NO347491B1 - Floating closed or semi-closed aquaculture facilities - Google Patents

Description

Floating closed or semi-closed breeding facilities

Field of the invention

The present invention relates to a floating closed or semi-closed breeding facility, comprising several closed fish tanks placed circumferentially around a center of the breeding facility, where the fish tanks are arranged to be filled with water and fish.

The background of the invention

Farming facilities consisting of open or closed cages floating in the sea are known. Traditionally, floating rings are used as floating collars and the cage in the form of a groove is suspended in the floating collar. For closed systems, a tight canvas is placed facing the groove that holds the fish.

Challenges with standard breeding cages include lice, which are particularly found in the upper water layers. In open facilities this is a major problem, but can be better dealt with in closed facilities. Runoff and associated contamination can also be a problem. Likewise, lack of space, fish disease and overfeeding.

With increasing volume and complexity of the systems, challenges can arise with the distribution of the correct water quality. With the right water quality (such as flow, salinity, temperature, oxygen) the fish can use the entire volume and have access to feed and the right water wherever they are.

The fish need to have the opportunity to exercise and it is important to ensure the correct water speed so that the fish get the necessary exercise to stay healthy.

Discussion of prior art

EP0347489B1 describes an offshore facility for farming and storing fish and other marine animals, comprising a semi-submersible floating platform containing silos which are kept submerged together with the platform. The silos are equipped with closable grid windows and a device for removing contaminants.

WO 2022/186700 A1 describes an aquaculture system for breeding aquatic organisms, where the aquaculture system comprises several rigid containers and a rigid central unit provided with several arms, each container comprises a waterproof wall and a waterproof bottom, and each container is vertically adjustable in relation to the central unit.

WO 2022/182242 A1 describes a floating structure for fish farming, where a polygonal or circular ring pontoon is the lower part of the structure and the basis for several stabilization columns, which internally have partially open prismatic tanks for fish delimited by the tank shell, where the bottom of the tanks is a net -structure that prevents the fish from escaping, but also regulates the circulation of water in and out of the tanks. Each column is attached to the pontoon with an outer shell that rests on the pontoon deck, and an inner tank shell, which due to its reduced cross-section penetrates the pontoon like a plug by having a circular/prismatic recess arranged in the pontoon from the top of the pontoon to the bottom.

WO 2018/156027 A1 describes a floating plant for breeding an aquatic organism, where the plant comprises at least two rigidly connected breeding units, where each breeding unit is surrounded in its upper part by a continuous wall made of a rigid material. The continuous wall forms at least in part a floating body, and the continuous wall of a first rearing unit (2) and the continuous wall of a second rearing unit are rigidly connected to a connecting wall formed in a rigid material, and the connecting walls and the connecting wall defines a well between the first farming unit and the second farming unit.

Stationary, long sea farms shaped like a ship are also known, or where old tankers are used for that matter.

Purpose of the present invention

The aim is to create a robust aquaculture facility that can be placed in or preferably outside Norwegian fjords, and which can compete with today's traditional facilities. Another aim is to create a closed breeding facility that provides a controlled environment for breeding the fish.

With a robust concept, operational reliability is ensured, so that technical breakdowns are avoided, and that biosecurity can be significantly improved, so that serious illness is avoided in the facility. Preferably, the facility will have zero emissions and will also be escape-proof.

The breeding facility according to the invention is preferably completely equipped with all systems/equipment for breeding fish.

The breeding facility is thought to be cast in concrete (or built in steel). The facility can, for example, be designed for normal operation in up to 16 meter waves, and designed for an accident condition of 22 meter wave height, with a buoyancy tank punctured or filled with water.

Summary of the invention

According to the invention as stated in the independent claim 1, a floating closed or semi-closed breeding facility is produced, comprising several closed fish tanks placed circumferentially around a center of the breeding facility, where the fish tanks are arranged to be filled with water and fish. The breeding facility comprises several circular-cylindrical flotation tanks placed circumferentially around the center of the breeding facility, with each flotation tank being located outside and at least partly intermediate between two adjacent circular-cylindrical fish tanks, and where the center is made up of a central well (moonpool) open at the bottom for drainage and stabilization of the breeding facility.

