NO20230076A1 - Sea-based farming system for fish - Google Patents

Description

FIELD OF TECHNOLOGY

The invention relates to a sea-based farming system for fish.

BACKGROUND

There are a number of challenges associated with farming fish and especially salmon farming. Challenges that threaten the salmon industry's operating basis, and basis for growth.

This applies in particular to lice, diseases and escapes, but also land use for sea and land as well as energy use and personal injuries. As a result of these challenges, efforts have been made in recent years to develop new technology that reduces or completely eliminates some of the problems, with a particular focus on lice and escape.

It has also been important to reduce waste in the form of fish sludge and dead fish around aquaculture facilities, which can cause problems both for the operation and for marine life in a given area. Fishing waste and sludge can be considered a resource and can, for example, be dried and used as fuel in biogas plants.

Today, there are major challenges with new locations for increased production of salmon and for the start-up of other species such as cod. Part of the reason is biosecurity, to ensure a good distance between the facilities, it is recommended that there is at least 2.5 km distance between the facilities within the same production zone. To be able to be in a separate production zone, the distance is 5 km.

Other factors that limit new possible locations are available approved area from the municipalities, fishing interests, spawning grounds/spawning areas.

Breeders today naturally want to have the best possible operating conditions at each location. The prerequisites are defined as how much fish can be produced without affecting the environment below and around the facility.

Faeces and pellets as residual products are spread with the current, strong currents and great depths give greater dispersion and thus also better carrying capacity. The proposed invention can be placed in places with low current and depths of around 15 meters and deeper, and will not be in direct competition for the same area and rather be the solution to using land-based areas that are not suitable for conventional farming.

Conventional farming is currently struggling with lice infestation. Addition of lice up to national limit values for the number of lice per farmed salmon results in a requirement for de-lice removal. Before deworming, farmed salmon must be starved, and during treatment the fish are exposed to mechanical deworming, temperature changes or medical forms of deworming.

Common to all is that this results in a directly higher mortality during de-fleaing, but also an indirect mortality in the following days. After deworming, the salmon's appetite is reduced, so it may take several days before the fish returns with the same appetite. Reduction in appetite results in lower growth than would have been the case without de-lice.

In the last couple of years, winter sores have been a major challenge for fish throughout the winter season. Fish with winter sores have a higher mortality rate, at the same time fish slaughtered with winter sores are downgraded to product fish, which in turn results in a lower price for breeders. Winter sores can occur via mechanical damage through treatment against lice, encroachment on the groove wall, displacement, predators, etc.

This can further lead to bacterial infection which is spread through the cage.

Winter sores are thus a problem for fish health. Exposure in closed constructions with control over the biotic factors will probably result in a reduction in mortality.

Farming at sea with floating closed cages, or semi-closed cages is part of the technology that is being tested to a greater extent and is also used and can be considered both a known and available technique in today's market and has been given the term closed cage concepts.

These concepts are often characterized by the fact that they are used in already existing plant structures and collect water with risers with filtration. This reduces the possibility of cross-contamination between devices, but it cannot be ruled out.

The concepts also use the same area as conventional farming and thus do not solve one of the industry's biggest challenges, which is available area. In addition, these concepts bring with them new problems relating to wave movements inside the closed cages as a result of external wave stresses, so-called resonant waves.

This can lead to unfortunate stresses in the constructions, moorings, the growing conditions of the fish in the cage and an HSE problem for personnel working in the cage.

From patent 345194, a breeding system for breeding fish is known, comprising a floating treatment and breeding facility, consisting of a floating structure equipped with several cages for breeding marine organisms, where the floating structure comprises at least one water channel, which water channel is provided with flowing water arranged to allow said marine organisms to swim through the water channel. The invention is characterized in that said water channel is placed externally on the floating structure and runs horizontally between the cages for breeding the marine organisms, said water channel comprising a longitudinal dividing wall to allow water flow both ways in the water channel, and respective cages comprise side water channels that run to the water channel.

From patent 332589, a breeding system for breeding fish is known, comprising a marine breeding facility comprising two or more standing tanks for breeding fish, with a funnel-shaped bottom, one or more water supply systems and one or more drainage systems where the characteristic features are that the tanks are arranged as integral parts of a rigid hull where the hull comprises at least an upper rigid main hull comprising a bow section, a stern section, ship sides and a main deck and where the upper rigid main hull is closed and one or more tanks are arranged with a loose and vertically displaceable raised bottom.

From the commitment for development permits for the Salmon Zero concept, the Directorate of Fisheries' reference 16/8836, a completely closed marine facility with full recycling of production water is described. In the facility, food fish will be produced until slaughter.

