NO811673L - PROCEDURE AND DEVICE FOR UNDER-SQUARE Aquaculture - Google Patents

Description

The present invention relates to a method and device for underwater culture, by placing in deep water in the order of 25 to 40 metres, a closed enclosure in which fish are reared, and to feed and monitor the fish from a more distant installation on land or at sea, as the bringing in of fish, their sorting and their collection is carried out by divers.

The enclosure is preferably a flexible enclosure, made of a net and equipped with sinkers and flotation devices which maintain it in its shape. Food is supplied from a fixed installation via a flexible or rigid pipeline, in which divided or granulated food (powdered fish food) is transported using water under pressure. Monitoring is ensured using a hydrophone unit.

The invention will now be described in more detail with help

by way of example and with reference to the drawings, where:

Fig. 1 shows a schematic view of a complete aquaculture installation. Fig. 2 shows a perspective view of an element of a fish enclosure.

Fig. 3 shows a schematic front view of an element

in accordance with fig. 2, in a position where it is not in contact with the bottom.

Fig. 4 shows a front view of an element in accordance with fig. 3, in which, however, in contact with a sandy bottom for farming flat fish. Fig. 5 shows a side view of several elements in accordance with fig. 3, put together. Fig. 6 shows a side view during the emptying of an installation as shown in fig. 5.

Fig. 7 shows a partial view of the feed pipeline.

Fig. 8 shows a schematic view of the beginning part of the feed pipeline. Fig. 9 shows a diagram of a first embodiment of the distribution box.

Follow 10 shows a diagram of a second embodiment

of the distribution fund.

In all the examples that will be described hereafter, it is assumed that the aquaculture is placed in salt water, but it is clear that the method and the device can also be used in fresh water.

Fig. 1 shows a general outline of an installation according to the invention, which includes a feeding device, a monitoring station A, on land, not far from the shore. A flexible feeding pipe B, a distribution box C, an enclosure D, in deep water, enclosure E for flat fish that burrow into the bottom, a rigid movable enclosure F for transporting fish.

The fish is retrieved by using the enclosure F which is rigid and preferably includes penummatic devices and sinkers, such as those described in French patent no. 77.34100, and French application no. 78.31951, which are provided with stabilization either near the seabed, without touching the bottom as shown, or near the surface where it is stored from the port.

The fish are then introduced with the help of divers into enclosures E or D, depending on whether they are flat fish that burrow to the bottom, or round fish, i.e. normal free-swimming fish. The enclosures D and E are flexible, made of a net, and are stabilized either in the middle of the water without touching the bottom, as is the case with the enclosure D, or stabilized in contact with the bottom, as is the case with the enclosures E.

When the fish are in enclosures D and/or E, the fish are fed from station A by means of pipeline B and distributor C without the need for any human intervention.

The fish are then taken from enclosures D and E by divers into the mobile, rigid enclosure F, which is brought back to the surface and towed to the port.

Fig. 2 shows an element 1, for casing D. or E, the casing being made of at least one element such as 1 and generally of several elements which are put together to form a casing.

Said element 1 is a large net pocket 2, with a cross-sectional shape of a crescent. The net is maintained in shape by means of beams > two side beams 3, two end beams 4, and a unit of cross beams 5 and 6,' which are curved. The upper beams 5 are made with rafts 7, while the lower beams are made with lead or other types of sinkers 8. The beams 3 are made with fastening rings 9, at the crossing points between the beams 5 and 6, since the beams 4, is made with other fastenings. The unit with the mooring rings 9 is placed in a horizontal plane that crosses the enclosure volume formed by means of the element 1. Any current, turbulence in the sea and drifting bodies impinging on the enclosure will deform it without obstacles, either above or below the horizontal plane around which the fixed points for the mooring nines are distributed. For the sake of clarity, the floating body 7 and the sinkers 8 have been shown in fig. 2 only on a beam 5, and a beam 6, but preferably all the beams are equipped with these. On the other hand, the leads 8 can all be replaced with other types of sinkers, e.g. with a lead rod sewn to the beam 6.

To the eye holes 9 (attachment rings), are at least

at two of the element l's ends, moorings 10 are attached to fixed bodies 11. The fixed bodies 11 are spaced so that the moorings 10 and the beams 3 are tightly netted. The floating bodies 7 and the sinkers 8 keep the beams 5 and 6 in shape.

The element 1 is preferably designed at their ends with two openings 12 and 13, at its upper part and at the center with an opening 14, made with a door and two similar openings 15 and 16, in the upper layer, as well as their symmetrical elements in the lower layer.

Fig. 5 shows several elements such as 1, 1a, etc. connected at the ends by means of tunnels 17 and 18 corresponding to the openings 12 and 13. The moorings 10a and corresponding fastening bodies 1a are arranged to thus retain the entire unit.

