RU2681683C1 - Cage for rearing on open water areas - Google Patents

Abstract

FIELD: manufacturing technology.SUBSTANCE: submerged cage includes a chamber from a netting with a frame, a means for creating constant buoyancy and an anchor. Chamber from the netting is made of separate cylindrical sections connected to each other. Frame is made of tubular metal hoops, passed through the netting at the junction of the cylindrical sections in a circle. Tubular metal hoops are made of cambered tubular elements with the ability to connect with each other. Upper tubular metal hoop is attached to the axial cable by radial ropes passed through the netting. Lower edge of the lower cylindrical section is fixed on the annular element, loosely mounted on the axial support cable above the anchor. Upper and lower cylindrical sections are equipped with sleeves from fine-meshed webbing, strung along the outer edge of the rope, passed through cells from fine-meshed webbing.EFFECT: invention provides ease of operation of the cage in open water areas.5 cl, 2 dwg

Description

The invention relates to fish farming, and in particular to cages for raising fish, and is aimed at providing ease of use and high reliability when used in open waters.

A device for growing fish - a cage, consisting of floating pipes made in the form of individual floats, combined in sections. The sections are interconnected at the ends by connecting products made of symmetrical halves with sockets for fastening the floats. The connecting elements and products and fasteners for the rail are made of an elastic material that provides fixation of the latter on the connected parts of the cage with an interference fit. The fixing of the rail in the fasteners is ensured by the threaded tips of the hooks. Connecting products can be made both detachable and semi-detachable (p. RU No. 2115310, IPC A01K 61/00, publ. 20.07.1998).

The disadvantage of this design is the inability to use in open water areas: there is no anchor design, and the suspension of the charge to the float of pipes constantly floating on the surface makes it vulnerable to wind and wave impact.

There is also known a device - a cage for fish growing (RU, PM No. 171091, IPC A01K 61/00, published on 05.19.2017), containing a pontoon part with a guard rail, a net camera with loads, and a net camera lifting system including a winch located on a bridge mounted on the pontoon, for winding a rope connected to a net camera made of three interconnected parts: a cylindrical, cone-shaped and additional net, while the cone-shaped part is made of several, at least 4, trapezoidal layers and has a height, ra or more than the height of the cylindrical part of the chamber, an additional net part is fixed to its lower part, which is a net that is connected to the rope by means of flexible elements of at least 3, each fixed at one end on a ring located outside the net chamber at the junction and the net-shaped parts of the chamber, and the other end connected to the rope, the second end of which is passed through the block, mounted on the boom of the hoist of the lifting system. The loads for deepening the cage are fixed on two ropes made of different lengths, one of them being rigidly connected to the load and the upper end fixed to the rail, and the second cable connected to the load with the possibility of sliding the load on it is attached to the bottom cylindrical selection parts of the network camera at the junction of the vertical vein with the lower selection of this part of the camera and the upper end is freely fixed on the rail rack. The net-shaped part is made with a diameter of at least 1 meter and a height of at least 0.8 meters. The winch has a manual drive with a stopper to prevent the rope from sliding back when the net is lifted, an arrow with a block through which the rope is passed and placed on the bridge so that the rope passes through the middle of the net. The loads for deepening the cage are made with a ring through which a rope is passed to slide the load and on which the lower end of the other rope is fixed.

The disadvantages of this design when operating in open waters, as in the previous one, is the location of the supporting float elements on the surface, which makes it vulnerable to wind and wave impact, as well as the complexity of the design.

The closest technical solution in terms of the number of essential features and the achieved result is a submersible cage device (p. RU No. 2105471, IPC A01K 61/00, publ. 02.27.1998) containing a net chamber with a frame, means for feeding feed and creating permanent buoyancy, a horizontal positioning system consisting of anchors connected to the frame by guy wires with floats, tanks with variable buoyancy and a vertical positioning system consisting of at least one flexible element with negative buoyancy Which has a variable, incrementally increasing the free end of the weight.

The disadvantage of this device is the complexity of the design using variable buoyancy elements and several anchors for positioning. Also, the device does not allow to carry out a full cycle of growing from juveniles to marketable fish without transplantation.

The technical problem posed by the invention is the creation of a cage of a simple design, suitable for operation in the open waters of the seas and ensuring the fulfillment of the full cycle of fish growing from juveniles to commercial products without transplantation.

