NO332589B1 - Floating closed aquaculture facility - Google Patents

Abstract

The invention is a marine fish farm (0) comprising two or more standing tanks (2) for fish farming, with funnel-shaped bottom (3), one or more water supply systems (5, 5b, 18, 19) and one or more drainage systems (14, 15, 16, 17, 9, 9b, 9c) and wherein the tanks (2) are arranged as integral parts of a rigid hull (1) wherein the hull (1) comprises at least an upper rigid main hull (1a) comprising a bow portion (1b), a stern portion (1c), ship sides (25) and a main deck (1h) and the upper rigid main hull (1a) is tight.

Description

Floating closed breeding facility

Introduction

The invention relates to a floating closed breeding facility for the production of farmed fish and for the operation of broodstock stations in the sea, preferably and mainly built in steel. The breeding facility comprises of an elongated, rigid, floating hull with sufficient buoyancy for safe stability, with walkways, tank tops and installation houses for technical equipment, and an underwater hull that includes vertical cylinders acting as fish tanks and a bottom hull that, together with decks, binds the structure together in a rigid floating unit for efficient and environmentally safe fish farming.

Background technology

Farming mainly takes place in floating cages with nets that are open to the surrounding sea and depend on natural currents for the supply of fresh oxygen-rich water and the removal of waste material from fish and offal. In periods of weak current, self-purification and oxygen levels can have unfavorable values for farming. In addition, the fish are also exposed to threats from the surrounding water column with salmon lice, algae, jellyfish and disease transmission. Predators such as birds, seals and otters are also occasionally a problem.

Infection pressure and water quality in open cages is a challenge when operating broodstock stations that manage genetic material for salmonids, through broodstock that are kept for 3 years in the sea for the production of roe for the entire farming industry.

Nuts and collars are also exposed to great mechanical stress, which in some cases leads to damage to cages and nuts with fish escaping as a result. Conventional floating open installations require a lot of inspection and frequent replacement of nuts and steel/plastic constructions and have a relatively short lifespan. Production in the upper water layer means that farmed fish are also exposed to high temperatures in the summer and low temperatures in the winter, which results in weaker growth than would otherwise be achievable.

Waste from the fish and residues corresponding to the amount of biomass produced at the plant are spread to the sea and the seabed. This requires a consistently good current to avoid accumulation of waste materials on the seabed. Accumulation of waste materials will lead to downgrading of the site and floating items. There is currently no practical technology for the collection of waste materials from such floating open facilities.

Localities to be used for farming are today most often located far from land in order to have satisfactory depth and current pattern. These are demanding locations exposed to weather and wind, so that both professional equipment and well-trained crews are required for operation.

Installations located in exposed locations are exposed to extreme stresses and, in periods of bad weather, may be inaccessible for calls by normal personnel boats, without great risk for crews. There will therefore always be a risk of damage occurring to the plant when it is inaccessible or very difficult and dangerous to approach.

US 57 62024 relates to a marine aquaculture facility with sealed tanks. Several tanks can be connected via a work platform. Pumps supply the tanks with water that can be brought in from various ocean depths. The breeding facility has systems for pre-distribution, fresh water intake and oxygenation, removal of solid waste and surplus water.

N0166511 describes a marine, semi-submersible and closable breeding facility. Several silos with lattice hatches can be connected together with a platform. The plant has equipment for supplying fresh water and for removing waste.

NO890779 is an ocean-going vessel operating as a production plant for food fish and other marine animals. The fix is stored in closable containers or the tank spaces that make up the vessel's cargo capacity. The plant is equipped with equipment for the production and distribution of feed as well as systems for monitoring and controlling the environmental conditions in the plant. Fresh water for the tanks can be collected by opening hatches against the external water flow or by pumping this in.

RU2027358 relates to a ship for the transport of live fish. Facilities for water circulation, fresh water intake with a Kingston valve as well as facilities for oxygenation and purification of water are included in the arrangement.

