NO874244L - DEVICE FOR FISHING SCHEMES. - Google Patents

Description

The present invention relates to a device at a fish mare for farmed fish, comprising a rigid, ring-shaped support structure with associated floats or other buoyancy-creating means, as well as a water-flowable fish container attached to the support structure.

A conventional design for a fish mare for farmed fish, as mentioned above, has the fish container attached to the support structure in the form of a bag of groove-shaped or groove-forming material. Optionally, the bag in local areas of the bag or even in the entire extent of the bag can be covered with dense cloth material. The fish container can be stretched in different directions below by means of tension members which can be anchored to the seabed or to attachments on land. In practice, it can present problems to have such fish containers repaired and cleaned or repaired at a level above the sea surface, among other things because of the anchoring to the seabed or to the attachment on land or because of the attachment to the support structure as well as the need to be able to keep the fish in the fish container while such inspection, repair and/or maintenance takes place.

When the fish container has been submerged in the sea for some time, it can be exposed to strong fouling and thereby, among other things, have reduced water flow to the fish container's cavity. There is therefore a need for routine inspection and maintenance of and possible repair of the fish container.

It can also present problems, especially with strong flow in the lateral direction towards the fish container, to keep it expanded to the desired large volume as a result of a lack of rigidity in the fish container, especially if one or more of the anchoring devices or tensioning devices should fail. Generally, the fish container has a low inherent stiffness, as any stiffening of the fish container normally further complicates inspection, cleaning and repair of the fish container.

In certain sea areas where there may occasionally be problems with strong sea currents and strong sea currents or strong wind loads at the sea surface, there may also be a need to be able to submerge the fishing pond to a level below the sea surface. In the case of a conventional type of fish pond, such immersion will greatly further complicate the design and operation of the fish container and the support structure, as one must then ensure that the fish pond is covered on the upper side with a roof-forming, complicating construction.

With the present invention, the aim is to remedy the above-mentioned problems and disadvantages in a simple and effective way by means of a particularly advantageous, but still relatively simple construction.

The device according to the invention is characterized by the fact that the fish container is in the form of a hollow body of rotation with a water-flowable, but otherwise closable cavity via separate access opening(s), for receiving the farmed fish in a quantity of water in the fish container, and that the fish container , or at least parts of it, are rotatably stored in the support structure about a horizontal axis that runs across the support structure approximately in its mid-plane, for setting the fish container in different rotational positions in relation to the support structure, at least a large proportion of, and preferably about half of the fish container's volume is submerged in water and a large portion of the fish container that projects upwards above the support structure forms a roof structure over the submerged part of the fish container, while the support structure floats on the sea surface.

According to the invention, a construction has been produced which can be used with great advantages both in a surface position and in a submerged position.

The fish container can be set in a surface position, where you have easy access to the interior of the fish container, in an easy way to different turning positions for different purposes. For example, routine inspection, repair or cleaning of previously submerged fish container parts can be carried out, by turning these parts of the fish container to a level above the sea surface, while other parts of the fish container are swung down into the sea to replace the parts that are swung upwards above sea level. This conversion can be carried out without thereby affecting the surrounding environment of the farmed fish in the fish tank, as the turning movement of the fish tank ensures a constant volume of water in the fish tank.

In the normal position of use, the roof-forming part of the fish container in a surface position can shield the farmed fish and the delimited aquatic environment above, for example from birds, while the roof-forming part of the fish container in a downward-turned, submerged position can delimit the farmed fish and the delimited aquatic environment from the surroundings in cases where this is considered necessary . For example, it may be appropriate to shield the fish container's water environment from the surroundings in cases where cleaning is carried out in those parts of the fish container which are tilted upwards above sea level. In particular, these are cases where the cleaning takes place by blowing fouling, in a direction away from the fish container and outwards on the sea surface outside the fish pond. In such a rotated state of the fish container, the normally bottom-forming part of the fish container can consequently be subjected to cleaning, repair, etc. in an easy and simple way, while the fish container's submerged volume of water containing fish is shielded against unwanted backflow of cleaning agent, removed fouling, etc. to the fish's aquatic environment. If the roof-forming part is made of canvas material or other dense material, the roof-forming part in the lowered state can possibly also form a heat shield or a temperature shielding wall around the farmed fish and the limited aquatic environment. In an easy way, larger or smaller areas of the fish container's perimeter can be further covered with shield-forming or wall-forming material, as needed, in a particularly simple and easy way by making such additional cladding of the fish container in local parts on its outside.

