NO314682B1 - Cultivation plants for aquatic organisms - Google Patents

Description

CULTIVATION FACILITIES FOR AQUATIC ORGANISMS

The invention relates to a submersible pipe concept, cultivation pipe, for the cultivation of aquatic organisms, such as shells, snails and the like.

Background for the invention

Today, longlines are mainly used for the cultivation of mussels, scallops, oysters and the like. Such longline stretches consist of so-called longline buoy stretches, these are in principle made up of buoys that carry a mainly horizontal rope on which mussel collectors and cages are hung. The buoy lines can be stretched between two transverse girders which lie in the sea and which are further held by each mooring line. There are several significant problems associated with this technology: Loss of a blower or a puncture means that the entire system

sinks.

At sea, you get movements on the bubbles that propagate down to the organisms, this causes shells to fall

of or you get poor growth.

The system represents a visual pollution, many

do not want to see such facilities on the coast.

Equipment such as collectors, cages etc. are attached to the carrying line which is constantly under water. Operation of the facilities then means that the system must be lifted out of the water

availability.

In conventional mussel systems, the collectors are attached to a horizontal support line either by tying them firmly, or they are attached with various types of clips.

Known technique

NO 800467 relates to elongated buoyancy bodies with attachment devices in the form of attachment hooks or islands for cultivation elements on the underside of the buoyancy devices. The buoyancy can be regulated. The entire buoyancy body with ropes or stockings for shells must be lifted using a hoist boom and adapted straps to put it out in the desired area in the sea, for inspection, or to harvest fully grown shells. Attachment hooks or eyes for cultivation ropes or stockings are attached to the underside of the buoyancy body by welding or clamps. A fleet of such operating elements comprises several shorter pipes (3-6 m) which must be connected together. The pipes can be made of plastic.

EP Al 137087 relates to an elongated buoyant body with fastening devices on the upper side of the buoyant body for attaching cultivation elements. The buoyancy can be regulated. The cultivation plates for shells are exchangeably attached to a buoyancy body in the form of a rigid tube.

The invention briefly summarized

A solution to the above-mentioned and other problems existing cultivation facilities is a cultivation facility for aquatic organisms comprising extensive buoyancy means for cultivation elements hanging in the sea, where the buoyancy means comprise at least one elongate buoyancy body where at least one elongate, mainly continuous attachment comb is arranged along the upper side of the buoyancy body in its normal floating position, where the attachment comb extends substantially the entire length of the buoyancy body, and where the attachment comb comprises a number of attachment devices for attachment of cultivation elements.

Other advantages of the invention appear from the associated subordinate claims.

According to a preferred embodiment of the invention, the cultivation facility comprises that the fastening devices comprise an elongated fastening comb with a mainly rectangular cross-section.

According to another preferred embodiment of the invention, the fastening devices comprise recesses or slots for fastening the cultivation elements.

According to a further preferred embodiment of the invention, the fastening devices comprise elevations for fastening the cultivation elements, preferably so that the recesses comprise continuous, preferably crosswise cuts formed in the elongated fastening comb.

According to yet another preferred embodiment, the recesses comprise slanted cuts formed in the elongate fastening comb.

According to yet another preferred embodiment, the recesses may comprise local groups of two or three shards formed in the elongated fastening comb.

According to yet another preferred embodiment, the cultivation elements can comprise at least one line fixed in the fastening device, but the cultivation elements themselves can also be suspended directly in the fastening devices, e.g. in that notlin or a ladder is hung directly in the recesses or notches in the fastening device.

For a cultivation tube, the continuous cultivation elements, also called the collectors, can be laid in a zigzag pattern over the tube, fixed in grooves on the comb. Release and harvesting can then take place from the surface. Attachment to the carrying line is avoided.

For cultivation tubes, it is achieved that the cultivation units are attached above the water surface. Availability will be very good, release and harvesting, inspection will be significantly simplified.

The cultivation tube can be lowered, thus reducing wave-induced movements of the structure and the organisms, the risk of damage is also reduced and the plant is normally not visible on the surface. This is achieved according to the invention by using a pipe which is equipped on the upper side with a fastening device for equipment, and by the fact that the pipe can be easily raised/lowered using compressed air.

The market may be the largest for mussel farming. This can mainly take place with permanently floating pipes that do not need to be lowered except in exceptional situations such as to avoid pollution or unfavorable temporary conditions.