Brief summary of the invention

The invention is a marine breeding facility (0) comprising two or more standing tanks (2) for breeding fish, with a funnel-shaped bottom (3), one or more water supply systems (5, 5b, 18, 19) and one or more drainage systems (14, 15, 16, 17, 9, 9b, 9c) and where the characteristic features are that the tanks (2) are arranged as integral parts of a rigid hull (1) where the hull (1) at least comprises an upper rigid main hull (la ) which comprises a bow section (lb), a stern section (lc), ship sides (25) and a main deck (lh) and where the upper rigid main hull (la) is closed and one or more tanks (2) are arranged with a loose and vertically displaceable raised base (10).

Embodiments of the invention

The invention is a marine breeding facility (0) comprising two or more standing tanks (2) for breeding fish, with a funnel-shaped bottom (3), one or more water supply systems (5, 5b, 18, 19) and one or more drainage systems (14, 15, 16, 17, 9, 9b, 9c) and where the tanks (2) are arranged as integral parts of a rigid hull (1) where the hull (1) at least includes an upper rigid main hull (la) which comprises a bow section (lb), a stern section (lc), ship sides (25) and a main deck (lh) and where the upper rigid main hull (la) is closed and where one or more tanks (2) are arranged with a loose and vertically displaceable raised floor ( 10). The breeding facility, which in one version can have tanks with a cylinder wall depth of 15 m, can regulate volume in the vessels by raising or lowering the internal loose bottom with the help of a winch arrangement. This is particularly advantageous when the fish are small and do not need a lot of space and water consumption can thus be kept to a minimum. In an embodiment of the invention, the rigid hull (1) will preferably be built in steel, but designs in concrete or in GRP or in composite materials or in combinations of these are also possible. The plant will be floating horizontally and can be moored with 4-8 moorings.

The main drainage system (14, 15, 16, 17) is arranged for low friction and resistance and thus low lifting height with filtering of particles before drainage.

A secondary drainage system (9, 9b, 9c) is arranged for interval flushing using compressed air, which enables almost complete collection of waste for further treatment of the collected waste.

A significant advantage of the invention is that the fish in the tanks are kept separate from the external environment on the surface where there is a possible risk of infection for fish diseases, as well as threats from salmon lice fry, algae and pollution such as oil. One will thus be able to avoid one of the biggest problems in the farming industry today, with salmon lice, and as a consequence avoid costly and risky de-lice processes, with reduced feeding and secondary disease. The facility according to the invention will also not contribute to the spread of salmon lice to the surrounding sea and waterways.

In closed tanks, you will also have a very good overview of and control over the disease picture and whether any outbreaks of disease should occur. By e.g. an outbreak of disease, it will be possible to medicate the fish with very precise dosages compared to today's open cages where there is poor control over how much of the medicine is actually taken up by the fish in the cages.

Another advantage of the closed farming facility according to the invention is that the risk of farmed salmon escaping is almost completely eliminated. Preventing escapes is a desired development in order to protect the national wild salmon stocks to the greatest possible extent from interference and pressure from escaped farmed salmon. In one embodiment of the invention, the inside of the wall (2a) of the tank (2) will be made of material of a different and patterned color, preferably light bluish and silver blue so that light is well reflected down through the tanks (2). This is advantageous as good light conditions and color pattern on the inner walls (2a) of the tanks (2) will give the fish growing in the tanks (2) an external quality in skin and color which means that the fish will compete for the best prices in the market.

In an embodiment of the breeding facility (0) according to the invention, channels (40) will be arranged between the tanks (2). The channels (40) between the tanks have the advantage that internal transport of fish at the breeding facility (0) becomes easier when, for example, it is to be split into groups of fish based on size, for example, or when all fish are to be moved from one tank (2) to another tank (2).

In one embodiment of the invention, a counting device and an automatic shutter can be installed so that a counting process can be fully automated.