The fish container is also designed to be pulled downwards to a level below the sea surface and in such a completely submerged position the fish container can have additional shield-forming or wall-forming material applied in advance to larger or smaller areas of the fish container's perimeter, as needed. In addition, by completely submerging the fish container in this way, a significant increase in the volume of the limited water volume in the fish pond can be achieved, since the entire volume of the fish container below the sea surface can then be utilized, i.e. both the volume below and the volume above the support body as a volume for taking in fish.

The further advantage is achieved according to the invention, by using a stiffened fish container and associated stiffened support structure, that the fish net can be anchored in a particularly simple way by means of a single bottom attachment or other single attachment at a level below the sea surface. Hereby, one has the option of being able to submerge the fish pond to a level below the sea surface or raise the fish pond to a level floating on the sea surface, as needed, with the help of a simple tensioning device.

Further features of the present invention will be apparent from the following description with reference to the accompanying drawings which show some preferred design examples and in which: Fig. 1 shows a vertical section of the device according to the invention. Fig. 2 shows a horizontal section of the device according to fig. 1. Fig. 3 and 4 show in corresponding section to fig. 1 and 2 an alternative embodiment of the device according to the invention. Fig. 5 shows a vertical section through the device's support structure. Fig. 6 shows a plant with two submersible fish meters according to the invention, according to a first embodiment. Fig. 7 shows a plant with two submersible fish meters according to the invention, according to a second embodiment.

In fig. 1 and 2, a fish mare is shown which consists of a support structure 10 and a fish container 11. The fish container 11, which forms a rigid structure, is rotatably stored about a horizontal axis 12 on the support structure 10, which also forms a rigid structure, the fish container 11 being rotatable radially within the ring-shaped main part 10a of the support structure. The fish container 11 is arranged concentrically or largely concentrically around a transverse bracing part 10b in the main part 10a of the support structure.

The support structure 10 can, for example, be produced in sections and assembled together to form a continuous structure in one piece or produced directly in one piece. Float-forming components can be produced which are assembled together into a uniform construction using a common casting process with the finished construction of the construction directly at sea. The construction is preferably made of reinforced concrete, for example with a significant proportion of the supporting structure's 10 volume made of concrete with a low specific weight (0.5-0.7), while other, less voluminous, tension- and pressure-absorbing parts of the supporting structure, which contains the significant proportion of the reinforcement, can be made of concrete with a somewhat higher specific gravity (1.0-1.3). A rigid structure can be produced in one piece of concrete with associated reinforcement, but with sufficient built-in buoyancy to support both the support structure 10 and the fish container 11 as well as other equipment. However, it is ensured that the buoyancy does not become greater than that the supporting structure with associated fish tank, etc. can be pulled downwards into the sea to a fully submerged state, without too much force being exerted.

In that in fig. 1 and 2, the support structure 10 is designed largely Ø-shaped (buckle-shaped), calculated in the horizontal center plane of the support structure, i.e. the circumferential part or the main part 10a of the 0-shape is shown circular-ring-shaped, while the cross-step part or stiffening part 10b of the Ø-shape is shown running diagonally inside in the ring shape. In this exemplary embodiment, the fish container 11 is designed with an approximate spherical shell shape, so that it can be rotated about the bracing part 10b, i.e. about the horizontal axis 12, and moved inside the Ø-shaped recesses relatively close to the main part 10a of the support structure.

Instead of a spherical shell-shaped fish container, for example, a cylindrical shell-shaped fish container can be used, with a corresponding rectangular 0-shape (buckle shape) on the associated support structure. Alternatively, different intermediate solutions between spherical shell shape and cylindrical shell shape can be used.

The fish container 11 is formed by two stationary, circular, disk-shaped end pieces 13 and 14 placed on the support structure, as well as an intermediate main structural part 15, which is rotatably supported on the end pieces 13 and 14 and which together with these form the aforementioned fish container 11.

The end pieces 13 and 14 are preferably cast or otherwise rigidly connected to the support structure 10 in the transition between the main part 10a and the stiffening part 10b. The end pieces 13, 14 can, at the same time as achieving effective stiffening and repulsion in the supporting structure's main part 10a and stiffening part 10b, also serve as effective stiffening and repelling for the supporting structure in said transition between the main part and the stiffening part. A closable entrance door 16 provides access from a walkway 17 on the main section 10a to a walkway 18 on the bracing section 10b. Dashed lines 19 indicate specially reinforced parts of the end piece 13, the entrance door 16 being adapted in a space between the reinforced parts 19.

