KR100696872B1 - Submersible cage facility for fish culture - Google Patents

Abstract

A submersible fish culturing equipment is provided to vertically move the fish culturing equipment in the seawater according to a temperature of the seawater for minimizing damage from the red tide. The fish culturing equipment includes a frame(11) fixedly installed on a bottom of the sea by a connecting rope(22) and having plural hollow pipes(12) communicating with each other, a net(13) enclosing the frame and having a specified space formed on a lower portion of the frame, a buoyant pipe(21) consisting of a double pipe having a buffer material formed between an outer pipe and an inner pipe, a control ship(31) spaced apart from the frame at a desired distance, a frame lifting member for controlling a height of the frame, and a feed supply member consisting of a feed supply pipe and a feed supply hose.

Description

Submersible cage facility for fish culture

1 is a perspective view when the underwater cage according to the present invention is located on the surface of the water.

2 is a cross-sectional view of the buoyancy pipe of the underwater cage according to the present invention.

3 is an elevational view when the underwater cage according to the present invention is located on the surface of the water.

4 is an elevational view while the underwater cage arrangement is submerged in accordance with the present invention.

5 is a perspective view of the underwater cage according to the invention when the device is located in the water.

6 is an elevation view when the underwater cage according to the present invention is located in the water;

Figure 7 is a flow chart illustrating a method of installation of the underwater cage according to the present invention.

8 is a perspective view of the cage device according to the prior art.

Description of the main symbols in the drawings

1: sleep 2: sea bottom

11: frame 12: hollow pipe

13: net 14: weight

15 rope 16 structure

21: buoyancy pipe 22: connecting rope

31: management ship 41: feed pump

42: Feeding Hose 51: Air Infusion Pump

52: air injection hose 53: sea water input pump

54: seawater input hose 61: camera

62: monitor 63: cable

101: frame 102: float

103: net 104: rope

The present invention relates to a cage device for farming fish in a certain space, and more particularly, to an underwater cage device for allowing fish to be submerged to submerge the entire fishery.

In general, cage farming is a method of producing fish that keeps fish from the larvae stage into fish in the sex stage, while keeping and feeding fish in a net space.

Such cage farming has been used a lot of fish because it is easy to feed the feed and observe the growth state by farming a large number of fish in a narrow space.

Looking at the general configuration of the cage farming apparatus according to the prior art, after forming a space in which the farmed fish is accommodated in the lower portion of the frame 101 is fastened 102, the net 103, and always sleep Frame 101 and the bottom of the sea was to be fixed using a rope (104) and so on.

However, such conventional cage devices have various problems because they are always located on the surface of the water.

Since the surface of the water is deeply affected by waves and algae in the depths of the water, the cages are easily damaged by severe waves and algae in typhoons or windy weather. Therefore, it is practically difficult to install cages to withstand severe waves and tidal currents, so that cages are restricted only in geographically closed areas such as islands or islands to prevent waves and tidal currents. It was possible. Due to the limited area available for cage farming, it was not easy to increase the yield of farmed fish.

In addition, since the portion near the water surface is easily heated by the sun, the temperature of the water rises in the summer, and it is inevitable that the aquatic fish die in the cage due to the red tide where algae breed abnormally. As described above, the conventional cage device is installed in a portion adjacent to the land due to its characteristics, and during the summer season when the water temperature is high and the nutrients are introduced from the land, when the red tide phenomenon that ideally breeds algae in the seawater lasts for several days, Large numbers of farmed fish die due to lack of oxygen.

In addition, cold-water fish were inherently incapable of growing because of unsuitable growth conditions in cages adjacent to the surface of the water.

The present invention has been invented to solve the above problems, and an object of the present invention is to provide a cage device that can farm fish in water.

Another object of the present invention is to provide a method for installing a cage device that can raise fish in water.

In order to achieve the above object, the underwater cage device of the present invention, the cage device is provided with a plurality of hollow pipes in communication with each other and fixed to the bottom surface by a connecting rope; A net surrounding the frame and forming a predetermined space in which the farmed fish is accommodated below the frame; A plurality of partition walls are formed inside the inner pipe so that the inner pipe is divided into a plurality of spaces in the axial direction, and is formed of a double pipe provided with a cushioning material between the outer pipe and the inner pipe. A buoyancy pipe connected to provide buoyancy to the frame; A management line provided at a predetermined distance from the frame; Frame lifting means for adjusting the height of the frame by adjusting the amount of sea water inside the frame; And a feed supply means comprising a feed feed pump provided at the management line, and one end connected to the feed feed pump and the other end of the feed feed hose located inside the net.