Alternative designs are specified in respective independent requirements.

The breeding facility may comprise a fleet of fish tanks and buoyancy tanks, where the respective tanks are standing, circular cylindrical tanks.

Three, four or more fish tanks can be placed vertically and circumferentially around the center, and three, four or more buoyancy tanks can be placed vertically and circumferentially around the center.

Each flotation tank can include a ballast pump for regulating the ballast level in the flotation tank, where the ballast system is self-regulating and designed to ensure a constant level on the freeboard regardless of loads on the farm.

Furthermore, the fish tanks and buoyancy tanks in an upper part can be equipped with stiffening ring beams.

The fish tanks and buoyancy tanks can also be equipped in an upper part with a rising wall-shaped wave protector.

The wave protector can be cast as an extension of the fish tanks and buoyancy tanks.

Alternatively, the surge protector can be mounted on and/or outside the ring beam.

The breeding facility can further include pump wells placed between the fish tanks, where each pump well is equipped with a seawater circulation pump and is connected to a seawater intake that extends into the sea.

Each fish tank can also include a seawater outlet at the bottom, where a perforated, strainer-shaped tube is placed vertically above the seawater outlet.

Said sieve-shaped pipe can be equipped with a pipeline plug for temporarily sealing the fish tank.

Feed tanks can be integrated into a top deck in the buoyancy tanks, and where feed pumps are located on a basement deck below the feed tanks.

The breeding facility may also include silage tanks placed on a basement deck in the center of the facility.

The entire breeding facility can be mainly cast, in one unit, in concrete, such as by means of slip casting.

The breeding facility may also include a housing/control unit located on a top deck in the center of the facility.

The fish tanks provide a closed controlled environment for raising fish. The buoyancy tanks provide buoyancy for the fish tanks and also act as "damage stability" for the farming facility. The center well ensures stability of the construction in the event of movements due to waves, in addition to that, stormwater and rainwater inside the facility will be drained out through the center well. The ring beams provide the necessary rigidity to the construction in case of larger movements due to waves.

Description of figures

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

Figure 1 shows a perspective sketch of a breeding facility according to the invention. Figure 2 shows a simplified perspective sketch of the farming facility.

Figure 3 shows a simplified overview sketch of the breeding facility.

Figure 4 shows a simplified sketch of the breeding facility with pump wells, seawater intake and feed tanks.

Figure 5 shows a section through the breeding facility, approximately halfway through the buoyancy tanks.

Figure 6 shows a section through the breeding facility, approximately in the middle of the fish tanks.

Description of preferred embodiments of the invention

The invention describes a floating closed or semi-closed breeding facility in the form of a raft built preferably of concrete, but which can also be built of steel.

In one version of the present invention, however, the entire breeding facility is cast, as a unit, in concrete using slip casting. This results in a very simplified and efficient construction process in terms of time and costs.

The breeding facility 10 comprises several closed fish tanks 12 placed circumferentially around a center 16 of the breeding facility 10. For breeding fish, the fish tanks 12 are naturally designed to be filled with water and fish.

The breeding facility 10 further comprises several buoyancy tanks 14 placed circumferentially around the center 16 of the breeding facility 10. Each buoyancy tank 14 is located outside and at least partially intermediate two adjacent fish tanks 12. This placement of the buoyancy tanks 14 provides improved and often necessary stability for the breeding facility in high waves .

The center 16 consists of a central well (moonpool) open at the bottom, which provides drainage and which further improves the stability of the breeding facility 10.

The attached figures show an embodiment of a breeding facility 10 which consists of four cylindrical fish tanks 12 for raising fish and four cylindrical buoyancy tanks 14 for ballasting and buoyancy. The fish tanks 12 are placed vertically around the center of the construction and the buoyancy tanks 14 are positioned outside. In the center of the breeding facility 10, there is a "moonpool" 16 for draining water and stabilizing the construction. The use of four cylindrical fish tanks 12 and four cylindrical buoyancy tanks 14 has proven to be the most optimal combination, both with regard to the production of the plant and with regard to stability, but the use of fewer or more fish tanks and buoyancy tanks is conceivable.

