KR100308581B1 - Nursery System for Raising Fishes Having Buoyancy-Control Function and Method of Using the System - Google Patents

Abstract

The cage farm structure of the present invention acts as a cage and air can be injected from the outside and when air is injected, it floats on the surface of the sea and the air is discharged so that the sea can be submerged into the sea, and the air is injected or A frame tube 2 having an air hose 5 for discharging and a water inlet 13 for discharging or discharging sea water; A fishing net (17) fixed to a lower portion of the frame tube to form a space in which fish grow therein and a lower frame (19) having a sufficient load to allow the cage farm structure to submerge into the sea; Fixing means consisting of a plurality of rich people (14, 15) and a rope (18) to fix the cage farm structure and to adjust the depth to be submerged into the sea; Automatic valve (9) for discharging the air of the frame pipe to the outside; An anemometer for measuring the wind speed to automatically open the automatic valve; And a compressor 8 for injecting air into the frame tube through the air hose.

Description

Nursing System for Raising Fishes Having Buoyancy-Control Function and Method of Using the System

Field of invention

The present invention relates to cage farms. More specifically, the present invention relates to a cage farm structure that can float on the sea surface or submerge into the sea by injecting air into the inside of the farm frame or by discharging the air. The present invention also relates to a method of allowing cages to float on the surface of the sea or to dive into the sea. The present invention relates to a cage farm that can be installed on the coast as well as offshore by allowing the cage to float on the surface of the sea or to dive into the sea.

Background of the Invention

Cultivated farms for aquaculture are widely used around the coast of the sea adjacent to the land. Because offshore areas are deep and deep, the cages have been actively used in coastal areas where the waves are not severe and deep.

The conventional cage farm fishing net structure is installed so that the cage is floating above the sea surface, the fishing net is located in the sea inside the frame. Fishing nets are secured to the cage by means of strings at the top. The bottom of the fishing net is extended to secure the anchor. The inside of the fishing net is the activity space of the fish to be farmed, and the fish grows in this space. The cage is fixed to the bottom of the buoyant material as necessary to float on the sea by buoyancy. The cage is a floating quadrilateral shape, about 60cm ~ 1m wide, where people walk over it to feed into fishnets or do other necessary work.

So far, the cages are made to form a regular shape such as a quadrilateral by combining wood (wood) and metal pipes with fastening means such as nails, and fixing the rich man made of Schiropol to the bottom of the cage Let's do it. The upper part of the cage is a structure that people can walk along the periphery of the frame, while walking on the frame to feed or take care of the fish and shellfish that are farmed inside the fishery. However, since the conventional cage is made of wood and iron pipes, the wood is broken in the severe waves, and the broken woods rot to pollute the coast. In addition, the traditional cages are supported by dragging the rich made of Schiropol to the lower portion of the cage, and as time passes Schiropol can be crushed to maintain proper buoyancy, the crushed Schiropol is scattered on the sea surface causing a lot of environmental pollution have. Due to the above problems, Schiropol rich man usually has to replace about once a year, wood should be replaced about once every 2-3 years. In particular, when a typhoon occurs, the cage is frequently broken. Therefore, the conventional caged float floating on the surface of the water can be installed around the coast with relatively little typhoon damage.

Conventional cage farm net structure has a length of about 5 to 15 m on one side of a quadrangular structure, and the depth of the fishing net is usually about 3 to 4 m. In some cases, fishing net structures with a depth of about 10 m are used.

Conventional fishing net structure is mainly installed on the coast, the fishing net maintains the unfolded state by the gravity of the fixed weight installed in the sea. Conventional fishing net structure can not be installed in the offshore area where the water depth is more than 10m 20 ~ 30m because the waves are severe. If a short-length fishing net structure is installed in a place where the waves are severe, the fishing net will be inverted, causing all the farmed fish to flow out into the sea. In addition, fishing net structures with long fishing nets are twisted with each other when the waves are severe. As a result, farmed fish dies.