The main structural part 15 is made up of a frame and/or rib structure, which comprises a number of circular, spaced apart, parallel rings 21 and rows of cross pieces 22 which connect the rings in pairs with each other. In the example shown, the cross pieces run flush with each other in each row, but may possibly have a different course, for example a zig-zag course calculated in the direction across the rings. In fig. 1 shows an example with six rows of cross-pieces, but in practice a larger (or smaller) number can be used as required. In a preferred embodiment, the rings 21 and the cross-pieces 22 are made of tubes, which can for example be filled with filler and which can be adapted to have a specific gravity of approximately 1.0, or not significantly greater than 1.0. In general, the aim is that the weight of the fish container (calculated for the part that is placed above sea level) does not exert any significant weight load on the support structure, while there is negligible buoyancy from the part of the fish container that is submerged in the sea. It is preferred that the frame and/or rib structure of the fish container includes a pair of opposite, particularly solid end rings 21a and 21b with which the main structural part 15 forms support against the peripheral edges of the end pieces 13,14. The storage itself is not shown in more detail, but sliding bearings or possibly roller bearings can be used between the end pieces 13, 14 and the end rings 21a, 21b at the same time as axial control is established between the same by means of control means known per se.

In the embodiment shown in fig. 1 and 2, an outer cladding layer 23 and an inner cladding layer 24 are used which are attached separately to each side of the spherical shell-shaped main structural part. The inner cladding layer 24 consists of ordinary net-shaped material which provides efficient water flow through the main structural part. Optionally, the cladding layer 24 can be delimited piece by piece, so that the pieces can be assembled and disassembled separately, as required. The outer cladding layer may consist of different types of cladding material, including ordinary net-shaped material, especially reinforced net-shaped material, dense but flexible and reinforced or unreinforced cloth material, plate material, etc. The outer cladding layer may at the same time have different cladding material in different areas, as needed, and is designed to be replaceable, also as needed, depending on the conditions of use at the individual place of use.

By letting the device float on the sea surface, as indicated in fig. 1, it is possible to turn the fish container's main structural part to a desired position above the sea surface

for inspection, cleaning, repair and replacement of cladding material locally as required. In addition, under changing conditions of use, for example when there is a risk of algae attack in certain layers of the sea surface, shield-forming cladding parts can be swung downwards into the sea to protect the farmed fish in the fish container. The aforementioned rotation of the fish container need not have a negative effect on the contents of the fish container, as the volume of water can be kept largely constant in the fish container by such rotation.

During maintenance work, etc. in connection with the external cladding layer, this can be done on the outside of the fish container from the walkway on the main part 10a of the support body, while feeding the fish in the fish container as well as other incidental work, including maintenance work in connection with the internal cladding layer, can be carried out on the inside of the fish container from the walkway on the support member's stiffening part 10b, respectively from the walkway on a pontoon 26 that can be pivoted about a vertical axis 25.

In fig. 3 and 4, an alternative embodiment is shown where, instead of a pivotable pontoon 26, a stationary fixed, rigid inner ring 27 is used which runs concentrically with the main part 10a on the inner side of the fish container, i.e. with the fish container freely pivotable in a gap which is delimited between said main part 10a and inner ring 27.

In fig. 1 and 2, a few tensile members or bar dunnages 28 are shown which are anchored individually to the support structure 10 with suitable intervals and which are fixed in the seabed 29 in a common fastening member 30.

Although it is not specifically shown here, it is obvious that precursors, oxygen, temperature-regulated water, etc. can be added. via per se known supply devices for the farmed fish in a partially or fully automated system. This is particularly relevant at such farming facilities where the fish container must be able to be stored submerged in the sea for longer periods of time. The necessary routines in connection with raising fish, including feeding, visual and other monitoring of the behavior of the fish in the fish tank, monitoring of fouling on the fish tank, etc., can take place by remote control of the relevant equipment. Such apparatus can be permanently connected to the support structure's bracing part 10b and/or to said pontoon 26 or said inner ring 27. Optionally, the apparatus can be adjustable in different positions in the fish container as needed, regulated by remote control. The aim is therefore to be able to keep the fishing container in a floating state on the sea surface or submerged below the sea surface for longer periods of time, based on remote control.

In fig. 6 and 7 shows a facility where two (or more) fishing nets according to the invention can be submerged separately in the sea to a suitable level below the sea surface or held in place in a specific position on the sea surface, controlled from a common control center 31 on a common wire reel -similar construction 32 which floats separately and vertically positioned in the sea.