Here, a cage monitoring means comprising a camera provided inside the net and a monitor connected to the camera on a management line to display a screen taken by the camera.

The buoyancy pipe is preferably made of a double pipe having a partition formed therein.

The frame elevating means includes an air injection pump provided at the management line, an air injection hose having one end connected to the air input pump, the other end connected to the frame, a sea water input pump provided at the management line, and one end It is connected to the seawater input pump, the other end is made of a seawater input hose connected to the frame.

The feed means, characterized in that the feed pump is provided on the management line, and one end is connected to the feed pump and the other end is made of a feed hose connected to the inside of the net.

In addition, the method of installing the underwater cage according to the present invention is coupled to the net receiving a fish species so as to surround the frame on the outside of the frame made of hollow pipe, the coupling step of connecting the buoyancy pipe at a predetermined distance from the frame ; A fixing step of moving the frame to a place where the frame is to be installed and fixing the frame to the horizontal surface using a frame fixing means to prevent the frame from moving horizontally; A subsidence step of discharging air into the frame and sinking the frame and the net into water by introducing seawater; And a height adjusting step of adjusting the height of the cage device by adjusting the amount of air and seawater inside the frame.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the underwater cage according to the present invention.

As shown in FIG. 1, the frame apparatus of the present invention includes a frame 11 made of a hollow pipe 12 and surrounded by a net 13, and a buoyancy pipe 21 providing buoyancy to the frame 11. The main component is a feeder supplying means for adjusting the height of the frame 11 and feeding the feed into the net 13 from the management line 31 and the management line 31 for feeding the farmed fish.

The frame 11 consists of a hollow pipe 12 which is hollow inside. The frame 11 processes the hollow pipe 12 to form the top surface of the cage device. The frame 11 has a polygonal, preferably rectangular, shape to facilitate processing and maintenance of the hollow pipe 12.

Here, the hollow pipes 12 forming the frame 11 are connected to each other to communicate with each other, so that the inside is a connected space.

In addition, the hollow pipe 12 may be provided with a plurality of air inlets and air outlets so as to pass through the inside and the outside of the hollow pipe 12 to inject air into the inside of the hollow pipe 12 and vice versa. Sometimes.

As described above, after the upper part of the frame 11 is formed of the hollow pipe 12, the net is tied to the lower part of the frame 11 to secure a predetermined space in which the farmed fish are farmed. With the frame 11 as an upper surface, the upper, lower, and side surfaces are surrounded by a net 13 so as to secure a space in which farmed fish are farmed in the lower portion of the frame 11. The lower portion of the net 13 binds the weight 4 so that the lower part of the net 13 sinks to maximize the internal space surrounded by the net 13.

Here, in the conventional cage device, the upper surface has an open structure, but in the present invention, since the cage device is located in the water, the upper portion of the frame 11 is also surrounded by the net 13 to trap the farmed fish.

After the frame 11 is installed in water, the frame 11 is fixed to the sea bottom 2 using frame fixing means for preventing horizontal movement by waves or tides. The structure 16 is installed on the sea bottom 2, and the frame 11 and the structure 16 are moved by waves and tides by using frame fixing means 15 such as ropes and chains. Prevent it.

The buoyancy pipe 21 is connected to the side of the frame 11 at a predetermined distance from the frame 11. The buoyancy pipe 21 is made of a hollow pipe 12 having a larger diameter than the hollow pipe 12 constituting the frame 11, so that buoyancy acts on the cage device according to the present invention, the frame 11 When submerged in the water, the frame 11 is maintained at a constant height in the water by the buoyancy pipe 21.

As shown in FIG. 2, the buoyancy pipe 21 has a double pipe structure, and a plurality of partition walls 21d are formed inside the buoyancy pipe 21 so as to be perpendicular to the axial direction. Consists of compartments. The buoyancy pipe 21 can be formed in a double structure of the outer pipe 21a and the inner pipe 21c, and the shock applied to the outer pipe 21a between the outer pipe 21a and the inner pipe 21c can be absorbed. A cushioning material 21b is provided, and partition walls 21d are provided in the inner pipe 21c at predetermined intervals so as to have a plurality of compartments. The reason why the buoyancy pipe 21 is formed as a double pipe is to prevent the buoyancy pipe 21 from being damaged due to the severe waves and the impact of foreign substances. The reason for dividing the buoyancy pipe 21 into a plurality of compartments is that This is to prevent the buoyancy of the entire buoyancy pipe 21 from being lost even if some of them are broken during severe waves and foreign objects.