In the conventional fishing net structure, the depth of the fishing net is changed due to the large change in the water depth in the west coast region where the tidal current is severe or the tidal difference is large, and the fishing net is twisted or flipped. Therefore, the conventional fishing net structure has been used mainly installed in the shallow coastal area.

Cage farms in coastal areas also cause other problems. In cage farming, the large amount of feed used to feed the farmed fish causes pollution in coastal areas. On the other hand, coastal seawater is contaminated by land contaminated rivers and factory wastewater, resulting in contaminated farmed fish. Because of these problems, many studies and attempts have been made to establish caged farms in the offshore area.

In addition, the conventional caged fish farming structure is installed in a shallow coastal area, and when a red tide occurs, the fish do not have a space to avoid the red tide layer, so that almost all fish are dead.

The present inventors can solve the above-mentioned limitations of the cage farm, and develop a cage farm net structure of the present invention that can be installed without any problem in coastal areas as well as offshore areas patent application No. 98-28383 (1998. 7. 14 applications) and 98-31310 (filed July 31, 1998). The inventors have developed the cage cage structure that can be installed without any problem in the offshore area where waves are severely hit by having the ability to dive into the sea, and the patent application No. 98-37930 (filed Sep. 15, 1998) Patent No. 98-31310 (filed July 31, 1998) filed a patent application, and the present invention has been further improved to develop a cage farm structure having a smooth diving function.

An object of the present invention is to provide a cage farm structure having a diving control function to be able to float on the surface of the sea or to dive to a certain depth in the sea.

Another object of the present invention is to provide a cage farm structure that can be safely installed in coastal areas as well as offshore areas having a depth of 30 ~ 40m by having a diving control function.

Another object of the present invention is to provide a cage farm structure that can prevent the death of fish even if the red tide phenomenon occurs on the surface of the sea or the surface layer of a certain depth by installing in the deep water area.

Another object of the present invention is to provide a cage farm structure that can be installed in the offshore to prevent seawater pollution in the coastal area and to farm clean fish.

Still another object of the present invention is to provide a cage farm structure that can protect fish from various diseases by installing in a deep water area and further reduce the cost of treatment, thereby reducing the cost of farming.

Another object of the present invention is to provide a conventional rich rich cage farm structure to float the cage on the sea surface by adjusting the buoyancy of the air by injecting air into the frame tube of the cage frame or by removing the air and injecting sea water It is to provide.

Still another object of the present invention is to provide a cage structure that is semi-permanent and can be recycled by manufacturing the frame tube of the cage with a synthetic resin such as polyethylene.

Still another object of the present invention is to provide a cage farm structure that can eliminate environmental pollution of the sea by not using conventional wood and Schiropol rich.

Still another object of the present invention is to provide a cage farm structure that can be significantly reduced repair and maintenance costs compared to conventional cage farm structures.

The above and other objects of the present invention can be achieved by the present invention described below.

Summary of the Invention

The cage farm structure of the present invention acts as a cage and air can be injected from the outside and when air is injected, it floats on the surface of the sea and the air is discharged so that the sea can be submerged into the sea, and the air is injected or A frame tube 2 having an air hose 5 for discharging installed therein and a water inlet 13 for discharging or discharging sea water; A fishing net (17) fixed to a lower portion of the frame tube to form a space in which fish grow therein and a lower frame (19) having a sufficient load to allow the cage farm structure to submerge into the sea; Fixing means consisting of a plurality of rich people (14, 15) and a rope (18) to fix the cage farm structure and to adjust the depth to be submerged into the sea; Automatic valve (9) for discharging the air of the frame pipe to the outside; An anemometer for measuring the wind speed to automatically open the automatic valve; And a compressor 8 for injecting air into the frame tube through the air hose.

The frame tube is fused to each other unit frame tube 12 formed of a synthetic resin to form a confinement such as octagonal, octagonal, hexagonal. Frame tubes may range from about 200 to 800 mm in diameter to form a cage as a single tube, but usually two or three tubes are assembled by fastening means 4 to form a cage.