Such a unit is immobile due to the moorings

and the fastening bodies 10, 11, 10a and 11a, but is flexible in that it is made in net and beam, and can be deformed by the influence of underwater currents and waves, while it maintains its general shape by the combined opposite effect ning of the floating bodies 7 and the sinkers 8. If it is desired to breed fish that do not belong to the demersal type, the moorings 10 and the fixed bodies can be placed so that the bottom of the elements 1, la ... do not touch the bottom. If it is desired to breed demersal fish that burrow into the bottom, very short moorings 10 are placed, so that the net is in contact with the bottom for practically the entire length of the beam 6, and water turbulence over the bottom - they can be natural or produced by artificial installations in the environment (obstacles), or produced instinctively by the fish when they "ventilate" with their fins - will quickly bury the net in the sand or mud. The fish will have the opportunity to burrow without coming out of the net. This arrangement is shown in fig. 4 (enclosure E). Fig. 5 and 6 show two rearing phases for fish swimming in the water, the elements 1, la corresponding to the enclosure D in fig. 1. Floating bodies 7a, which have sufficient buoyancy to maintain the net, are preferably placed at each end of the end beams 5, the part that makes up the second beam 7 is only to keep the beams 5 in their shape. The floating bodies 7 can be produced as described in the previously mentioned French patent application No. 78.31951, which means that they can be deflated by turning them over. Thus, a diving team can empty all the floating bodies 7, to the end beams 5, to an enclosure D for air, so that the net 2, collapses, and then by continuing step by step as shown in fig. 6, the fish is progressively driven out of element 1 towards element la, by passing through the tunnels 17 and 18. If adjusted gates have been previously placed in the tunnels, a type of fish can be sorted out in this way. ;It is also possible to disconnect the tunnel 17 and/or 18, and put them in connection with the enclosure F which has been brought to the adjacent element 1dg, thereby transferring all the fish to the enclosure F. To displace the enclosure F, it is sufficient to inflate a of its ballasts, so that it gets slight positive buoyancy and thereby allow movement of it to the desired position where it is brought back to a negative buoyancy. ;To bring back the elements 1, let ... to their original shape, it is sufficient to blow air back into the floating bodies 7, either via a pipeline from the surface or by the divers' air cylinders.. ;One can also arrange net pockets at the bottom or over net 2, in order to collect floating dead fish or those that sink. ;Furthermore, by using divers, the moorings 10 can be disconnected from the fixed bodies 11, and the entire unit 11, la etc. thereby bringing the entire installation back to the surface. The casing then floats freely/and it can assume a slack shape that allows it to be emptied on board a ship. As soon as it is on the surface, it is also possible to attach tensioning parts to such casings which maintain them in approximately the same shape. The tensioning parts can be produced, e.g. of rigid arches of a circular unit by means of cross-pieces and attached to the ends of each casing. Each enclosure can then be moored to a surface buoy or also towed, as the fish in the enclosure have sufficient room for movement. The openings 14, 15 and 16 may be provided with rigid doors which are removed to open them, with doors made of a mesh or simply closed by means of associated rigid fibers running from the two opposite sides and which are tied together in the middle of the opening. ;The necessary feed for the rearing of the fish is transported to the enclosures D and/or E by means of the pipeline B, which goes out from the station A, and reaches the distributor C, from which several pipelines emerge, leading into one of the enclosures D and/or É. Pipeline B carries pre-particles or pellets in the water and is therefore pushed by the water so that it is only necessary to apply pressure at the end of the hose at location A to transport the pellets as far as desired. It is known that fish must consume fresh water that they find in the prey that they consume. When they are lined with pellets, it is necessary to add fresh water to the pellets before they are taken to the seawater. If they are consumed quickly enough, they still contain enough fresh water. According to the method, which is the subject of the present invention, a pillow of pellets in fresh water is brought to circulate in the pipeline B, and is moved forward by driving the water and pellets from the station to the enclosures. The pad with pellets and fresh water is preferably placed between two areas filled only with fresh water. ; On fig. 7 shows a section through the hose B, shown in area 0 with a length "1" of the hose filled with pellets and fresh water, two areas M and N with the length "m" only filled with fresh water, the other areas P and Q until the hose is filled with seawater. In the example shown, the length m is equal to the length 1, but this is not an absolute condition. In some cases, the length m may be equal to 0. ;Fig. 8 shows that in the starting position at station A, the pipeline B, whose diameter can be a few hundred mm, such as 40 mm, includes a diaphragm pump 20, and a pressure trap 21. Upstream of the pump 20 is a pipeline B, connected by three pipelines, 22, 23 and 24, with valve ports 25, 26 and 27, being arranged upstream in relation to these, tanks 28, 29 and 30. Tank 28 is filled with seawater, tank 29 is filled with a mixture of pellets and fresh water, the tank 30 is filled with fresh water. The gate 25 is opened first, and the pump 20 is started. Then gate 25 is simultaneously closed and gate 27 is opened for a rather short period, and then gate 27 is closed and gate 26 is opened, also for a rather short period, and then gate 26 is closed again and gate 27 is opened again. There is thereby provided i:?>?;/7Æ/f,i?,1\?-7/?)n jE f,{?j!.7.e,nd-e f orde m.ng: Sea water ( area Q) , ;fer s* va.-./, hjz- rJr% X,, p',))'-. <y far& vføir tfWMfr Of, ffiffå water (area N) , sea water (area P) . fy.-t' ÅZ\p& pu((\ p<ii f, fif-water into the pipeline B for a period tilatrekkolig iarifj to drive the areas N, 0, M to the breeder enclosures.'

