KR100643779B1 - The crawl facility for shellfish - Google Patents

Abstract

The present invention relates to a cage for shellfish.

The cage facility of the present invention comprises: an upper center plate to which one side is connected to the mouth; A plurality of empty horizontal buoyancy members and vertical buoyancy members are assembled with a form space therein. The horizontal buoyancy members and the vertical buoyancy members are in communication with each other, and a water outlet is formed at one lower side of the upper center plate. Buoyancy structure is fixed to the upper end; A lower center plate fixed to the lower portion of the buoyancy structure; A bottom structure installed inside the buoyancy structure and having a footrest provided thereon; A plurality of aquaculture vessels fixed on the bottom structure and having a space where shellfish live therein; One side is connected to the lower buoyancy structure, the air supply valve is installed, the other side and the air supply pipe is fixed to the buckle; One side is connected to the upper buoyancy structure, the air discharge valve is installed, the other side is an air discharge pipe is fixed to the buckle; consists of.

According to the present invention, shells inside the cage can be protected from red tide, waves, and natural enemies, and the balance can be well maintained during rising or falling, and the shells are not stolen or lost.

Shellfish, aquaculture, cage, buoyancy, balance

Description

Shell Cage Facility {THE CRAWL FACILITY FOR SHELLFISH}

1 is a perspective view showing a conventional shell cage facility.

Figure 2 is a perspective view of the cut portion of the shell cage facility of the present invention.

Figure 3 is a perspective view showing a state in which the buoyancy structure and the bottom structure of the cage facility installation.

Figure 4 is a schematic cross-sectional view showing a state in which the present cage installation is installed.

Figure 5 is a cross-sectional view showing a state in which the crane lifting ring is installed in the upper center plate of the cage facility.

Figure 6 is a schematic view showing a side connected to the upper center plate and buoyancy structure of the present invention cage facility.

Figure 7 is a schematic view showing a cross-section of the upper center plate and buoyancy structure of the present invention cage facility

8 is a cross-sectional view showing a horizontal buoyancy member and a vertical buoyancy member connected state of the cage facility of the present invention.

Figure 9 is a partial perspective view showing a state in which the culture box is installed on the buoyancy structure of the present invention.

Figure 10 is a partially cut perspective view showing the aquaculture of the cage cage facility of the present invention.

<Detailed Description of Major Symbols in Drawing>

10: upper center plate 11: float

12: crane lifting ring 12a: space member

20: buoyancy structure 21: horizontal buoyancy member

21a: first horizontal buoyancy member 21b: second horizontal buoyancy member

21c: third horizontal buoyancy member 22: vertical buoyancy member

22a: first vertical buoyancy member 22b: second vertical buoyancy member

22c: third vertical buoyancy member 22d: fourth vertical buoyancy member

23: water outlet 23a: water outlet valve

23b: water distribution pipe 24: netting

25 Bracket 26 Bolt

27: flange 28: plate

29: assembling flange 30: lower center plate

40: floor structure 41: outer frame

42: connecting member 43: scaffold

50: form box 51: cover

52 case 52a: outlet

53: partition 54: locking jaw

60: fixing device 61: fixing member

62: fixed rod 70: air supply pipe

71: air supply valve 80: air discharge pipe

81: air discharge valve 82: air distribution pipe

90 anchor 91 anchor weight

100: flotation

The present invention relates to a cage for shellfish.

In general, methods for farming shellfish such as abalone and shellfish have been used in aquaculture using land tanks or in the surface layer of seawater.

Aquaculture using onshore tanks made it difficult to install and maintain facilities by installing seawater and then supplying seawater.

In addition, a method of farming in the surface layer of seawater has been devised, such as 'Overturning farming tools' (Korean Utility Model Registration No. 20-0206641), but the facilities are damaged due to the loss of shellfish due to red tide or strong waves in bad weather. There was a problem that shellfish were likely to be stolen.

In order to solve this problem, the 'shore coastal fishbed fish and shellfish both-side cages' were formed to settle on the bottom of the sea (Korea Patent Publication No. 1992-0000484).

The above facilities raise shellfish at the bottom of the sea and, if necessary, supply and discharge air to the flotation (100) to support the facilities above the sea by buoyancy, but it is difficult to maintain balance when the facilities rise or fall. there was.