Carcass weight should be around 6.5 kg. Production will take place in closed cages at sea. The recycling and water treatment systems must mainly be located on land, and parts of the water treatment must be integrated into the production units. In the longer term, it should be possible to move all installations to sea, with recycling facilities on board a suitable fleet. The facility must be modular.

SUMMARY OF THE INVENTION

The present invention aims to solve some of the problems with the above-mentioned systems with the main emphasis on fish health, land use of coastal areas and HSE problems. And the invention is hereby described in an introduction and some embodiments.

The invention comprises a marine structure that houses closed breeding units, which reduces the risk of lice and diseases coming from the water intake as well as from cross-contamination of the water from one breeding unit to another.

For each slaughter cycle, the fish that is prepared for slaughter must go through a starvation process where the fish's amount of feed is reduced. By using the waiting tank, you avoid having to starve all the fish standing in the breeding tank, including fish that are not ready for slaughter. Instead, only the fish you want to slaughter at any given time are transferred.

The benefit is better control over the slaughter process and you avoid delaying the growth process of fish that are not ready for slaughter.

The sea intake will be from a depth of over 25 meters to reduce the possibility of lice, algae and jellyfish in the intake. Furthermore, the wild seawater is led up to separate closed inlets to each breeding tank. This ensures good biosecurity, water from one tank will never come into contact with water from other tanks until it is in the drainage system out of the module(s). This gives full control over the water relationship.

The facility will be modular so that it can easily be scaled up in the event of future increased demand, or scaled down in the event of reduced demand. Each module is in independent connection with the seabed through a set of legs, where the module only has a movable degree of freedom in the vertical direction and is locked in the horizontal plane. This prevents wave resonance both in the rearing tanks and holding tanks and, in addition, there will be no need for mooring, which normally in floating constructions extends beyond a larger area. As the facility is module-based, it will also make it possible to place the modules optimally in relation to the seabed.

The aforementioned is achieved with a farming system as defined in the independent claim 1 where the system for farming fish consists of one or more floating farming units, and where each farming unit comprises a floating structure that carries one or more closed and independent farming modules. And where the floating structure is attached to the seabed so that it can move in a vertical direction, but has limited or no movement in a horizontal direction.

Alternative designs are specified in the independent requirements.

In a second embodiment of the above-mentioned System, the floating structure is fixed to the seabed through vertically oriented telescopic legs placed under the floating structure and where an upper, outer cylinder is attached to the floating structure and a lower, inner cylinder is fixed to the seabed.

In a third embodiment of the above-mentioned System, said breeding module(s) comprise a breeding tank for breeding fish, where the breeding tank rests on the floating structure on a horizontal plane flange, and is simultaneously locked to the floating structure in a horizontal direction. And where the rearing tanks are independently movable in an upward vertical direction in relation to the floating structure.

In a fourth embodiment of the above-mentioned system, the rearing tank can be separated from the floating structure by being lifted vertically up and out.

In a fifth embodiment of the above-mentioned system, said rearing module(s) comprise at least one waiting tank for starvation feeding and preparation of fish for slaughter, where the waiting tank rests on the floating structure on a horizontal plane flange. And at the same time is locked to the floating structure in a horizontal direction, and where the holding tank is independently movable in an upward vertical direction in relation to the floating structure.

In a sixth embodiment of the above-mentioned system, the holding tank can be separated from the floating structure by being lifted vertically up and out.

In a seventh embodiment of the above-mentioned system, the rearing module further comprises at least one feed tank for feeding fish in the rearing tank.

In an eighth embodiment of the above-mentioned system, the farming module further comprises:

- at least one silage tank for receiving and processing dead fish coming from the rearing tank and/or waiting tank, and

- at least one cleaning tank for filtering waste and water coming from the rearing tank and/or waiting tank.

In a ninth embodiment of the above-mentioned system, said farming module further comprises a bio-waste facility common to all modules for receiving waste coming from purification tank(s).

In a tenth embodiment of the above-mentioned system, said breeding module (1) further comprises at least one oxygen unit for oxygenating water into the breeding unit(s) and/or into the holding tank(s).

The invention will be described in more detail in the subsequent patent claims.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be described with reference to the figures 1 to 3 mentioned below. Further properties and advantages appear in the subsequent detailed description.

Figure 1 shows the system consisting of 5 farming units in perspective.

Figure 2 shows the system consisting of a farming unit seen from above in a horizontal section.

Figure 3 shows a farming unit in perspective.