As described above, the buoyancy pipe 21 and the frame 11 are connected to each other using the connecting rope 22 so that the buoyancy pipe 21 maintains a predetermined distance from the frame 11 and the settlement of the frame 11 occurs. The buoyancy is provided to the frame 11 connected to the connecting rope 22 by a buoyancy pipe 21 located on the water surface 1.

On the other hand, to feed the farmed fish farmed in the net 13 and to adjust the position of the frame 11, a management line 31 is provided. The management line 31 is positioned on the water surface 1 at a predetermined distance from the frame 11. The management line 31 feeds the farmed fish in the net 13 located in the water, observes their condition, and adjusts the height of the frame 11 so that the position of the frame 11, that is, from the water surface 1 It is responsible for controlling the degree of sinking.

The management line 31 is provided with a frame lifting means for submerging the frame 11 below the sea level, and causing the frame 11 to rise again in the submerged state.

The frame lifting means includes an air injection pump 51 and a seawater input pump 53 on the management line 31, and connects the air injection pump 51, the seawater input pump 53, and the frame 11 to each other. The injection hose 52 and the seawater injection hose 54 are provided.

An air injection pump 51 is provided on the management line 31, one end of the air injection hose 52 is connected to the air injection pump 51, and the other end is connected to the air injection port of the frame 11 to connect the frame 11. Inject air into the inside.

In addition, as described above, the seawater input pump 53 is provided on the management line 31, and the seawater input pump 53 and the frame 11 are connected to each other by the seawater input hose 54. Supply seawater inside.

Feeding means is provided between the management line 31 and the net 13 to feed the farmed fish. The feed means comprises a feed feed pump 41 provided in the management line 31 and the feed feed hose 42 for connecting the feed feed pump 41 and the frame 11.

The feed pump 41 is provided on the management line 31 to supply the feed necessary for the growth of sheep fish into the net 13.

One end of the feed hose 42 is located inside the net 13, the other end is to be connected to the feed pump 41 provided in the management line (31).

Due to the nature of cage farming, many fish are densely farmed in a narrow space, and natural algae flow prevents them from growing food. Therefore, in the cage form, the worker separately feeds, in the present invention can not feed smoothly because the entire net 13 is located in the water.

In order to solve this problem, one end is positioned inside the net 13, and the other end is provided with a flexible feed hose 42 connected to the feed pump 41 of the management line 31, and the management line 31 as necessary. ) To feed the feed necessary for the growth of farmed fish from the inside of the net (13).

In addition, in the conventional caged culture with an open top, it is easy to observe the state of the farmed fish in the naked eye, but in the present invention in which the farmed fish is present inside the net 13 submerged from the surface 1 In order to observe the state of the fish growing in the water, a cage monitoring means is provided.

The cage monitoring means includes a camera 61 located in the net 13, a monitor 62 provided on the management line 31, and a cable 63 connecting the camera 61 and the monitor 62. . A plurality of cameras 61 are provided inside the net 13, and a monitor 62 for displaying a screen shot from the camera 61 is provided on the management line 31, and then connected with a cable 63. Let's do it.

Therefore, the state of the farmed fish in the net 13 can be confirmed from the remote management line 31.

Underwater cage installation method according to the present invention is a coupling step (S110) for connecting the frame 11 and the net 13 and the buoyancy pipe 21, and a fixing step for fixing the frame 11 to the bottom (2) ( S120, and the sinking step (S130) to sink the frame 11 in water and the height adjustment step (S140) for adjusting the height of the frame (11).

In the coupling step S110, the net 13 is coupled to the frame 11 constituting the underwater cage, and the buoyancy pipe 21 is connected to the frame 11 at a predetermined distance. Through the coupling step (S110) is formed a space in which the cultured fish is farmed.

When the coupling step (S110) is completed, it is moved to the desired place for installation.

As described above, in a state in which the net 13 and the buoyancy pipe 21 are coupled to the frame 11, after moving to the place to be installed, the frame 11 is fixed to the sea bottom 2, FIG. 1 And the state of FIG. 3. In the fixing step (S120), a plurality of structures 16 and the frame 11, which are pre-installed on the sea bottom 2, are fixed using the frame fixing means 15, that is, a rope and a chain. By connecting the side of the frame 11 and the structure 16 of the sea bottom 2, the frame 11 and the net 13 connected to the frame 11 are prevented from moving horizontally by waves or birds. .