In addition, the facility is settled on the bottom of the sea there was a problem that it is difficult to protect shellfish from natural enemies such as starfish.

The shellfish cage facility of the present invention is to solve this problem, by placing a cage for shellfish farming in the water, the shellfish inside the shell from the natural enemy mainly inhabiting the sea bottom and climatic factors caused by red tide and waves, etc. There is a purpose to protect.

In addition, through the supply and discharge of air and water in the buoyancy structure pipe is to lower or raise the cage to a certain position to maintain a good balance during the rise or fall.

There is also an object to secure a plurality of aquaculture vessels inside the buoyancy structure to prevent shellfish from being stolen or lost.

The present invention relates to a cage for shellfish.

The cage facility of the present invention can be fixed at a certain position in the water, thereby protecting shellfish in farming from red tide, waves, and natural enemies.

In addition, the air and water in the buoyancy structure can be moved vertically in accordance with the supply and discharge of water, but both the horizontal buoyancy member and the vertical buoyancy member is connected to maintain a good balance.

In addition, it is possible to secure a large number of shellfish by fixing a plurality of aquaculture boxes therein, so that shellfish are not lost or stolen during the culture.

To this end, the shell cage facility of the present invention, the upper center plate is connected to the buckle on one side; A plurality of horizontal buoyancy members and vertical buoyancy members of a hollow material is assembled with a form space inwardly, but the horizontal buoyancy members and the vertical buoyancy members communicate with each other, and a water outlet is formed at one side of the lower side. A buoyancy structure having an upper end fixed to the upper center plate and configured to move up and down in water according to the amount of air in the horizontal buoyancy member and the vertical buoyancy member; A lower center plate fixed to the lower part of the buoyancy structure and formed of a material having a large mass to hold the center of gravity of the buoyancy structure; A bottom structure installed in a horizontal direction inside the buoyancy structure and having a scaffold installed thereon; A plurality of aquaculture boxes installed on the floor structure and fixed to the top of the floor structure by a fixing device, and having a space in which shellfish live therein; One side is connected to the lower buoyancy structure, the air supply valve is installed, the other side and the air supply pipe is fixed to the buckle; One side is connected to the upper buoyancy structure, the air discharge valve is installed, the other side is an air discharge pipe is fixed to the buckle; consists of.

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

However, the accompanying drawings are only one example for more specifically describing the technical idea of the present invention, and thus the technical idea of the present invention is not limited to the accompanying drawings.

The upper center plate 10, which is a component of the present invention, is connected to the buckle 11 on one side.

The upper center plate 10 may be formed of various materials having a large mass, and is preferably formed of a material such as a stainless steel plate having corrosion resistance.

As shown in FIG. 2, the upper center plate 10 may be connected to a buoy 11 floating on the surface of the water by a line such as a chain or a rope.

The planar shape of the upper center plate 10 may be formed in various squares, spheres and the like in addition to the circular shape.

4 shows an example in which the crane lifting ring 12 is installed on the upper center plate 10, and the crane lifting ring 12 is hooked by a crane when the cage of the present invention is forcibly lifted by the crane. have.

 In addition, the crane lifting ring 12 was able to give a little flow using the spacer member 12a and the like without being completely fixed to the upper center plate (10).

As shown in FIG. 2, the buoyancy structure 20, which is a component of the present invention, is assembled with a plurality of horizontal buoyancy members 21 and vertical buoyancy members 22 having a hollow interior of a solid material, forming a space therein. Formed.

2 and 3 it can be seen that the inner space surrounded by the horizontal buoyancy member 21 and the vertical buoyancy member 22 is a habitat space.

The horizontal buoyancy member 21 and the vertical buoyancy member 22 are in communication with each other so that the horizontal buoyancy member 21 and the vertical buoyancy member 22 is easy to maintain balance in the process of supplying or discharging air.

As shown in FIG. 3, the buoyancy structure 20 has an upper end fixed to the upper center plate 10, and a water discharge port 23 is formed at one lower side thereof so that the horizontal buoyancy member 21 and the vertical buoyancy member 22 are formed. ) As water is supplied and discharged inside, water in the water is discharged or supplied.