Drawing overview

The invention is illustrated in the accompanying figures which are not to be understood as a limitation of the invention. Fig. 1 illustrates a buoyancy body in the form of a tube with fastening devices placed along a rectangular strip along the side of the tube which is to face upwards. Fig. 2 illustrates cultivation elements 4 which are shown here hanging in lines 8, e.g. in the form of a cage 9. Anchoring or weight loading and weight stabilization are also shown. Fig. 3 illustrates that a line 8 in itself can constitute

cultivation element for shells.

Fig. 4 illustrates a simple cultivation facility where a buoyancy body is provided with cultivation elements and placed in a submerged position by means of anchoring cables or plumb bob 10, and where the pipe can be brought to the surface by means of injection of compressed air at one end. Fig. 5 illustrates an inner tube which can be a permanent buoyancy body or which can be filled and emptied with water to regulate the buoyancy. Fig. 6 illustrates two alternative embodiments of a

air hose 14.

Fig. 7 illustrates an outrigger for lateral stabilization against rolling (and lateral movement) of the buoyancy element 1 and its attachment cam. Fig. 8 illustrates an embodiment of the invention where there are knots on the line to keep the line from slipping in the notches. Fig. 9 shows a way of attaching the line in three and three notches

the attachment comb.

Description of the preferred embodiment of the invention

The cultivation tube according to the invention is shown in drawing i

Fig. 1 and shows part of a cultivation facility for aquatic organisms comprising extensive buoyancy means for cultivation elements 4 hanging in the sea, where the new thing about the invention is that the buoyancy means comprise at least one elongated buoyancy body 1 with at least a number of attachment devices 2 arranged along the upper side of the buoyancy body in its normal floating position, for attaching cultivation elements 4. According to a preferred embodiment of the invention, the attachment device comprises an overlying outer flange or comb, for mounting cultivation units, all described below.

According to a preferred embodiment of the invention, the fastening devices 2 comprise an elongated fastening comb 3 with a mainly rectangular cross-section, as shown in Fig. 1 and 2. The fastening devices 2 may comprise recesses 5 and/or sticks/elevations 6 for fastening the cultivation elements 4.

According to a preferred embodiment, the recesses 5 run through, preferably transversely oriented shards 7 formed in the elongated fastening comb 3. If the shards lie closely along the fastening comb 3, the remaining parts of the fastening comb between the closely spaced shards make up the elevations 6. There can be slanted shards 7 formed in the elongated fastening comb 3 so that a larger friction surface occurs against a line 8 which is laid in the grooves and holds the cultivation elements 4 or which make up the cultivation elements 4.

A preferred embodiment of the invention comprises local groups of two or three shards 7 formed in the elongated fastening comb 3, as shown in Fig. 3, where the line 8 is laid through two and two shards and where the line 8 hangs down into the sea alternately on the one and on the other side of the float tube l.

In Figure 9, it is shown how there are three slits 7 cut out in the fastening comb 3 so that the line is passed twice through the fastening comb and is thus attached faster and with more friction, and generally runs from one side to the other of the float tube 1.

In a preferred embodiment of the invention, the cultivation elements can be formed by the line 8 in that points with a substantially uniform first distance along the line 8 are fixed in recesses 5 with a substantially uniform second distance along the fastening ridge 3, where the second distance is shorter than the first distance as that the line hangs like loops or a chain line down from the fastening comb. The shells can then grow directly on the line. In another embodiment of the invention, the cultivation elements 4 can comprise a cage 9 which hangs from the line 8.

In a preferred embodiment of the invention, at least one line can hold anchoring elements 10 for anchoring the cultivation facility. These anchoring elements can be plumb, but in an advantageous embodiment the anchoring elements 10 comprise chain as illustrated in fig. 2, because the chain provides a soft and variable weight load in that the joints that have settled on the bottom at all times do not contribute to anchoring weight, and thus provide a passive damping of the cultivation facility's vertical movements.

Figure 5 shows a preferred embodiment of the invention, where a preferably fixed inner pipe 16 for air or water is arranged, for regulating the buoyancy of the buoyancy body 1, arranged inside the buoyancy body 1 and running mainly along the entire length of the buoyancy body. The inner tube 16 can form a solid buoyant body, e.g. filled with solid fluid or pressurized with air. According to a preferred embodiment shown in fig. 4, an air hose 14 is arranged at a first end of the buoyancy body 1, designed to fill or empty the buoyancy body 1 with air. Fig. 6 illustrates two alternative designs of an air hose 14: a connection to the inner tube 16, or a connection to the complementary space of the buoyancy body outside the inner tube 16.