The technical problem posed is solved by the fact that in the well-known submersible cage for raising fish in open waters containing a camera from a net web with a frame, a means for creating constant buoyancy and an anchor, according to the invention, the net web camera is made of separate cylindrical sections connected to each other another, the frame is made of tubular metal hoops passed through a net web at the junction of the cylindrical sections in a circle, while the tubular metal hoops are made of arcs of shaped tubular elements with the possibility of connection with each other, the cylindrical sections are made of mesh fabric having a mesh of different sizes, the mesh of the upper, adjacent and lower cylindrical sections are made of fine mesh, and starting from the second cylindrical section the mesh size of the mesh fabric increases from top to bottom moreover, the number of cylindrical sections is one more than the number of tubular metal hoops, the means for creating buoyancy is made in the form of a buoy, fixed with its upper end to the axle the supporting cable, passed inside the chamber from the mesh web and attached to the anchor from below, the upper cylindrical section is fixed to the axial carrier cable below the buoy, and the upper tubular metal hoop is attached to the attachment point of the upper cylindrical section to the axial cable, radial ropes passed through the net, lower the edge of the lower cylindrical section is mounted on an annular element loosely mounted on an axial bearing cable above the anchor, the upper and lower cylindrical sections are equipped with sleeves of fine stand delhi, tied along the outer edge with a rope, passed through the meshes of fine-meshed delhi.

The execution of the net chamber from separate cylindrical sections connected in series from small to top to coarse to the lower part of the net chamber allows the conditions for keeping fish of different sizes, from planting material (juvenile) to marketable fish, to be adjusted with regulated sizes.

The manufacture of the chamber frame from tubular metal hoops that are passed through the net at the junction of the cylindrical sections in a circle gives sufficient structural rigidity when the cage is stretched under the weight of the hoops themselves, and their execution from arcuate tubular elements with the possibility of connection with each other, which is ensured, in in particular, in that the arcuate tubular element is hollow on one side and provided with a metal pin, the diameter of which corresponds to the inner diameter meter arcuate tubular element, i.e. a spike-groove lock is created. This connection provides the ability to create immersion cages of any given diameter and ease of assembly of the immersion cage directly at the installation site. The number of hoops and the distance between them, and accordingly, the number and volume of sections of the submersible cage, is determined by the desired amount of planting material and the specifics of growing a particular object for which the submersible cage will be used (survival rate, used standards for keeping fish per unit volume, etc.). Thus, the proposed design provides the creation of a cage of simple design, suitable for operation in the open waters of the seas and allows for a full cycle of fish growing from juveniles to commercial products without transplantation.

Fastening of the upper cylindrical section made of fine mesh to the axial load-bearing cable by collecting the beam in the form of a bundle or by making wedge-shaped darts, and the lower cylindrical section made of fine mesh, Delhi, on the movable ring, worn on the supporting cable, forming net cones , allows you to create a reliably closed chamber chamber for operation in a submerged state.

The supply of the upper and lower sections with mesh sleeves from fine mesh allows operations for planting material, unloading marketable products and cleaning the submersible cage directly from the board of the service craft, which greatly simplifies the operation of the submersible cage.

To adjust the dimensions of the immersion cage, it is additionally equipped with at least three adjusting cables, which are attached with their lower end to the lower tubular metal hoop, are passed through separate meshes of the net web from the inside of the net chamber, frame, and through rings placed on the upper tubular metal hoop . Moreover, next to these rings on the upper tubular metal hoop are fixed devices of the bollard or weft type, on which the adjusting cables are securely fixed in the desired position. The adjustment is carried out due to the weakening and tension of the adjustment cables. Before installation, it is advisable to mark the adjustment cables in accordance with the number and height of the cylindrical sections of the cage to facilitate its height adjustment. To ensure greater rigidity of the upper tubular metal hoop due to the fact that the control cables are fixed on it, the joints of its arcuate tubular elements are provided with through holes for cotter pin that are compatible when connected.

The implementation of the means for creating permanent buoyancy in the form of a buoy, fixed with its upper end on an axial load-bearing cable, passed through a mesh web inside the chamber, and bottom mounted to the anchor ensures vertical placement of the charge in the water column, creating favorable conditions for the growth and development of cultivated aquatic organisms in it.

 The submersible cage can be additionally equipped with an automatic feeder-dispenser, fixed under the means to create constant buoyancy (buoy), which will further automate the growing process. In this case, the granulated feed will wake up directly on the upper net cone of the chamber from the net web, in the center of which the buoy is located, and disperse over the area of the submersible cage, which increases the percentage of feed consumed by the fish being grown, which ultimately helps to ensure that the complete fish rearing cycle juveniles to commercial products without transplantation.

The device is illustrated by two figures. In figure 1. - presents a General view of the submersible charge in the working position, figure 2. - structural elements of a separate tubular metal hoop of the frame.