That is, according to the amount of air in the horizontal buoyancy member 21 and the vertical buoyancy member 22 is to be able to move up and down underwater.

At this time, by attaching the water discharge valve (23a) to the water discharge port 23 by opening and closing the water discharge valve (23a) according to the user's intention can also control the access of the water inside the buoyancy structure (20).

In addition, in order to allow the water flowing into the buoyancy structure 20 to flow in evenly, each horizontal buoyancy member 21 is connected to a water distribution pipe 23b made of an elastic material such as rubber, and then water on one side of the water distribution pipe 23b. When the outlet 23 and the water discharge valve 23a are formed, water is evenly introduced or discharged to the vertical buoyancy member 22.

Alternatively, when the horizontal buoyancy member 21 is formed below the buoyancy structure 20, the water discharge port 23 and the water discharge valve 23a are not formed in the horizontal buoyancy member 21 without forming a separate water distribution pipe 23b. ) May be installed.

At this time, the horizontal buoyancy member 21 and the vertical buoyancy member 22, which is a component of the buoyancy structure 20, mixed with a material having a specific gravity greater than water and a material having a specific gravity smaller than water in a constant mass ratio, In the state in which the air is filled inside the structure 20, the buoyancy structure 20 is intended to rise above the surface, and when a certain amount of water enters the inside, it is preferable to be fixed at a certain position in the water.

Specifically, when the air is filled in the buoyancy structure 20, it is good to rise above the surface, but when a certain amount of water enters the buoyancy structure 20, it is good to fix it at a certain position in the water.

To this end, the horizontal buoyancy member 21 and the vertical buoyancy member 22 is formed of a hollow tube,

In particular, the buoyancy structure 20 is controlled without excessively supplying or discharging air inside the buoyancy structure 20 by controlling a member having a specific gravity more than water such as a stainless steel pipe and a member having a specific gravity less than water, such as a polyethylene tube. It can be easily moved up and down underwater.

As described above, the buoyancy structure 20 in which a plurality of horizontal buoyancy members 21 and vertical buoyancy members 22 are assembled while communicating inside is different from that of buoyancy members, air rings, etc. installed in the existing cages. It is much easier to maintain the balance, and it is possible to maintain the balance well while moving up and down.

As an example of the buoyancy structure 20, as shown in FIG.

A plurality of first vertical buoyancy members 22a having an upper part fixed to the upper center plate 10 and having a lower part inclined out of the habitat space;

A first horizontal buoyancy member (21a) fixed to an upper portion of the first vertical buoyancy member (22a) and installed in a tube shape along a circumference of the habitat space;

A second vertical buoyancy member (22b) having an upper portion fixed to the first horizontal buoyancy member (21a) and a lower portion formed perpendicularly from the first horizontal buoyancy member (21a);

A second horizontal buoyancy member (21b) fixed to an upper portion of the second vertical buoyancy member (22b) and installed in a tube form along the circumference of the habitat space;

A third vertical buoyancy member (22c) having an upper portion fixed to the second horizontal buoyancy member (21b) and a lower portion formed perpendicularly from the second horizontal buoyancy member (21b);

A third horizontal buoyancy member (21c) fixed to the upper portion of the third vertical buoyancy member (22c) and installed in a tube form along the circumference of the habitat space;

The upper portion is fixed to the third horizontal buoyancy member (21c), the lower portion of the fourth vertical buoyancy member (22d) is formed to be inclined to the interior space; can be configured.

The above configuration is a bulging structure of the center of the buoyancy structure (20).

At this time, the planar shape of the buoyancy structure 20 in which the horizontal buoyancy member 21 is installed may form various shapes such as a circle and a square.

In addition, the number of horizontal buoyancy members 21 and vertical buoyancy members 22 may be reduced or increased so that the overall cross-sectional shape may be formed in a circular or square shape.

6 and 7 illustrate a state in which the upper center plate 10 and the first vertical buoyancy member 22a are connected, and a bracket 25 having a lower portion fixed to the upper center plate 10 and having a bolt hole formed therein. ),

Fasten with the bolts 26 by inserting the plate 28 with the bolt holes to match the bolt holes formed in the bracket 25,

The end of the first vertical buoyancy member 22a was welded and fixed with the flange 27, and one end of the plate 28 was welded and fixed with the flange 27.