In an embodiment of the breeding facility according to the invention, the hull (1) comprises at least a dense center hull section (23) with center hull side walls (23a) which extend below central parts of the main hull and which partially enclose the tank's (2)

circumference and connects parts of the tank's side walls (2a) and where the center hull is preferably shorter and or narrower than the main hull (la). An upper tight and rigid hull provides buoyancy, good rolling stability and good, safe working conditions.

In one embodiment of the invention, the hull will be vertically guided between the tanks down to the bottom hull (8) which forms a frame that binds the tanks together and provides a solid structure necessary during construction and docking of the breeding facility (0).

In an embodiment of the breeding facility (0) according to the invention, the tanks (2) are cylindrical or polygonal. The advantage of being able to choose the shape of the tanks (2) is to find the best possible shape with regard to both space utilization, rigidity and water flow in the tanks (2).

An embodiment of the breeding facility according to the invention comprises a bottom hull (8) with bottom hull side walls (8a) which extend mainly vertically as a continuation of the center hull side walls (23a) to below the bottoms (3) of the tanks (2), and is equipped with a main bottom (8b) ) and is designed to be filled with water. Such a construction will result in good bracing for the tanks (2) and thus the overall stability of the farming facility.

In an embodiment of the breeding facility (0) according to the invention, the main bottom (8b) covers at least all of the tank's (2) central bottom point with sluice (9). In this way, the material requirement is reduced while maintaining the strength of the hull at the same time as the drainage system (9, 9b, 9c) is kept within the hull of the breeding facility.

An embodiment of the breeding facility (0) according to the invention will have a main bottom (8a) which has openings for water intake pipes (5c) and preferably closes to these so that the bottom (8a) is not restrictive for the pump wells and the water intake pipes (5c)'s location.

In an embodiment of the breeding facility (0) according to the invention, the tanks (2) are arranged with an upper edge or top (4) that extends above the construction water line and where the tanks (2) are arranged to have a water level that is above the construction water line. In this way, the primary drainage system can function self-regulating based on flow through and the farm's (0) trim, so that it always has a self-correcting effect on the farm's construction.

The plant is basically a flow-through plant, but it is possible to recycle parts of the water in whole or in part, or redeem oxygen in order to reduce pumping costs. In order for the drain to work with little resistance, the level in an embodiment of the invention is placed so that the threshold (17) is approx. 0.6m below sea level, i.e. outside, i.e. the construction water line. The drain has a calculated height of approx. 1.2m where half of the area in the drain is below sea level and the rest above. In one embodiment of the invention, there will be a damper such as a spring-loaded plate which will rise to above sea level if the water outflow decreases and there is no water flow out. Center strainers and filters also provide barriers so that there is no real risk of, for example, the intrusion of pelagic or anadromous fish species. The low lifting height results in low energy requirements. The area of the outlet, here preferably 1.2 x 2m, is calculated on the basis of a maximum imaginary water demand for the illustrated facility, and an outlet speed of 0.5m/s. Such a strong flow will occur rarely. In addition, there will be an element of self-regulation. A tank without flow-through will contain a lower water table and thus raise this tank's side of the facility somewhat, and the threshold will be higher on this side of the vessel. To avoid the ingress of algae or lice, the water intake should never be completely stopped in a tank.

In one embodiment of the breeding facility (0) according to the invention, the tanks (2) have a greater depth than their diameter. In one embodiment of the invention, the breeding facility has a secondary drainage system (9, 9b, 9c) which is designed to separate and transport away dead fish, remains and particles. This can be transported to the deckhouse (6) for sorting and further processing there.

The breeding facility (0) has space and equipment to take care of waste from production and process the waste so that it can be used as a resource. In one embodiment, the breeding facility will have a wastewater treatment system. This means that the facility does not pollute the external environment and that it is therefore possible to put it into use

safer and more sheltered sea locations close to land.

The secondary drainage system (9, 9b, 9C) will in one embodiment be arranged for interval flushing using compressed air, which enables approximately complete collection of waste and further processing of collected waste.