The fish tanks 12 are preferably circular concrete tanks with an outlet 26 in the bottom plate 34 for water circulation. The buoyancy tanks 14 are preferably circular concrete tanks and are completely closed with the possibility of ballast water adjustment. The ballast system is self-regulating and ensures a constant level on the freeboard regardless of loads on deck. The top deck 38 in the buoyancy tanks 14 can be a steel deck.

A concrete wall is located on the outside of the fish tanks 12 and the buoyancy tanks 14. This wall is a wave protector 20 which is to protect against overwash from waves.

At the top of the fish tanks 12 and the buoyancy tanks 14, a ring beam 18 is cast in concrete. Its function is to take up the tensile forces at the top of the tanks 12,14 and it will function as a walkway around the tanks 12,14 and a structure for the steel decks 38 at the top of the buoyancy tanks 14. In each buoyancy tank, ballast pumps will be placed which will regulate the ballast level in the buoyancy tank and regulate the buoyancy level. The ballast system is self-regulating and ensures a constant level on the freeboard regardless of loads on deck.

The wave protector 20 can be cast in concrete, preferably by slip casting, on the ring beam 18 on top of the tanks 12,14. Alternatively, the surge protector can be mounted on top of the ring beam 18.

Seawater circulation pumps for water circulation are placed in separate pump wells 22 between the circular tanks (triangular cells), for example in the area marked T in figure 3 or in the center 16 on the top deck 38, and outlet 26 for seawater is placed at the bottom of the fish tanks 12, as shown in figure 6 The seawater circulation system ensures good control of water circulation, as the amount of water can be adjusted as needed.

The pump wells 22 prevent lice from entering the fish tanks 12 and protect against the growth and bloom of algae in the pump inlet. The outlet at the bottom of the fish tanks 12 protects against the intake of lice from shallower water during backflow. Adequate distance must also be ensured between intake and outlet of seawater.

In the center of the breeding facility 10, there are two levels of concrete cover/center plate with a thickness of, for example, 0.35 meters for both the top cover 38 and the basement cover 44.

The concrete deck will also act as ring braces for the fish tanks.

A housing unit 36 with a control room can be placed in the center of the structure on the top deck 38. In the center of the breeding facility 10 on the basement deck 44 there will be a technical room with, among other things, silage tanks 32, fuel tanks and a reserve circulation pump. Both of these decks 38,44 will be able to have drainage so that seawater that reaches the top deck will flow back to sea.

The feed tanks 30 can be integrated into the top deck 38 of the buoyancy tanks 14. Feed pumps can also be placed on the basement deck 44 below the feed tanks 30. Anchoring lines will preferably be above the buoyancy tanks 14.

The fish tanks 12 have seawater circulation. Seawater circulation pumps can be placed between the tanks (tricells) in the pump wells 22, and will pump fresh seawater into the fish tanks 12 and build up an overpressure in the fish tanks, for example of approximately 0.5 meters in the fish tanks. The excess pressure pushes out dirty water in the outlet 26 in the bottom plate in the fish tanks 12. Each fish tank can, for example, have a water volume of 25,000 m<3>.

A perforated pipe 28 can be fitted over the seawater outlet 26 inside the fish tanks 12. This will act as a strainer and prevent the discharge of dead fish, larger particles and sludge. The perforated, strainer-shaped pipe 28 can also be equipped with a pipeline plug for temporarily sealing the fish tank 12, thereby being able to bilge the fish tanks 12 to create extra buoyancy, e.g. in case of discharge from construction dock.

Dead fish, particles and sludge can be sucked up from the fish tanks using a sludge suction device, for example of a known type placed on the outlet 26.

During operation of the breeding facility 10, the water level 42 outside the facility is preferably somewhat below the water level 40 inside the fish tanks 12, as shown in figure 6. For example, this level difference can be approximately 1m during normal operation and without wave influence. The fish tanks 12 can, for example, have a water height of approximately 30m from the bottom 34 up to the upper water level 40.