The submersible cage consists of an anchor 1, mounted on the lower end of the axial bearing cable 2, which is attached with the upper end to the buoyancy device made in the form of a buoy 3. An annular element 4 is put on the axial cable 2 to fix the lower edge of the net web of the net camera 5. The lower and upper fine-mesh sections of the net chamber 5 are equipped with net sleeves 6 with a contractible neck (not indicated in the drawing). The arcuate elements 7 of the tubular metal hoops 8 of the frame are threaded through the mesh of the web at the junction of the cylindrical sections of the net chamber 5, forming a framework due to the fact that one end of the arcuate tubular element is hollow on one side (not indicated in the drawing) and provided on the other side a metal pin 9, the diameter of which corresponds to the inner diameter of the arcuate tubular element, i.e. a spike-groove lock is created. Adjusting cables 10 for their rigid vertical positioning are passed inside the net chamber 5, through rings 11 located on the upper tubular metal hoop 8 and fixed in position on devices 12 such as bollards or “ducks” mounted on the upper tubular metal hoop 8. Upper the edge of the network camera 5 is collected in a bundle 13 and is rigidly fixed on the axial bearing cable 2 under the buoy 3 at a predetermined distance. The buoy 3 is attached to the carrier cable 2 by a bracket 14, to which the autonomous immersed feeder-feeder 15 and the free end 16 are also fixed in the working position. The upper tubular metal hoop 8 is attached to the attachment point of the upper conical section on the axial cable 2, radially passed through a net ropes 17.

These cages can be mounted both individually and as part of the previously proposed “design for the cultivation of marine hydrobionts on the shelf and the mainland slope” (Application reg. No. 2018102984 of 01/26/2018). In this case, the cage is easily mounted around the vertical bearing cable of this design from the side of the vessel in accordance with the step-by-step instructions for installing collectors and cages with bio-carrier given in the application.

It is advisable to carry out the assembly of the structure on the shore without joining the elements of the prefabricated rings, then when folded, the cage will not take up much space on board the vessel from which the installation will proceed. In this case, the arc elements of the hoops can be sewn to Delhi for reliable fixation during transportation. After setting up the anchor device, it will only remain to expand the net bag and gradually lowering it overboard to alternately join the hoop elements starting from the bottom.

Assembling the device and bringing it into working position at the bottom can be carried out directly on the spot according to the following algorithm:

At a selected point in the open water area, an anchor 1 of reinforced concrete is lowered on a supporting cable 2 of sufficient length so that its upper end remains on board the vessel. The weight of the anchor block should be sufficient to secure the cage with the carrier buoy 3 at the bottom, but should also allow, if necessary, to lift the entire structure on board the ship with a ship’s winch.

An annular element 4 is put on the cable to fix the lower edge of the net bag. Then the cable 2 is passed through the network camera 5, so that the first sections with a fine mesh are on top.

The lower edge of the net chamber 5 is collected in a bundle and fixed on the annular element 4, forming a conical section (not indicated in the drawing). In this case, the distance from the beam collected on the ring element 4 to the beginning of the lower cylindrical section with the largest mesh should be approximately 1.5 times greater than the radius of the lower tubular metal hoop 8. The lower net sleeve 6 should be pulled together with a rope (closed).

The arcuate elements 7 of the lower tubular metal hoop 8 are threaded through a shallow del at the base of the lower section and are joined together. The assembly of the hoop is best done from a boat at the side of the service vessel, from which a net bag will be fed.

To the lower hoop at 3-4 points at an equal distance, the lower ends of the control cables 10 are fastened, previously passed through the del along the vertical axis of the netting chamber 5.

The upstream tubular metal hoops 8 of the frame are sequentially assembled so that their arcuate elements 7 are passed through the last row of the finer mesh of the overlying section. At the same time, the net chamber 5 is gradually fed from the side of the vessel, and the assembled tubular metal rings 8 are lowered into the water and stretch the lower part of the cage around the supporting cable 2.

After assembling the upper tubular metal hoop 8 and securing its arcuate tubular elements 7 with cotter pins (not indicated in the drawing), devices for fixing 12 control cables (bollards or “weft”) are bolted to it, and the cables 10 themselves are passed through those located on the tubular metal hoop 8 of the ring 11 and are fixed on it.

The upper tubular metal hoop 8 of the cage is tied at three points to the side of the vessel (not shown in the drawing) so that the cage is completely straightened vertically, and the upper tubular metal hoop 8 is immersed in water to a sufficient depth so that the boat can freely approach carrying cable.