Farming facilities according to one embodiment of the invention can be moored with a fore raft and a raft for collecting residual waste and dead fish, where these are moored to the attached facility instead of this being placed in the deck house (6).

In an embodiment of the breeding facility according to the invention, a flushing system will be arranged at the bottom of the tanks. Control of the drainage systems at the bottom of the tanks must be able to be carried out from the upper deck manually using a rod or similar. The secondary drainage system (9, 9b, 9c) comprises pipes or hoses (9b, 9c) to transport dead fish, offal etc. to a treatment facility (9d) in the stern section (20). Waste, particles and dead fish are filtered out through the secondary drainage system from the bottom of the tanks, which flushes out waste at set intervals in a continuous process, where water is filtered out and the waste is taken care of for further treatment or composting. The waste will also be able to be used in biogas production. The main flood of almost pure waste water is discharged to the open sea through the particle filter and its grate. The particle filter is installed in the drainage channel before the grate and also acts as a secondary safeguard both against escape and intrusion.

In an embodiment of the breeding facility (0) according to the invention, the secondary drainage system (9) on the vertically displaceable raised bottom (10) has a flexible, preferably spiral-shaped hose (9c) for removing waste from the lock (9) arranged in the lower part of the funnel, where waste , particles and dead fish will accumulate during normal operation of the facility. The advantage of this hose (9c) is that it will follow the raised bottom of the tank upwards in cases where it is raised.

An embodiment of the breeding facility (0) according to the invention has one or more telescopically arranged water intake pipes (5c) designed to collect water from depths determined by the temperature and oxygen level in the intake water. The water supply system (5, 5b, 5c) pumps seawater from a deeper water level to obtain very good or nearly optimal conditions for the production of fish in closed tanks. Since the water used is pumped from sea depths between 25m and 50m, pollution at shallower depths between Om and 20m will not affect the fish in the tanks. By retrieving water from deeper layers, the seawater will have a relatively even temperature, and high summer temperatures are avoided. At high summer temperatures, the water will have a lower oxygen content. Low winter temperatures result in reduced feeding and growth. Such very good conditions indicate growth rates beyond what can be expected in open cages, even without regard to disease and salmon lice infestation. With oxygen monitoring as a regulating factor, it will be possible to adapt the pump pattern and flow rate so that no more pump energy is used than necessary. In an embodiment of the invention, depth adjustment of the telescopic water intake pipes (5c) can take place by means of a centered wire in the center of the water intake pipes (5c). The wire can further be connected to the bottom pipe and which runs through the pump well to above deck to a winch arrangement. This arrangement is placed over to the side of the facility with the help of hoists so that the winch itself can be held below deck, for example in a canopy for descent to the center hull. The regulation will initially be manual, but in an embodiment of the invention it can be automatic using a series of temperature and oxygen meters approximately every 5 meters down, at sea depth, which read in values continuously and which can activate the winch so that the intake has an approximately optimal intake depth. In winter, you will probably want to fetch water as deep as possible, but in summer you may want to raise it a bit to get a slightly better temperature. One or more relatively powerful winches must be used. Total lifting weight can be 6 tonnes and requires good foundations and strong wires. In an embodiment as shown in Fig. 3, the pump wells (5) are placed between the tanks (2) with submersible intake pipes (5c) with powerful pumps (5b) arranged submerged or dry-docked to supply the plant with new water in sufficient quantity for the production of preferably at least 786 tonnes of biomass. From the overflow in the pump towers (18), the water flows into vertical fresh water distribution pipes (19) which distribute water and determine the direction of rotation and rotation speed in the tanks (2).