This operation can be repeated many times, and this makes it possible to bring in several partial portions, which is the most efficient way of feeding fish, regardless of the weather and conditions on the lake.

When there is only a single breeder enclosure, the pipeline B is led directly into the enclosure. Where there are several casings, the pipeline B is led to a distributor C, as shown in fig. 9 and 10.

In fig. 9, it is shown that the pipeline B enters

in a box 31, cylindrical, the cylindrical wall being designed with several openings 33, each connected by a pipe B<1>, preferably of the same diameter as B, each pipe B' serving the enclosures D or E. Pipe B is led to a turning connection 35, to a jack 34, rigidly connected with a catch device attached to the connecting rod 35, to a jack 34, fed by a small control line 36, connected to the pipeline B. At the bottom of the turning connection 31a, attached a bent tube 32, the end part of which is fed into the front splines 33. When the jack is fed by the control line 36, the connecting hose 35 rotates to the hose 32 over the part of a revolution necessary to pass from one. hole 33 to the next. From station A it is therefore possible to control the passage from one pipeline B<1> to another.

It is also possible to carry out all these operations automatically for starting the pump, opening and closing the ports 25, 26 and 27, and putting the pipeline 36 under pressure.

According to an alternative embodiment (Fig. 10),

the rotary hose placed in the box 31 can be connected to the bottom of the box and bent Z-shaped, in order to thus move under the inner flat plate of the cover which is tied with the pipeline B'.

Instead of placing an additional pipeline 36,

one can connect the jack 34 to the pipeline B by placing an adjusted overpressure valve. When the pressure that prevails in pipeline B, normally here the valve is closed, and the jack is not affected. When an over-

pressure in the hose B by increasing the flow rate to the pump 20, the cross-section of the pipeline B is reduced (loss of load), or both at the same time and the valve is opened, and the jack 34 is affected.

In order to ensure that the change from one pipeline B<1> to another has really been carried out, it is preferably advantageous to place the catch device for the turning connection 31a, so that for a full working layer of the connecting hose 35, the hose 32 (37) is turned only half revolution, necessary for leading from one hole to another, as the current saw

is stopped and the pressure is increased strongly in the pipeline B, as this is detected by the pressure arrester 21, the pressure is then allowed to fall and thereby the jack 34 (made with a return spring) can assume its former position, and the pressure is then put back on, which in turn operates the jack. It is then ensured that the swivel hose has really passed from one opening to another.

To control the breeding, hydrophones of known types are placed in the enclosure D and/or E, which record sounds which are then sent after amplification to one or more loudspeakers placed at station A.

This device allows sounds to be recorded which indicate: - the arrival at the end of the pipeline B<1> of a current and therefore for; the vivacity of the fish, and therefore their state of health, or whether a panic has occurred by accident, or by their disappearing through a hole in the net; - the presence of divers; - the arrival and departure of boats in the area.

The enclosures D. and/or E can thus be placed at a great distance from land, up to 5 km for example, and on the bottom which can be as deep as is usually the normal limit for underwater diving, i.e. around 50 metres, but the is clear that it is easier to limit yourself to depths of 25 meters and to distances of the order of one km.

Claims (29)

