the sump (8). In a preferred embodiment of the invention, the pipe connection between the vertical supply channels (121) and the main water inlets (11) is arranged inside and through the ballast sections (7, 7c) with the mouths for the main water inlets (11) arranged as horizontal elliptical openings flush with the top of the ballast sections ( 7, 7c), see Fig. 1, 9a, 9b.

In one embodiment of the invention, the breeding tank is equipped with an anchor windlass (6) arranged in the tip part (4) and with one or more approximately vertically running anchor lines (chain, wire, rope, elastic anchor line) which extends down through the central column (2), either in one of the channels (121) among the pump channels (121) or in a separate pipe channel (121A) and equipped with a spigot (121B) as reinforcement at least in the lower end of the pipe channel (121, 121A) around the outlet of the anchor line, and with mainly vertical anchoring to the seabed. An advantage of having a vertical anchor that extends down through the lower end of the column (2) and down to an anchoring point on the seabed is that the length of anchor lines can be significantly reduced compared to having a star arrangement of anchor lines from the floating ring , which could otherwise require several kilometers of anchor lines in total, and that such a star arrangement would otherwise have blocked large parts of the sea and the seabed and thus prevent ordinary fishing such as trawling around the breeding tank. As an anchor, you can use bolts driven into solid rock, plumb bob or suction anchors.

Water exchange system for fresh water when de-liceing

In one embodiment of the invention, a flexible hose (92) with a fresh water supply can be connected from shore to the rearing tank to replace the entire tank's seawater with fresh water to kill salmon lice while the salmon tolerates fresh water. This flexible hose (92), see Fig.9a can be connected to the space inside the column (2) outside the water filter or through the top of the water filter (9) and over the plate (129), with a higher pressure than the water that otherwise rises through the inlet (10) at the bottom of the column (2) so that the pumps (12) drive fresh water into the breeding volume (0). To return to normal seawater circulation, only the fresh water supply is disconnected.

Claims (22)

Patent claims 1. A fish breeding tank comprising the following features: - an egg-shaped shell (1) with a mainly vertical long axis and gradually tapering shape towards its upwardly pointing tip part (4); - where the shell (1) forms a substantially rigid, closed tank; - where the shell (1) has one or more main water inlets (11) to a farming volume (0) and one or more water outlets (16) from the farming volume (0), - where the egg-shaped shell (1) is arranged to hold air in its upper tip part (4) and water in a rearing volume (0) down to a ballast (7) in its lower, blunt end part (5), - an axially directed central hollow column (2) extending from the upper tip part (4) of the egg-shaped shell (1) to the lower blunt end part (5); - where the main water inlet (11) is arranged near the bottom (51) of the lower end part (5), and where the water outlet (16) is at the upper, inner surface of the water in the farming volume (0), - and where the main water inlets (11) are approximately horizontally, tangentially directed so that a circular main flow is established from below upwards through the farming volume (0), - characterized by - a water intake (10) arranged through the lower part of the central column (2); and - pumps (12) arranged inside the central column (2) and arranged to supply the main water inlet (11) to the rearing volume (0), where the pumps (12) are driven by motors (123) arranged dry above the water surface and its level inside the the central pillar (2). 2. The fish farming tank according to any of the above requirements, - where the pumps (12) are arranged at the top of pressure channels (121) which extend down through the central column (2) and with openings out to radial inlet channels (11a) out to the tangential main water inlets (11) to the farming volume (0 ). 3. The fish farming tank according to any of the above requirements, - where a replaceable intake water filter (9) is arranged between the water intake (10) and the intake of the pumps (12), inside the central column (2). 4. The fish breeding tank according to any of the above requirements, - where the pumps (12) and the water filter (9) are arranged with their intakes close to below the water surface inside the central column (2). 5. The fish breeding tank according to any of the above claims, comprehensively - that the tubular central column (2) has a passage (201) with substantially the same diameter as the column (2) itself, vertically upwards through the tip part (4) of the shell (1). 6. The fish breeding tank according to any of the above requirements, with a float ring (3) arranged at and below the top part of the shell (4) and equipped with an annular drainage channel (31) which leads to a water purification plant (160) and further to the outlet (29) for the purified water to the sea. 7. The fish breeding tank according to the preceding requirement, - where the water purification system (160) comprises a rotating drum filter (162) 8. The fish breeding tank according to claim 6 or 7, where the rotating drum filter (162) is arranged to send the separated wet solids on to a sludge belt separator (164). 9. The fish breeding tank according to any of the above requirements, - where the water intake (10) comprises an extension pipe (102) which extends to a desired depth below the lower end of the central tubular column (2). 10. The fish farming tank according to any of the above requirements, - where the pumps (12) below the water surface have drive shafts (122) which extend from motors (123) placed above the water surface, preferably where the drive shaft extends through a well cover under a working deck. 11. The fish farming tank according to any of the above requirements, - where ballast (7) is arranged at the bottom of the blunt end (5) of the shell (1) and around the column (2). 12. The fish farming tank according to any of the above requirements, - where an annular floating collar (3) is arranged around the upper tip part of the shell (4). 13. The fish farming tank according to any of the above requirements, - where a water purification system (160) is arranged in the annular float collar (3), where the water purification system has an inflow channel (161) from the outlets (16) to the inside of one or more horizontally aligned rotating drum filters (162), collectors for separated material from the filter drums inside, and with an outlet for purified water from the outside of the rotating filter drums (162) to the water outlet (29) to the sea. 14. The fish farming tank according to any of the above requirements, - where the shell (1) below the external waterline is essentially continuous and without penetrations except for the column (2). 15. The fish farming tank according to any of the above requirements, - where the farming volume in the shell (1) is between 4500 m3 and 22000 m3 or more. 16. The fish farming tank according to any of the above requirements, - where an annular sump (8) for dead fish and sediment is arranged around the transition between the outside of the tubular column (2) and the top of the ballast (7), and where a J-shaped drainage suction pipe (81) extends from the sump (8) into through the wall of the tubular column (2) and up inside the column (2) to the surface. 17. The breeding tank according to any of the above claims, equipped with an anchor winch (6) arranged in the tip part (4) and with one or more approximately vertically running anchor lines that extend down through the central column (2), in a separate pipe channel (121A) and equipped with a spigot (121B) as reinforcement at least at the lower end of the pipe channel (121, 121A) around the outlet of the anchor line, and with mainly vertical anchoring to the seabed. 18. The breeding tank according to claim 17, with the windlass (6) arranged in the upper part of the central column (2). 19. The fish farming tank according to any of the preceding claims, where an intake water filter (9) is cylindrical with intake at its lower end and arranged in a central opening in a plate (129) below the water surface internally in the column (2). 20. The fish breeding tank according to claim 19, where the intake water filter (9) has outlet openings in its cylinder wall towards the water above the plate (129) and towards the surrounding intake for the pumps (12) which surround the intake water filter (9). 21. The fish breeding tank according to any one of the preceding claims, wherein the intake water filter (9) is divided into two concentric filters (9o, 9i) where the inner filter (9i) is threaded inside the outer filter (9o), and both are arranged to be mounted releasably in the plate (129) in a center hole with a flange with a diameter less than or equal to the inner diameter of the inner filter (9i), where the water flows in axially, and where the water runs out radially through both filters. 22. The fish breeding tank according to any of the preceding claims, with two or more separate ballast sections (7c) arranged as sectors around the pillar (2), where the ballast is cement, pumpable sand slurry or water exchangeable via ballast pumps with inlet pipes via the inside of the pillar (2).