According to one embodiment of the invention, the air hose 14 is arranged at a first end of the inner tube 16, designed to fill or empty the inner tube 16 or the part of the buoyancy body 1 that is not formed by the inner tube with air, and a second end of the buoyancy body 1, opposite to it first end, is open to the sea and preferably located somewhat deeper than the first end as illustrated in figure 4. Air can be pressed in via a compressor on the surface through the air hose 14 mounted on the shallower part of the buoyancy body 1 and gradually fill it with air, and water is driven out through openings at the opposite end of the buoyancy body. In this way, the tube can be raised and lowered by releasing air via the air hose 14. If the inner tube 16 is permanently air-filled or fluid-filled, it can constitute the permanent buoyancy of the buoyancy body 1. Conversely, the inner tube 16 can be connected to the air hose 14 and be filled and emptied for air, and the surrounding space in the buoyancy body 1 be permanently filled with air or floating material (or also yarn balls etc. The permanent inner tube 16 can be replaced with yarn balls for permanent buoyancy, and the buoyancy body 1 otherwise be arranged for filling and emptying of air. The second end of the inner tube 16, opposite the first end, can have an opening towards the sea if it is the inner tube that is to be filled and emptied, preferably as a hole through the lower edge of the inner tube 16 and the buoyancy body. Otherwise, the holes must only be in the buoyancy body 1. Thus, a preferred embodiment of a method for lowering a floating, elongated buoyant body 1 for use in aquatic farming facilities, in that the buoyant body a 1 is provided with anchoring elements 10 arranged to lie on the bottom and held by lines 8 of adapted lengths, and fixed at their upper ends in the buoyancy body 1, so that the other end of the buoyancy body 1 lies deepest in the submerged position, and with the first end of the buoyancy body 1, to which the air hose 14 is connected, arranged to lie moored shallowest in the submerged position, and arranged for the lowering of the second, opposite end only when air is emptied via the air hose 14 by air being released from the first end via the air hose 14 , and that water is admitted through the other, open end of the buoyancy body 1.

In the embodiment illustrated in fig. 4, the buoyancy body 1 is anchored with the anchoring elements 10 lying on the bottom and held by lines 8 of suitable length, with the second end lying deepest in the submerged position, and with the first end with the air hose 14 moored lying shallowest in the submerged position, and arranged for raising the first end first when filling with air via the air hose 14 by forcing water out at the second, open end of the buoyancy body l.

The cultivation elements 4 include rope, notlin, "Swedish tape", or ladder. "Swedish rope" is a common term in the farming industry and denotes a rope made of rope, often with a rough and uneven surface, and which may resemble a very narrow ladder.

Fig. 7 shows the buoyancy body 1 provided with an outrigger 18 arranged to be placed mainly transversely over the buoyancy body 1, with at least one fully or partially circular recess with a notch 17 arranged to enclose the attachment cam 3 and thus lock the buoyancy body 1 as that it does not twist under torsional load, e.g. from unevenly distributed forces from cultivation elements 4, mooring etc. in the preferred embodiment, the outrigger 18 will extend over two or more buoyancy bodies 1.

In an embodiment shown in fig. 8, knots or balls 20 can be made on the line and arranged to stop the line 8 from sliding through the slits 7 or the depressions 5.

In fig. 8, it is also shown that at least one of the shards can be beveled or angled to increase the friction or gripping ability against the line 8.

A method for manufacturing a cultivation tube comprising a buoyancy body 1 with a number of attachment devices 2 arranged along what is to be the upper side of the buoyancy body in its normal floating position, for attachment of cultivation elements, where the attachment devices 2 comprise an elongated attachment comb 3 with a mainly rectangular cross-section, can be carried out according to the invention in that the buoyancy body 1 and the fixing cam 3 are extruded in one and the same operation through a nozzle with a tubular extrusion opening, and where a recess is arranged in the outer edge of the tubular shape for simultaneous extrusion of the fixing cam 3.

The comb can be equipped with open slots for attaching either continuous lines, such as mussel collectors or ear-hung scallops or, for example, cages with oysters, fig. 2 shows the principle with a cage 9 hanging from a line.

The pipe can be lowered to the desired depth by attaching vertical anchor lines to the pipe, these are firmly anchored to the pipe and their length is adapted to the bottom topography and the deep pipe is desired to be lowered to, when raised to the surface these are lifted up from the bottom, fig. 4.