In an embodiment of the breeding facility (0) according to the invention, the tanks (2) comprise vertical fresh water distribution pipes (19) arranged inside the tank (2) near the tank wall (2a), designed to distribute and direct incoming water via preferably directionally adjustable slots or nozzles. The fresh water can be oxygenated via its own oxygen generators which provide continuous dosing and distribution of oxygen to all parts of the tanks to increase production and reduce pumping costs. The water circulates because the fresh water distribution pipe (19) is angled so that the water jet is directed in one direction, mainly tangentially along the tank wall (2a), and further accelerated by fish swimming in the opposite direction. Too much circulation can be a problem, but the channel (15) will break up and slow down circulation so that this problem is avoided. Water supply pipes are arranged so that they can be controlled at different angles to regulate the direction of circulation.

Fish in breeding facilities can set up a wave that rotates and can build up to a great height and eventually wash over the top of the tank. Off-centre extraction of water can cause and amplify the wave formation. For plastic tanks this can be destructive, while for steel tanks it will not have such a significant impact on the structure. For this problem, the channel (15) will have a dampening effect.

In an embodiment of the breeding facility (0) according to the invention, the fresh water distribution pipes (19) comprise an outer pipe (5e) and an inner pipe (5f) designed to be rotated, raised and lowered in relation to each other in a controlled manner. In this way, the amount, direction and height of the fresh water supply can be adjusted. The water supply is distributed with excess pressure to the water supply pipes which distribute and direct incoming seawater to the tanks (2).

In an embodiment of the breeding facility (0) according to the invention, the tanks (2) comprise a center drain strainer (14) arranged in or near the axis of the tank (2) and which is designed to extract surplus water from all or parts of the height/depth of the tank. The fish in the tanks will have fresh seawater in uniform circulation throughout the water column, with oxygen distribution that provides very good growth conditions throughout the tank. With the fresh water inlet on the periphery and the outlet in the center of the tank, this means that the inlet water must rotate and mix in the tank and not be led directly out of the tank before mixing with other water in the tank, as can easily happen with the known technique that has both inlet and outlet in the periphery of the tank. Fig. 2 shows the breeding facility (0) according to an embodiment of the invention with a drainage system, which leads out the main flow of wastewater from the tanks through suspended center drain strainers (14) and drainage channels (15) via filters (16), and back to the sea through screened grates (17) which prevent escape and penetration. Such a drain threshold for used water is illustrated in Fig.9.

An embodiment of the invention is illustrated in Fig. 1 which illustrates a profile and a side view of the farming facility (0) on the port side of the hull. In this solution, 6 tanks (2) are arranged in two rows, cylindrical, standing, with a funnel-shaped bottom part (3) with drain (9) for particles and dead fish arranged in the lower edge of the funnels (3), and tank tops (4) ) that protrude above the deck. Pump well tops (5) are placed between the tanks for intake, aeration and distribution of water to the 6 fish tanks (2).

Aft can be placed a deckhouse (6) with equipment for the installation of a central lining system, fore silos and technical facilities, as well as an upper deckhouse (7) with a control room, living room and space for accommodation. The figure also shows a raised walkway above the aisle (21). The breeders get a work platform that will be very safe and secure under all conditions and meets all requirements for personnel safety and so-called HSE requirements. In the bow part of the breeding facility (0) according to one embodiment of the invention, there is an aggregate room (22), diesel tanks and other technical facilities for safe and continuous operation of the facility. In an embodiment of the breeding facility (0) according to the invention, the facility as shown in Fig. 5 can be arranged below the main deck, with a generator system and oxygen generators and space for other technical equipment, dry rooms and wet rooms around the tanks.

Aft, the deck house (6) is located As shown in Fig.3. Fig.4 shows the aft 2nd floor/upper deck house (7) with control room overlooking the breeding facility, offices, living room and bedroom. The facility is also shown with an elevated walkway (21) over the aisle and over the pump tower and with a descent to the deck. A walkway above the deck (21) provides an overview and control over the condition of the fish in the tanks and elsewhere in the facility, and also acts as a foundation for laying out lining hoses. A washing robot and a smaller crane can be arranged next to each other from the walkway. The breeding facility according to the invention will have space for technical equipment for feeding fish from on-board storage or from free-standing sources, generating electricity and for normal operation of the breeding facility. Silos for fish feed with the necessary technology for feeding fish feed to fish tanks can be part of the equipment.