Since cage cage structures of the present invention are usually installed in one position, a central control system 7 for controlling them should be installed at any one position. The central control system is equipped with compressors, automatic valves and anemometers to allow cage farm structures to automatically dive and float back to the sea surface.

Cover cages are to be provided to cover the inlets of cage cages to protect the fish in the cages when the cage farm is submerged.

The cage farm structure of the present invention farms fish in a state in which air is injected into the frame tube so that the cage is floating on the sea surface. At this time, if the wind is getting worse and you want to submerge the cage structure underwater, the anemometer will measure the wind speed and the automatic valve will open when the wind speed reaches a certain speed. When the automatic valve is opened, the air inside the frame pipe is discharged to the outside through the air hose. At this time, the seawater is injected into the frame tube through the water entrance. When seawater is injected, the cage cage structure submerges into the sea under the load of the lower frame. At this time, the cage farm structure is submerged by the length of the rope 18 because it is connected by the rope 18 to the rich. When the sea calms down after the storm passes, a person takes a boat to approach the central control system, closes the automatic valve and activates the compressor to inject air into the frame tube. Then, the seawater injected into the frame tube is discharged and the cage is floated to the sea surface.

Hereinafter, with reference to the accompanying drawings will be described in detail the contents of the present invention.

1 is a perspective view schematically showing the cage farm structure of the present invention floating on the sea surface.

FIG. 2 is a schematic plan view of an embodiment in which the cage farm structure of the present invention is installed, showing a shape in which eight cage farm structures are installed in one central control system.

FIG. 3 is a schematic diagram illustrating an air injection and discharge system in which each air hose connected from eight cage farm structures is connected to a compressor.

4 is a schematic perspective view of a frame pipe of a cage farm structure according to the present invention.

5 is a perspective view of a frame tube for showing a water inlet and outlet installed in the lower portion of the frame tube of the present invention.

6 is a perspective view showing an example of a fastening means for coupling the inner frame tube and the outer frame tube to each other.

FIG. 7 is a schematic perspective view illustrating a state in which an inner frame and an outer frame are fastened by the fastening means of FIG. 6.

8 is a plan view schematically showing a state where the cage farm structure of the present invention is fixed by a pair of rich people installed in the sea.

9 is a schematic front view showing a state in which the cage farm structure of the present invention is floating on the sea surface.

Figure 10 is a schematic front view showing a state in which the cage farm structure of the present invention submerged in the sea.

Fig. 11A is a schematic perspective view of another embodiment of the frame tube, and Fig. 11B is a sectional view thereof.

12A is a schematic perspective view of another embodiment of the frame tube, and FIG. 12B is a cross-sectional view thereof.

Figure 13 is a schematic perspective view of a rich man who has been used conventionally and can also be used in the present invention.

* Brief description of the major symbols *

1: nursery system for raising fishes

2: nursery frame

3: inner frame pipe

3 ': outer frame pipe 4: jointing means

5: air hose 6, 6 ': cock

7: central control system

8: Compressor 9: Automatic Valve

10: anemometer 11: pipe

12: frame pipe unit

13: water charge / discharge

14, 15: Rich 16: Anchor

17: fishing net 18: rope

19: lower frame 20: sea surface

21: rich man 41, 41 ': fastening cock

42, 42 ': Fastener 43, 43': Storage space

The cage farm structure of the present invention acts as a cage and air can be injected from the outside and when air is injected, it floats on the surface of the sea and the air is discharged so that the sea can be submerged into the sea, and the air is injected or A frame tube 2 having an air hose 5 for discharging installed therein and a water inlet 13 for discharging or discharging sea water; A fishing net (17) fixed to a lower portion of the frame tube to form a space in which fish grow therein and a lower frame (19) having a sufficient load to allow the cage farm structure to submerge into the sea; Fixing means consisting of a plurality of rich people (14, 15) and a rope (18) to fix the cage farm structure and to adjust the depth to be submerged into the sea; Automatic valve (9) for discharging the air of the frame pipe to the outside; An anemometer for measuring the wind speed to automatically open the automatic valve; And a compressor 8 for injecting air into the frame tube through the air hose.