The buoyancy in the tube is varied by the fact that it is equipped at one end with an air hose into which compressed air is filled or air is drained out. At the other end, the pipe is equipped with an open pipe end into which the water is filled and drained, fig 4.

For such a system to work, the buoyancy in the pipe must be such that the pipe, when filled with water, sinks, but no further than until the vertical anchor weights reach the bottom. This means that the entire system, pipes + suspended cultivation equipment must have positive buoyancy, but not greater than the plumb weight.

In order to achieve sufficient buoyancy, an additional inner tube is inserted which is filled with air, see figure 5. One can also imagine tying together links of bellows which are threaded into the tube and which we give the same function.

Two types of cultivation elements in the form of mussel collectors which are very common, a type of ladder consisting of ropes and intermediate pieces, as well as strips of notlin. On these, the shells will attach and grow to market size in 1.5-2 years. The image is intended as an example. Normally only one type of collector is used. This is continuous and is laid in a zigzag pattern over the comb hanging in loops a few meters into the water. Notlin is widely used for mussel cultivation. If this is placed around two narrow grooves on the comb, it is ensured that the knot line is held firmly. When harvesting, the net line is lifted vertically out of the comb.

Claims (17)

1. Cultivation facilities for aquatic organisms comprising buoyancy means for cultivation elements (4) suspended in the sea, where the buoyancy means comprise at least one elongated buoyancy body (l), characterized by at least one elongate, substantially continuous attachment cam (3) arranged along the upper side of the buoyancy body (1) in its normal floating position, where the attachment cam (3) extends substantially along the entire length of the buoyancy body (1), and where the attachment comb (3) comprises a number of attachment devices (2) for attachment of cultivation elements (4). 2. Cultivation plant according to claim 1, characterized in that the buoyancy body (1) comprises an extruded tube. 3. Cultivation plant according to claim 1, characterized in that the fastening devices (2) comprise recesses (5) for fastening the cultivation elements (4). 4. Cultivation plant according to claim 1 or 3, characterized in that the recesses (5) comprise continuous, preferably transversely arranged swaths (7) formed in the elongated attachment comb (3). 5. Cultivation plant according to claim 3 or 4, characterized in that the recesses (5) comprise slanted swaths (7) formed in the elongated fastening comb (3). 6. Cultivation plant according to claim 4 or 5, characterized in that the recesses (5) comprise local groups of two or three shards (7) formed in the elongated attachment comb (3). 7. Cultivation facility according to claim 1, characterized in that the cultivation elements (4) comprise at least one line (8) fixed in the attachment device (2). 8. Cultivation plant according to claim 7, characterized in that the line (8) is attached by hooking into one or more depressions (5) or one or more swaths (7). 9. Cultivation plant according to claim 8, characterized in that the cultivation elements are formed by the line (8) in that points with a substantially uniform first distance along the line (8) are fixed in recesses (5) with a substantially uniform second distance along the fastening comb (3), where the second distance is shorter than the first distance so that the line hangs like loops or a chain line down from the fastening comb. 10. Cultivation facility according to claim 7 or 8, characterized in that the cultivation elements (4) comprise a cage (9) which hangs from the line (8). 11. Cultivation plant according to claim 1, characterized in that at least one line (8) holds anchoring elements (10) for anchoring the cultivation plant. 12. Cultivation facility according to claim 8, characterized in that the cultivation elements (4) comprise rope, notlin, "Swedish tape", or ladder. 13. Cultivation plant according to claim 1, characterized in that the buoyancy body (1) is provided with an outrigger (18) arranged to be placed mainly across the buoyancy body (1), with at least one fully or partially circular recess with a notch (17) arranged to enclose the fastening cam (3) and thus lock the buoyancy body (l) so that it does not twist under torsional load, e.g. from unevenly distributed forces from cultivation elements (4), mooring etc. 14. Cultivation plant according to claim 13 (19), characterized in that the cantilever (18) extends over two or more buoyancy bodies (l). 15. Cultivation plant according to claim 7, characterized by knots or balls (20) designed to stop the line (8) from sliding through the slits (7) or the depressions (5). 16. Cultivation plant according to claim 1, where the attachment comb (3) has a mainly rectangular cross-section. 17. Cultivation facility according to claim 1, characterized in that the fastening devices (2) comprise elevations (6) for fastening the cultivation elements (4).