In the settlement step (S130) to prevent the horizontal movement of the frame 11 and the sea bottom (2) to the place to be installed using the frame fixing means 15, and then fill the sea water inside the frame 11 and instead the frame ( Step 11 is to sink the frame 11 to the water by discharging the air in the interior 11). When the seawater input pump 53 is operated, when seawater is introduced into the frame 11 through the seawater introduction hose 54 and air is discharged, the inside of the frame 11, which was a hollow inside the frame 11, Since there is no specific gravity difference with the outside and the weight 14 is connected to the lower end of the net 13, it gradually sinks into water as shown in FIG.

The frame 11 which has started to sink into water stops after sinking by the length of the connecting rope 25 connecting the frame 11 and the buoyancy pipe 21 (see FIGS. 5 and 6). The hollow frame 11 has a specific gravity lower than that of seawater so that it floats on the water surface 1 easily, but the frame 11 in a state where the seawater is filled inside is settled because the specific gravity is slightly higher than the seawater.

When the settlement of the frame 11 begins to proceed, the connecting rope 22 connected to the buoyancy pipe 21 at the side of the frame 11 also accompanies and sinks along the frame 11.

When the settlement of the frame 11 progresses to some extent, the connecting rope 22 connecting the buoyancy pipe 21 and the frame 11 is in a vertical state, and the buoyancy pipe 21 is directly above the frame 11. It is located at. In this state, the buoyancy of the buoyancy pipe 21 and the force to be settled by the frame 11 are in equilibrium so that the frame 11 maintains a constant height.

Height adjustment step (S140) is a step of adjusting the height of the settled frame (11). In order to adjust the height of the frame 11 as necessary in a state in which the frame 11 maintains a constant height in water, air is injected into the frame 11 to float the frame 11 or vice versa. The frame 11 is settled. As in the submarine height adjustment principle, by adjusting the amount of air inside the frame 11, the height of the net 13 including the frame 11 is adjusted.

After the underwater cage device according to the present invention is installed in the water in the same manner as described above, the feed is continuously supplied to the farmed fish housed in the net 13 using the feed means, and from time to time using the cage monitoring means. Monitor the status of farmed fish.

Then, the growth of the cultured fish is completed, in order to capture it, first, air is injected into the frame 11 to float the frame 11. When air is injected into the hollow pipe 12 constituting the frame 11 and the length of the frame fixing means 15 which fixes the frame 11 to the sea bottom 2 is increased, the specific gravity of the frame 11 becomes seawater. It is lowered so that the net 13 including the frame 11 rises.

When the frame 11 slowly rises and the frame 11 is positioned on the water surface 1, the upper part of the net 13 is opened, and through this, the farmed fish are captured.

According to the underwater cage device of the present invention as described above, it is possible to farm in the water away from the sea surface with high water temperature, it is possible to culture the cold water fish, and to prevent the damage by submerging the cage device during red tide due to the water temperature rise can do.

In addition, since the waves and tides are located in the water away from the strong sea level, there is little damage during typhoon invasion.

In addition, when the red tide occurs, by further submerging the cage device, it is possible to evacuate the cage device during the red tide occurs.

In addition, since there is no land or island nearby, farming is possible even in open areas where the flow of birds is strong or far away from the land. Therefore, large-scale farming of high-quality fishes in clean areas is possible, and expansion of farming facilities The amount of fish added increases.

Claims (6)

In the cage device, A frame provided with a plurality of hollow pipes communicating with each other and fixed to the sea bottom by a connecting rope; A net surrounding the frame and forming a predetermined space in which the farmed fish is accommodated below the frame; A plurality of partition walls are formed inside the inner pipe so that the inner pipe is divided into a plurality of spaces in the axial direction, and is formed of a double pipe provided with a cushioning material between the outer pipe and the inner pipe. A buoyancy pipe connected to provide buoyancy to the frame; A management line provided at a predetermined distance from the frame; Frame lifting means for adjusting the height of the frame by adjusting the amount of sea water inside the frame; And Underwater cage device comprising a; feed pump provided in the management line, and a feed supply means having one end connected to the feed pump and the other end of the feed feed hose located inside the net. The method of claim 1, A camera provided inside the net; Underwater cage device, characterized in that the cage is connected to the camera to the management line consisting of a monitor for displaying a screen taken by the camera. delete The method of claim 1, The frame lifting means, An air injection pump provided at the management line; An air injection hose having one end connected to the air input pump and the other end connected to the frame; Sea water input pump provided in the management ship, An underwater cage device, characterized in that the one end is connected to the sea water input pump, the other end is made of a sea water input hose connected to the frame. The method of claim 1, The feed means, A feed pump provided at the management line, Underwater cage device, characterized in that the feed end is connected to the feed pump and the other end is connected to the inside of the feed pump. delete

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