In fig. 6, a foundation 33 is shown which is placed on and anchored to the sea bed 29. The two shown fish ponds 10,11 are in a similar way to that shown for the fish pond according to fig. 1 and 2 respectively fig. 3 and 4 equipped with tension members or bar feathers 28 which are attached to a common fastening member 30. From the fastening member 30, a tension member 34 runs via guides 35 in the foundation 33 upwards to and through guides 32a in the construction 32 to the top of this to an associated pulling member 36 At 37, an anchoring line is shown between the construction 32 and the foundation 33.

In fig. 6, one of two fish ponds is shown submerged at a certain level below the sea surface, while the other fish pond is shown at a level on the sea surface, i.e. in a floating state on the sea surface. The fishing nets can be lowered and lifted independently of each other with the help of each of their tension-regulating pulling devices.

In fig. 7 shows a similar arrangement where the structure 32 and the foundation 33 form part of a continuous structure 40. In a similar way as in fig. 6, for illustrative reasons, one of two fish maws is shown in a submerged state, while the other fish maw is shown in a position floating on the sea surface. In fig. 7, the foundation 33 in the structure 40 is shown at a level above the seabed, as anchoring members 41 and 42 are attached to the seabed via fasteners 43 and 44. At 45, vector gauges are shown for tightening the anchoring members in the event of a springing sea.

Claims (10)

1. Device at a fish pond (10,11) for farmed fish, comprising a rigid, ring-shaped support structure (10) with associated floats or other float-forming equipment as well as a water-flowable fish container (11) attached to the support structure, characterized by that the fish container (11) is in the form of a hollow body of rotation with a cavity through which water can flow, but which is otherwise closable via separate access opening(s) (16), to accommodate the farmed fish in a quantity of water in the fish container, and that the fish container (11), or at least parts (15) thereof, is rotatably stored in the support structure (10) about a horizontal axis (12) which runs across the support structure approximately in its mid-plane, for setting the fish container (11) in different pivot positions in relation to the support structure (10), in that at least a large proportion of, and preferably approximately half of, the fish container's volume is submerged in water and a further large proportion of the fish container which projects upwards above the support structure, forms a roof structure over the submerged part of the fish container, while the support structure floats on the surface of the sea. 2. Device in accordance with claim 1, characterized by that the fish container with associated support structure is designed to, for example by means of traction means, be submerged to a suitable level below the sea surface, to form an increased fish container volume. 3. Device in accordance with claim 1 or 2, characterized by that the support structure is equipped with a transverse bracing part that runs close to or coaxial with the fish container's axis of rotation, to form a section of walkway that runs transversely in the fish container. 4. Device in accordance with requirements 1, 2 or 3, characterized by that the supporting structure has an approximate Ø-shape in its central plane, possibly with a first external ring-shaped walkway section and a second internal walkway section with an intermediate slot for accommodating the main section of the fish container, and that the fish container has an approximately or largely spherical cavity, i.e. a circular or largely circular ring shape calculated in a radial plane and from a polygonal to a circular or approximately circular ring shape calculated in an axial plane. 5. Device in accordance with one of claims 1-4, characterized by that the fish container is formed by two stationary fixed to the support structure, mutually opposite, preferably rigid end walls with an associated closable access opening to the interior of the fish container and by an intermediate part rotatably mounted on the end walls, which forms the water-permeable part of the fish container. 6. Device in accordance with claim 5, characterized by that the water-flowable fish tank part is formed by a rigid frame and/or rib structure which is covered with groove-forming material, preferably with an external, particularly resistant, possibly reinforced groove-forming material and with an internal groove-forming material that can be more easily dismantled. 7. Device in accordance with claim 6, characterized by that the frame and/or rib structure is designed to, for example locally delimited in certain zones on the rotatable part of the fish container, form a carrier for flow shield-forming and/or heat- or cold-protective cloth or plate material. 8. Device in accordance with claim 6 or 7, characterized by that the frame and/or rib structure comprises a series of mutually parallel stiffening rings which are arranged at a certain distance from each other concentrically about the axis of rotation of the fish container, including two mutually opposite end rings with which the frame and/or rib structure is rotatably supported on the support structure, as well as rows of stiffening members that run across the stiffening rings and connect these in pairs with each other. 9. Device in accordance with claim 8, characterized by that the frame and/or rib structure is made of pipe material, preferably with a perforated pipe wall. 10. Device in accordance with one of claims 1-9, characterized by that the supporting structure is made of reinforced concrete with a specific gravity of from 0.5 to 0.7, and that the fish container's storage devices are made of reinforced concrete with a specific gravity of from 1.0 to 1.3.