The upper, finely meshed edge of the netting chamber 5 is assembled into a bundle 13 from the boat using a rope previously passed through the upper cells of the netting. The upper tubular metal hoop 8 to the attachment point of the upper conical section on the axial cable 2, is attached by radial cables 17 passed through the net.

With a winch from a ship (not indicated in the drawing), the support cable 2 with the anchor 1 is lifted (1-3 meters) so that after firmly fixing the upper edge of the net chamber 5 to it, the upper edge of which is assembled into a bundle 13, and setting the anchor 1 back to the bottom, the opened cage turned out to be completely submerged in the water column to the desired (selected for this place) depth.

A buoy 3 is attached to the support cable 2 with the lifting bracket 14 so that the support cable 2 is constantly stretched vertically and the buoy 3 remains on the surface or is lowered to the depth necessary for reliable operation in the selected water area (in the case of operation of the cage as part of the “design for cultivation of marine hydrobionts on the shelf and the mainland slope ”in the conditions of the Sea of Japan is 2-3 meters below the surface). A sufficient end of the cable with a bracket at the end 15 must remain from the attachment point of the carrier buoy 3 so that the entire structure can be safely lowered to the bottom during installation and pulled out to the vessel during dismantling.

After completing the installation of the submersible cage and bringing the structure into working position, it must be raised by the ship's winch until the upper tubular metal hoop 8 appears on the surface. Pulling the adjusting cables 10 one by one from the boat and being guided by the marks applied to them, the cage is folded so that the lower tubular metal hoop 8 alternately presses the ones located above, collecting the lower sections of the net bag until the upper, finely meshed section remains stretched. In this position, the adjustment cables 10 are securely attached to the locking devices 12, and this fixation does not weaken due to the constant tension from the tubular metal hoops 8.

After fixing the immersion cage in the desired opening through the upper sleeve 6 in the immersion cage poured planting material. As the juveniles grow, the procedure for adjusting the dimensions of the submersible charge can be repeated.

After installing the submersible cage in the working position with planting material under the carrier buoy 3, an automatic feeder-feeder 15 can be fixed, which will allow observing the feeding of fish even in stormy weather, when maintenance from the craft will be difficult.

Thus, as a result of the application of this invention, it is possible to obtain a technical result - providing convenience and reliability in operation by simplifying the process of assembly and maintenance of a fully submerged cage for raising fish from juveniles to marketable products in open waters.

Claims (5)

1. A submersible cage for raising fish in open water areas, comprising a camera from a net web with a frame, a means for creating constant buoyancy and an anchor, characterized in that the camera from a net web is made of separate cylindrical sections connected to each other, the frame is made of tubular metal hoops passed through the net at the junction of the cylindrical sections in a circle, while the tubular metal hoops are made of arcuate tubular elements with the possibility of connection with each other another, the cylindrical sections are made of a mesh fabric having a mesh of different sizes, the mesh of the upper adjacent to it and the lower cylindrical sections are made of fine mesh, and starting from the second cylindrical section, the mesh size of the mesh fabric increases from top to bottom, and the number of cylindrical sections by one more than the number of tubular metal hoops, the means for creating buoyancy is made in the form of a buoy, fixed with its upper end on an axial load-bearing cable, passed inside the chamber from a net web and attached to the anchor from below, the upper cylindrical section is fixed to the axial bearing cable below the buoy, and the upper tubular metal hoop is attached to the attachment point of the upper cylindrical section to the axial cable by radial ropes passed through the net, the lower edge of the lower cylindrical section is fixed to the ring element, freely seated on an axial load-bearing cable above the anchor, the upper and lower cylindrical sections are provided with sleeves made of fine-meshed material, tightened along the outer edge with a rope passed through a cut of fine-mesh mesh. 2. The submersible cage according to claim 1, characterized in that the arcuate tubular element is hollow on one side and provided with a metal pin, the diameter of which corresponds to the inner diameter of the arcuate tubular element. 3. The submersible cage according to claim 1, characterized in that the fixing of the upper cylindrical section on the axial bearing cable is made by collecting a net web in the form of a cone-shaped bundle or by making wedge-shaped darts. 4. Submersible cage p. 1, characterized in that it is additionally equipped with at least three adjusting cables fixed to the lower ends on the lower tubular metal hoop, passed through the mesh mesh from the inside of the mesh chamber, the frame and rings placed on the upper tubular a metal hoop, with devices of the bollard or weft type attached to the rings. 5. The submersible cage according to claim 1, characterized in that it is additionally equipped with an automatic feeder-dispenser attached to an axial load-bearing cable above the upper cylindrical section.

Images