1 is a perspective view schematically showing the cage farm structure of the present invention floating on the sea surface.

The cage of the cage farm structure of the present invention is composed of a frame tube (2). The frame tube is fused to each other unit frame tube 12 formed of a synthetic resin to form a cage, such as a hexagonal, octagonal, hexagonal. Frame tubes may range from about 200 to 800 mm in diameter to form a cage as a single tube, but usually two or three tubes are assembled by fastening means 4 to form a cage. 1 is a structure in which two frame tubes are fastened by a plurality of fastening means (4). 1 is a structure in which the inner frame tube 3 and the outer frame tube 3 'are fastened by a plurality of fastening means 4.

FIG. 2 is a schematic plan view of an embodiment in which the cage farm structure of the present invention is installed, showing a shape in which eight cage farm structures are installed in one central control system. FIG. 3 is a schematic view showing a central control system in which each air hose 5 connected from eight cage farm structures is connected to a pipe 11. The air hose is connected to the frame tube on one side by the cocks 6 and 6 'and to the pipe 11 on the other side.

Since cage cage structures of the present invention are usually installed in one position, a central control system 7 for controlling them should be installed at any one position. The central control system is equipped with compressors, automatic valves and anemometers to allow cage farming structures to automatically dive and float back to the sea surface. Even if cage farm structures are submerged underwater, the central control system should remain suspended at sea surface.

The cage farm structure of the present invention farms fish in a state in which air is injected into the frame tube so that the cage is floating on the sea surface. At this time, if the wind is getting worse and you want to submerge the cage structure underwater, the anemometer will measure the wind speed and the automatic valve will open when the wind speed reaches a certain speed. The anemometer in which the automatic valve is opened can be easily set by those skilled in the art. When the automatic valve is opened, the air inside the frame pipe is discharged to the outside through the air hose. At this time, the seawater is injected into the frame tube through the water entrance. When seawater is injected, the cage cage structure submerges into the sea under the load of the lower frame. At this time, the cage farm structure is submerged by the length of the rope 18 because it is connected by the rope 18 to the rich. When the sea calms down after the storm passes, a person takes a boat to approach the central control system, closes the automatic valve and activates the compressor to inject air into the frame tube. Then, the seawater injected into the frame tube is discharged and the cage is floated to the sea surface. If cage farm structures float on the surface of the sea, it is desirable that about two-thirds of the frame tubes float on the surface of the sea. Compressors, automatic valves and anemometers installed in the central control system can also be readily implemented by one of ordinary skill in the art.

4 is a schematic perspective view of a frame pipe of a cage farm structure according to the present invention. The frame tube is fused to each other unit frame tube 12 formed of a synthetic resin to form a confinement, such as octagonal, octagonal, hexagonal, circular. The frame tube may be made of polyethylene, polypropylene, polystyrene, or the like. Frame tubes may range from about 200 to 800 mm in diameter to form a cage as a single tube, but usually two or three tubes are assembled by fastening means 4 to form a cage. The unit frame tube 12 is fused to form a cage, and the diameter of the cage is preferably in the range of about 5 to 15 m.

5 is a perspective view of the frame tube for showing the water inlet and outlet 13 installed in the lower portion of the frame tube of the present invention. When air is injected into the frame tube, the cage is floated on the surface of the sea and air is discharged, so that the sea water is injected into the sea. Is installed. It is preferable that water entrances and exits are usually provided at about four places in one frame pipe. For example, in FIG. 1, water inlets 13 are installed at four lower portions of the inner frame tube 3, and water inlets 13 are installed at four portions of the outer frame tube 3 ′.