1. Method of underwater aquaculture, characterized in that it is placed in a.-stable way at an important depth, but within a diver's reach, one or more flexible closed enclosures made of a net, maintained, in shape on one side of the sinker, and on the other side of floating devices, placement of fish to be reared in the enclosures, and by feeding them from a more permanent installation on land or at sea, by means of a pipeline placed on the seabed. 2. Method according to claim 1, characterized in that the fish are sorted out, cleaned, brought into place, cared for with the help of divers. 3. Method according to claim 2, characterized in that the enclosures are emptied by divers by flattening the enclosures. 4. Method according to one of claims 1-3, characterized in that various feeding operations, diving operations, and the movement of boats and the activity of the fish are monitored by hydrophones. 5. Enclosure for carrying out the method according to one of claims 1-4, characterized in that it is made of at least one flexible closed element (1), made of a net (2), which has a cross-section in the form of a crescent. as the net is placed on beams (3, 4, 5 and 6), as the upper transverse beams (5) are connected to float devices (7) and the lower transverse beams (6) are lowered (8) . 6. Enclosure according to claim 5, characterized in that it consists of several elements (1, la, etc.) connected to each other by means of tunnels (17, 18). 7. Enclosure according to claim 5 or 6, characterized in that each element (1, la, etc.) is connected by means of moorings (10) to fixed bodies (11), sufficiently spread out with a distance to maintain the shape of the elements (1, la, etc.) to maintain the end beams (3) taut. 8. Wrap according to claim 7, characterized in that the attachment points for the moorings (IQ) of the wrap are made of rings (9) arranged in the central horizontal plane of the wrap. 9. Enclosure according to one of claims 5-8, characterized in that the moorings (10) are sufficiently long so that the bottom of the net (2) and the lower beam (6) do not touch the bottom. 10. Enclosure according to one of the claims 5-8, characterized in that the moorings (10) are sufficiently short so that the entire part which forms the bottom of each element lies against the bottom, and over time is buried under sand and mud. 11. Method for carrying out enclosures according to claim 10, characterized in that small artificial barriers are placed around each enclosure, so that the current deposits a sedimentation layer on the lower part of the net. 12. Enclosure according to one of claims 5 - 11, characterized in that it includes, at its top part and its bottom part, pockets for receiving floating, dead fish and sinking, dead fish. 13. Method for emptying fish from the enclosure according to one of claims 5-12, characterized in that the buoyancy of floating bodies (7) is reduced by filling it with water, so that the upper wall of each element comes against the lower wall when sinking. 14. Method according to claim 13, characterized in that the row of floating bodies (7) is removed step by step, so that the elements flatten together progressively and thereby drive the fish away. 15. Procedure for bringing in fish according to requirements. 13 d 14, characterized by the fact that the last pocket to be emptied is brought into connection with a rigid mesh casing (F) with ballast dg sinking seam can be set in positive, negative or neutral buoyancy, in order to be able to move this easily close to the bottom, and tow it to the port on the water surface. 16. Method for providing one or more enclosures according to claims 5-12, characterized by disconnecting the mooring (10) from the ring (9), so that under the influence of floating bodies (7), they return to the surface and float freely by assuming a soft shape that enables emptying from a boat. 17. Method for providing one or more enclosures according to claims 5-12, characterized in that the moorings (10) are disconnected from the rings (9), so that under the influence of floating bodies (7) they return to the surface, where they are equipped with tension members which maintains them essentially in their original shape so they can be moored to a surface buoy and towed. 18. Procedure for feeding fish that are inside the enclosure placed in the sea, characterized by. that the material is sent in the form of particles or pellets by means of pumping into a pipeline connected to a fixed station on land or sea to the enclosure. 19. Method according to claim 18, characterized in that a pad of pellets is introduced into fresh water (0) between two seawater streams (P and Q). 20. Method according to claim 18, grade i in that a cushion of pellets in fresh water (0) is introduced between two liquid cushions of fresh water (M and N) which are in turn enclosed between two seawater liquid streams (P and Q). 21. Device for carrying out the method according to claims 1-4 and 18-20, characterized in that it is made of a flexible or rigid pipeline (B) placed on the seabed, which goes out from a control station (A), placed on land or to by sea, and which has been taken to the enclosures (D or E). 22. Device according to claim 21, characterized in that the pipeline is connected in its starting position to a seawater source (29), a source of pellets and fresh water mixture (29), and a source of fresh water (30), equipped with valve ports. (25, 26, 27). 23. Device according to claims 21 and 22, characterized in that the pipeline opens into a rotary distributor (C), from which protrude as many secondary pipelines (B') as there are casings (D or E). 24. Device according to claim 23, characterized in that the rotation distributor is made of a cylindrical box (31), into which rotates a bent pin, (32-37) connected to the inlet pipeline (B), and whose end is led into the front of the opening ( 33) each of which is connected to the secondary pipeline (B\). 25. Device according to claim 24, characterized in that the movement of the rotation hose (32, 37) is controlled by means of a jack (34), which drives a catch device (31a). 26. Device according to claim 25, characterized in that the capture device provides at each stage a rotation that corresponds to half the distance covered by the two openings (33), thereby causing once out of two a pressure increase in the pipeline (B), which is detected in the station by means of a misprint. 27. Device according to one of claims 25 or 22, characterized in that: the jack (34) is fed by means of a special pipeline (36). 28. Method according to one of claims 25 or 26, characterized in that the jack (34) is. connected to the pipeline (D) via an adjusted valve. 29. Device according to any one of the preceding claims, characterized in that the enclosures (D and/or E) are made with hydrophones connected to the station (A).