In one embodiment of the invention, the breeding facility (0) will be equipped with electric generators and thus self-sufficient in electricity and energy for ordinary operation, but can also be run with shore current since the facility can be located close to land.

In an embodiment of the invention as shown in Fig. 9, an additional quay will be arranged aft.

An embodiment of the breeding facility (0) according to the invention will have main dimensions that give a production capacity corresponding to biomass for one licence. It is estimated that this will give a total length of 60.5m, width 35m and draft 16.2m. The breeding facility (0) according to one embodiment of the invention can be arranged with a net roof to keep out seabirds, and it is also possible to arrange a roof over each individual tank (2) with loose sections in GRP or composite.

All possible combinations of the various embodiments of the invention are to be regarded as embodiments of the invention.

Short figure explanation

Embodiments of the invention are illustrated in the attached drawings where

Fig. 1 is a combined section and side view of the floating farm's (0) port side hull. The hull has a center hull (23) and fenders (25), standing tanks (2), with funnel-shaped bottom part (3) and drain (9). The figure also shows the pump well (5).

Deckhouse (6) is shown aft. Parts of the bottom hull (8) are illustrated. The figure also shows a raised walkway above the aisle (21). The section in the figure is along the line A-A' in Fig. 3. Fig. lb shows the same breeding facility (0) in side view as Fig. 1, with pump well (5) with telescopically lowered intake pipes (5c The figure also shows pipes (9b) for removing waste materials from locks (9) in the bottom of the tanks (2). Fig. 2 shows the same side view and section as Fig. 1 with a drainage system such as a hanging center drain strainer (14) and a drain channel (15) via a filter (16) and a screened grating (17). Furthermore, loose, movable lifting bottoms (10) are shown in two of the tanks (2) in different positions. The lifting bottoms (10) are shown with flexible hoses (9c) for removing waste from the locks (9) and centra- the sediment strainers (14) in different positions depending on the height positions of the raised bottoms (10). Fig.3 Shows a deck plan view of the main deck (lh) of the breeding facility (0) with six tanks (2) arranged in two rows in a steel facility in the form of a rigid steel hull with a certain ship shape. The figure shows center drain strainers (14), drain gutters (15), partial filters (16) and grates (17). Fi the diagram also shows the location of the distribution chamber (18) and standing water supply pipes (19) and channels (40) for internal transport and sorting of fish between the tanks (2). The location of the generator room (22) with space for generators and diesel tanks and other technical facilities, below the main deck, is also indicated. Fig. 4 Shows a deck plan view of the main deck of the breeding facility as in Fig. 3. Aft shows a plan section of the 2nd floor deck house (7) with control room, offices, lounge and bedroom. The figure also shows the walkway (21) over the aisle and the water distribution systems in the facility. Fig 5. shows a deck plan/section of the deck below the main deck of the breeding facility (as in Fig. 3. Components below the main deck are shown here, with a generator system and oxygen generators and space for other technical equipment. Fig. 6 shows a horizontal section and outline of the tanks ( 2) and bottom hull (8) and a bottom deck (26) arranged at the level at the transition between the cylinder sides and the funnel-shaped bottoms (3), see Fig. 1. Location of the locks (9) hoses (9b and 9c) in the out- guides for respective tanks with fixed and height-adjustable bottoms. Fig. 7 shows a partial cross-ship section, e.g. along the line B -B' in Fig. 3 through two of the tanks (2) seen from the front as well as a view of the superstructure seen from the front. Between the tanks (2 ) the pump well (5) with submersible, telescopic intake pipes (5c), distribution chamber (18) and supply pipe (19) is located. Parts of the bottom hull (8) are shown. Fig. 8 shows a front view and imaginary sections of the breeding facility along the line C - C in Fig. 3 and shows the main drainage system with center drain strainers (14) and av runner (15) with outlet (17). In the bottoms of the funnel-shaped bottoms (3) sluices (9) and drain pipes (9b) are shown. Fig. 9 Shows sections in different parts of the vessel and a view from the stern of the main deck of the breeding facility. The figure shows deck house (6) with floor for control room (7), additional quay (30) and drainage threshold with grating (17). The figure also shows the different levels and extents of the hull parts (1,23,8). Figure 10 shows a chart of a moored aquaculture facility according to the invention moored with a fore-raft and a raft for the collection of residual waste and dead fish associated with the facility.