6 is a perspective view showing an example of a fastening means for fastening two frame tubes, that is, an inner frame tube and an outer frame tube, to each other. The fastening means 4 is formed of a synthetic resin such as polyethylene, like the frame tube 2. The fastening means 4 is provided with storage spaces 43 and 43 'so as to accommodate the frame tube 2 in parallel on both sides, and the frame tube 2 is stored in the storage space and then fastened to support them. Bands 42 and 42 'and fastening rings 41 and 41' are attached. Fastening means having a fastening band and a fastening ring can be easily carried out by those skilled in the art. The fastening means are of course made of steel and can be fastened using bolts and nuts. FIG. 7 is a schematic perspective view illustrating a state in which an inner frame and an outer frame are fastened by the fastening means of FIG. 6.

The fishing net 17 is fixed to the lower portion of the frame tube, there is formed a space in which the fish grow. In the lower part of the fishing net is fixed a lower frame 19 having a sufficient load so that the cage structure submerged in the sea. If necessary, additional weights may be attached further to the bottom of the fishing net. The side portion of the frame tube 2 of the cage farm structure is fixed by a fixing means consisting of a plurality of rich 14, 15 and the rope 18. The depth at which cage farm structures can submerge into the sea is controlled by the length of this rope 18. 8 is a plan view schematically showing a state where one cage farm structure according to the present invention is fixed by a pair of rich people installed in the sea. The rich man 15 is fixed by a rope to the anchor 16 installed in the sea, the rich man 14 is connected to the rich man 15 by a rope, and the cage and the rich man 14 by the rope 18 Connected. Fig. 13 is a schematic perspective view of the rich person 21 which has been used conventionally and can also be used in the present invention.

9 is a schematic front view showing a state in which the cage farm structure of the present invention is floating on the sea surface. The cage farm structure of the present invention farms fish in a state in which air is injected into the frame tube so that the cage is floating on the sea surface. In the state where the cage farm structure is floating on the sea surface, the rope 18 connected to the rich 14 is in a loose state as shown in FIG.

10 is a schematic front view showing a state where the cage farm of the present invention submerged in the sea. The cage farm structure of the present invention farms fish in a state in which air is injected into the frame tube so that the cage is floating on the sea surface. At this time, if the wind is severe and the anemometer 10 of the central control system detects the set wind speed, the automatic valve 9 is opened. When the automatic valve is opened, the air inside the frame pipe is discharged to the outside through the air hose. At this time, the seawater is injected into the frame tube through the water inlet 13. When seawater is injected, the cage cage structure submerges into the sea under the load of the lower frame. At this time, the cage farm structure is submerged by the length of the rope 18 because it is connected by the rope 18 to the rich. That is, when the cage farm submerged in the sea, the rope 18 between the cage and the rich 14 maintains the tension as shown in FIG. This is because of the load of the lower frame 19 installed at the bottom of the fishing net.

When the sea calms down after the storm passes, a person takes a boat to approach the central control system, closes the automatic valve and activates the compressor to inject air into the frame tube. Then, the seawater injected into the frame tube is discharged and the cage is floated to the sea surface.

Fig. 11A is a schematic perspective view of another embodiment of the frame tube, and Fig. 11B is a sectional view thereof. Fig. 11 shows a circular frame tube 12 'having a lower portion of the frame tube in an open shape. In the frame tube 12 as shown in FIG. 5, the water inlet and outlet 13 can be blocked by seaweed or shellfish. Therefore, the open frame tube 12 ′ of FIG. 11 has an advantage of easily removing the foreign matter when it is caught inside the frame tube.

12A is a schematic perspective view of another embodiment of the frame tube, and FIG. 12B is a cross-sectional view thereof. Fig. 12 shows a rectangular frame 12 'in which the lower part of the frame tube is open. The open frame tube 12 'of FIG. 12 also has the advantage of being easily removable when foreign matter gets inside the frame tube.

Cover cages (not shown) should be installed to cover the inlets of cages in order to protect the fish inside the fishing nets when the cage farm structure of the present invention is submerged in the sea. If the cover fishing net is not installed, the fish in the fishing net 17 will go out into the sea when diving into the sea.

The cage farm structure of the present invention can facilitate the operation of feeding the feed into the fishing net while the person walks on it by installing wooden planks and the like above the cage.