A closed breeding facility according to the invention will therefore be able to incorporate a silo for feeding, space for handling waste, space for oxygen production, etc., and does not need an expensive work boat for efficient production. A closed facility provides opportunities for controlling water quality, such as salinity, temperature and oxygen, as well as making it possible to create favorable currents in the water column to improve fish health. In a closed facility, lice and disease will be avoided from entering the facility, waste can be taken care of, escape and overfeeding of the fish prevented. A closed concrete plant will have a long life - preferably 40 to 50 years, and a closed concrete plant will also be cost-effective and environmentally friendly.

Claims (15)

Patent claims 1. Floating closed or semi-closed breeding facility (10), comprising several closed fish tanks (12) placed circumferentially around a center (16) of the breeding facility (10), where the fish tanks (12) are arranged to be filled with water and fish, characterized by that the breeding facility (10) comprises several circular-cylindrical buoyancy tanks (14) placed circumferentially around the center (16) of the breeding facility (10), each buoyancy tank (14) being placed outside and at least partially intermediate between two adjacent circular-cylindrical fish tanks (12), and that the center (16) consists of a central well (moonpool) open at the bottom for drainage and stabilization of the farming facility (10). 2. Floating breeding facility (10) in accordance with claim 1, characterized in that the breeding facility (10) comprises a fleet of fish tanks (12) and buoyancy tanks (14), where respective tanks (12,14) are standing, circular cylindrical tanks. 3. Floating aquaculture facility (10) in accordance with claim 1, characterized in that three, four or more fish tanks (12) are placed vertically and circumferentially around the center (16), and that three, four or more buoyancy tanks are placed vertically and circumferentially about the center (16). 4. Floating aquaculture facility (10) in accordance with claim 1, characterized in that each buoyancy tank (14) comprises a ballast pump for regulating the ballast level in the buoyancy tank (14), where the ballast system is self-regulating and designed to ensure a constant level on the freeboard regardless of loads on the breeding facility (10). 5. Floating aquaculture facility (10) in accordance with claim 1, characterized in that the fish tanks (12) and the buoyancy tanks (14) in an upper part are equipped with stiffening ring beams (18). 6. Floating aquaculture facility (10) in accordance with claim 1, characterized in that the fish tanks (12) and the buoyancy tanks (14) in an upper part are equipped with an upwardly extending wall-shaped wave protector (20). 7. Floating aquaculture facility (10) in accordance with claim 6, characterized in that the wave protector (20) is cast as an extension of the fish tanks (12) and the buoyancy tanks (14). 8. Floating breeding facility (10) in accordance with claim 6, characterized in that the wave protector (20) is mounted on and/or outside the ring beam (18). 9. Floating aquaculture facility (10) in accordance with claim 1, characterized in that the aquaculture facility (10) comprises pump wells (22) placed between the fish tanks (12), where each pump well (22) is equipped with a seawater circulation pump and is connected to a seawater intake ( 24) which extends into the sea. 10. Floating breeding facility (10) in accordance with claim 1, characterized in that each fish tank (12) comprises a seawater outlet (26) at the bottom, where a perforated, strainer-shaped pipe (28) is placed standing above the seawater outlet (26). 11. Floating aquaculture facility (10) in accordance with claim 10, characterized in that said sieve-shaped pipe (28) is equipped with a pipeline plug for temporarily sealing the fish tank (12). 12. Floating farming facility (10) in accordance with claim 1, characterized in that feed tanks (30) are integrated in a top deck (38) in the buoyancy tanks (14), and where feed pumps are placed on a basement deck (44) below the feed tanks (30) . 13. Floating breeding facility (10) in accordance with claim 1, characterized in that the breeding facility (10) comprises silage tanks (32) placed on a basement deck (44) in the center of the facility (10). 14. Floating breeding facility (10) in accordance with claim 1, characterized in that the entire breeding facility (10) is mainly cast in one unit in concrete, such as by slip casting. 15. Floating breeding facility (10) in accordance with claim 1, characterized in that the breeding facility (10) comprises a housing/control unit (36) placed on a top deck (38) in the center of the facility (10).