Claims (16)

1. A marine aquaculture facility (0) comprising two or more standing tanks (2) for raising fish, with a funnel-shaped bottom (3), one or more water supply systems (5, 5b, 18, 19) and one or more drainage systems (14, 15, 16, 17, 9, 9b, 9c) characterized in that the tanks (2) are arranged as integral parts of a rigid hull (1) where the hull (1) at least comprises an upper rigid main hull (la) comprising a bow section (lb), a stern section (lc), ship sides (25) and a main deck (lh) - where the upper rigid main hull (la) is closed - where one or more tanks (2) are arranged with a loose and vertically displaceable raised floor (10) . 2. The breeding facility according to claim 1, where the hull (1) comprises at least a dense center hull section (23) with center hull side walls (23a) which extend below central parts of the main hull and which partially enclose the circumference of the tanks (2) and connect parts of the tanks side walls (2a) and where the center hull is preferably shorter and or narrower than the main hull (la). 3. The breeding facility according to claim 1, where the tanks (2) can be cylindrical or polygonal. 4. The breeding facility according to claim 2, comprising a bottom hull (8) with bottom hull side walls (8a) extending mainly vertically as a continuation of the center hull side walls (23a) to below the bottoms (3) of the tanks (2), and is equipped with a main bottom ( 8b) and is designed to be filled with water. 5. The breeding facility according to claim 4, where the main bottom (8b) covers at least all the central bottom points of the tanks (2) with sluice (9). 6. The breeding facility according to claim 4, where the main bottom (8b) has openings for water intake pipes (5c) and preferably closes tightly to these. 7. The breeding facility according to claim 1, where the tanks (2) are arranged with a top (4) that extends above the construction water line and where the tanks (2) are arranged to have a water level that is above the construction water line. 8. The breeding facility according to claim 1, where the tanks (2) have a greater depth than their diameter. 9. The breeding facility according to claim 1, where the tanks (2) have a larger diameter than their depth. 10. The breeding facility according to claim 1, where a secondary drainage system (9, 9b, 9c) is arranged to separate out and transport away dead fish, remains and particles. 11. The breeding facility according to claim 10, where the secondary drainage system (9, 9b, 9c) comprises pipes or hoses (9b, 9c) to transport dead fish, offal etc. to a treatment facility (9d) in the stern section (20). 12. The breeding facility according to claim 1, where the secondary drainage system (9) on the vertically displaceable raised bed (10) comprises a flexible, preferably spiral-shaped hose (9c). 13. The breeding facility according to claim 1, where one or more telescopically arranged water intake pipes (5c) are arranged to collect water from depths determined by the temperature and oxygen level in the intake water. 14. The breeding facility according to claim 1, where the tanks (2) comprise standing fresh water distribution pipes (19), arranged inside the tank (2) near the tank wall (2a), designed to distribute and direct incoming water via slits or nozzles. 15. The breeding facility according to claim 6, where the fresh water distribution pipes (19) comprise an outer pipe (5e) and an inner pipe (5f) designed to be rotated, raised and lowered in relation to each other in a controlled manner. 16. The breeding facility according to claim 1, where the tanks (2) comprise a center drain strainer (14) arranged in or near the axis of the tank (2) and designed to extract surplus water from all or parts of the height/depth of the tank.