When the fish in the fishing net 17 are to be grown and harvested, the fishing net containing the fish must be lifted. The fishing net can be lifted by installing 4 to 20 ropes (not shown) on the side of the fishing net and winding these ropes with a motor (not shown) on the upper part of the cage.

The cage farm structure of the present invention can automatically submerge the fish cage structure to a certain depth in the sea in case of severe storms such as a typhoon, so that the fish can always be safely farmed, and in coastal areas as well as the usual depth of 30 It can be safely installed in offshore areas of ~ 40m.

An object of the present invention is to have a dive control function to float on the surface of the sea or to dive to a certain depth in the sea, and having a dive control function can be safely installed in coastal areas as well as offshore areas having a depth of 30 ~ 40m. In addition, it is possible to prevent the death of fish even if red tide occurs on the surface of the sea or a certain depth of the sea by installing in the deep sea area. In addition, the present invention can provide fish cage structure that can protect fish from various diseases and further reduce the cost of treatment by installing fish in deep sea area.

Simple modifications or variations of the present invention can be readily understood by those skilled in the art, and all such variations or modifications can be considered to be included within the scope of the present invention.

Claims (9)

In a cage farm structure that floats on the surface of the sea when air is injected into the frame tube of the cage and submerges into the sea when air is injected, The frame tube (2) is provided with an air hose (5) for injecting or discharging air and a water inlet (13) for injecting or discharging sea water is installed at the bottom, By fixing means consisting of a plurality of rich (14, 15), anchor 16 and the rope 18 installed in the sea to fix the cage farm structure and adjust the depth to submerge in the sea, Automatic valve 9 for discharging the air of the frame tube to the outside, an anemometer 10 for measuring the wind speed to automatically open the automatic valve and for injecting air into the frame tube through the air hose Cage farm structure, characterized in that floating by the central control system consisting of a compressor (8) or submerged in the sea. The frame tube according to claim 1, wherein the frame tube is fused to each other by the unit frame tube 12 formed of synthetic resin to form a quadrilateral, octagonal, hexagonal or circular curb frame, and the diameter thereof is about 200 to 800 mm. Cage farm structure characterized in that the range. The cage farm structure according to claim 1, wherein the frame pipe is assembled by two fastening means to form a cage. The method of claim 1, wherein the fixing means is composed of a plurality of rich (14, 15) and the rope 18 installed in the sea, the rich 15 is fixed by a rope to a plurality of anchors 16 installed in the sea And, rich (14) is connected to the rich (15) by a rope, the cage and the rich (14) is a cage farm structure, characterized in that connected by the rope (18). 8. The cage farm structure according to claim 7, characterized in that the rope (18) has a length that is loose when the cage farm structure is floating and maintains sufficient diving depth to be taut when the cage farm structure is submerged. According to claim 1, The fastening means 4 is formed in the storage space (43, 43 ') to accommodate the frame tube 2 in parallel on both sides, the frame tube 2 in the storage space After the fastening bands (42, 42 ') and fastening rings (41, 41') for supporting them, cage cage structure, characterized in that attached. 2. The cage farm structure according to claim 1, wherein the frame tube (2) is a circular frame tube having a lower portion thereof in an open form. If the wind of the sea becomes more severe than the set wind speed, the anemometer detects the wind speed and the automatic valve is opened; When the automatic valve is opened, the air inside the frame pipe is discharged to the outside through the air hose; Sea water is injected into the frame tube through the water inlet; And When the seawater is injected, the cage cage structure submerges into the sea by the load of the lower frame; Diving method of cage farm structure, characterized in that consisting of steps. Close the automatic valve by approaching the central control system to float the caged farm structure submerged by the method of claim 12 on the sea surface; Operating the compressor to inject air into the frame tube; Draining the seawater injected into the frame tube; And When the seawater is injected, floating the cage farm structure on the sea surface by buoyancy of air injected into the frame pipe; Floating method of cage farm structure, characterized in that consisting of steps.