DETAILED DESCRIPTION OF THE INVENTION

The following reference number is also used in the document's detailed description and in the figures:

13 Breeding tank

11 Waiting tank

17 Feed tank

18A Cleaning tank

18B Silage tank

22 Oxygen unit

A Biowaste plant

14A, B Telescopic legs, 14A part of the floating structure and 14B fixed in the bottom

1120 Plan horizontal flange for the holding tank 11 and floating structure 20

1320 Plan horizontal flange for the rearing tank 13 and floating structure 20

SIT Seawater pipe for water in

Figure 1 shows the present farming system 100 with several farming units 10 interconnected and where each unit 10 comprises a floating structure 20 with at least one farming tank 13 where said farming tank(s) 13 further comprises a superstructure at a height from the upper deck of the unit 10, And where the top of the superstructure is covered with solar panels 12 which provide energy to supply the rearing tanks 13 and/or the waiting tanks 11 with electricity for the right amount of light and electricity for pumps for internal air circulation over the pool. A bio-plant A that receives waste from all the modules 10 is placed on the upper deck of one of the modules 10.

Figure 2 shows the current farming system 100 in a horizontal plan view of a farming unit 10 seen from above where the top deck of the floating structure 20 has been cut away and two closed farming modules 1 are shown. , silage tank 18B, and feed tank 17 as well as pipe connections between roof and structure for the attachment of legs 14 a, b, and intake of seawater SIT. On the right side of the module 10, a similar, mirrored farming module 1 is shown which is not embedded.

Figure 3 shows a rearing unit 10 in perspective where parts of the floating structure 20 are illustrated, and where the rearing tank 13 is raised vertically above the floating structure 20 and its flat horizontal flange 1320 on which the rearing tank 13 rests during production. The figure further shows the holding tank 11 raised vertically above the floating structure 20 and its flat horizontal flange 1120 on which the holding tank 11 rests during production. These mentioned tanks 11,13 are both completely sealed in communication with the sea and will be able to be lifted vertically up either by water being pumped out of the tanks which results in the tanks gaining greater buoyancy, and/or by the tanks being physically lifted up vertically by a mechanical device.

The figure further shows some of the legs 14a, b which in this embodiment of the invention are illustrated as telescopic legs and where 14a is an upper, outer cylinder which is attached to the floating structure 20 and where 14b is a lower, inner cylinder which is in connection with the seabed and motionless. In the event of tidal variations, the upper, outer cylinders 14a will move together with the floating structure 20 in a vertical direction up and down over each respective lower, inner cylinder 14b.

Claims (10)

PATENT CLAIMS 1. System (100) for farming fish consisting of one or more floating farming units (10), characterized in that each farming unit (10) comprises a floating structure (20) which carries one or more closed and independent farming modules (1) where the floating structure ( 20) is fixed to the seabed so that it can move in a vertical direction, but has limited or no movement in a horizontal direction. 2. System (100) according to claim 1, where the floating structure (20) is attached to the seabed through vertical telescopic legs (14A, B) placed under the floating structure (20), where an upper, outer cylinder (14A) is attached to the floating structure (20) and a lower inner cylinder 14(B) is fixed to the seabed. 3. System (100) according to claim 1, or 2, where said breeding module(s) (1) comprises a breeding tank (13) for breeding fish, where the breeding tank (13) rests on the floating structure (20) on a horizontal flat flange ( 1320), and at the same time is locked to the floating structure (20) in a horizontal direction, and where the rearing tank (13) is independently movable in an upward vertical direction in relation to the floating structure (20). 4. System (100) according to claim 3, where the rearing tank (13) can be separated from the floating structure (20) by being lifted vertically up and out. 5. System (100) according to claims 1 to 4, where said breeding module(s) (1) comprises at least one holding tank (11) for starvation feeding and preparation of fish for slaughter, where the holding tank (11) rests on the floating structure (20) on a horizontal plane flange (1120), and at the same time is locked to the floating structure (20) in a horizontal direction, and where the holding tank (11) is independently movable in an upward vertical direction in relation to the floating structure (20). 6. System (100) according to claim 5, where the holding tank (11) can be separated from the floating structure (20) by being lifted vertically up and out. 7. System (100) according to one of the preceding claims where said breeding module (1) further comprises at least one feed tank (17) for feeding fish in the breeding tank 8. System (100) according to the preceding claim where said farming module (1) further comprises: - at least one silage tank (18B) for receiving and processing dead fish coming from the rearing tank (13) and/or holding tank (11) and - at least one cleaning tank (18A) for filtering waste and water coming from the rearing tank (13) and/or waiting tank (11). 9. System (100) according to claim 8, where said farming module (1) further comprises a biowaste facility (A) common to all modules (1) for receiving waste coming from purification tank(s) (18A, B). 10. System (100) according to the preceding claim where said farming module (1) further comprises at least one oxygen unit (22) for oxygenating water into the farming unit (13) and/or into the holding tank (11).