The above method is to facilitate the assembly by allowing the first vertical buoyancy member (22a) to flow through the bolt 26 axis.

The above embodiment is only one example of a number of connection methods for connecting the first vertical buoyancy member 22a and the upper center plate 10, and in some cases, the first vertical buoyancy member 22a on the upper center plate 10. May be configured to form a bolt hole to be inserted, and to form a screw thread at the end of the first vertical buoyancy member 22a to be inserted into the upper center plate 10.

Of course, it is preferable that a rubber bar or the like is installed so that water does not flow when screwing.

In addition, the flange 27 may be welded and fixed to the end of the first vertical buoyancy member 22a, and the bracket 25 may be welded to the flange 27 and the upper center plate 10 to be formed.

8 illustrates a state in which the first vertical buoyancy member 22a and the second vertical buoyancy member 22b are connected to the first horizontal buoyancy member 21a.

As shown in the figure, after forming holes in the upper and lower portions of the first horizontal buoyancy member (21a) and then welding the fixing pipe to the hole, the connecting pipe and the first vertical buoyancy member (22a), the connecting pipe and the second vertical buoyancy After joining the members 22b together, the assembly flange 29, the bolts 26, and rubber bars were connected and fixed.

To this end, the assembling flange 29 used that the hole is formed is inserted into the connector.

At this time, in addition to the above method, the hole is formed in the first horizontal buoyancy member 21a, and the first vertical buoyancy member 22a and the second vertical buoyancy member 22b are inserted into the hole to be connected and fixed. It may be.

In other assembling methods, one side of the tubes to be assembled with each other may have a larger diameter to insert one tube into the other tube, and then seal the insertion part by external rubber baring or the like.

The above connection method is applied to the connection method of the other vertical buoyancy member 22 and the horizontal buoyancy member 21 together.

Lower center plate 30 is a component of the present invention is fixed to the lower portion of the buoyancy structure (20).

Like the upper center plate 10, the lower center plate 30 may be formed of various materials having a large mass, and may be formed of a material such as a stainless steel plate having corrosion resistance.

In the example in which the lower center plate 30 is assembled to the buoyancy structure 20, the flange is welded to the end of the lowest vertical buoyancy member 22 in the same way as the upper center pipe is assembled to the buoyancy structure 20 from above, and the bolt is fixed. After fixing one side of the plate 28 in which the hole is formed to the flange 27, a bracket 25 having bolt holes formed on both sides of the plate 28 may be attached and fastened to the bolt 26.

As described above, the vertical buoyancy member 22 at the bottom of the buoyancy structure 20 is rotatable from the lower center plate 30 to facilitate assembly.

In addition, after welding the flange to the end of the vertical buoyancy member 22, the flange and the lower center plate 30 may be fixed by welding.

The floor structure 40, which is a component of the present invention, is installed in the horizontal direction inside the buoyancy structure 20, and the scaffold 43 is provided at the top thereof.

The floor structure 40 may be formed in various ways.

For example, as shown in Figure 2 and the outer frame 41 which is fixed inside the horizontal buoyancy member 21;

It can be configured; a plurality of connecting members 42 installed inside the outer frame 41.

At this time, the fixing method of the outer frame 41 and the horizontal buoyancy member 21 is welded fixed to the connecting pipe to the outer frame 41 as shown in the drawing, and then welded and fixed to the connecting pipe,

The outer frame 41 can be fixed by bolting each flange after welding fixing the connection pipe and the flange.

In addition, the outer frame 41 may be directly welded to the horizontal buoyancy member 21,

After the installation of the connecting pipe welded to the outer frame 41 and the horizontal buoyancy member 21, the flange to the connector can be welded fixed or the welded pipes may be fixed.

In the configuration as described above, the outer frame 41 is not limited to only the tube as shown in the figure, it can be used a steel member, stainless steel member, polyethylene member and the like having a variety of cross-sectional shape.

In addition, in addition to the method of forming the outer frame 41 and the plurality of connection members 42 as the configuration of the bottom structure 40 may be formed in various configurations of the structure that can support the upper load.

The scaffold 43 may use various scaffolds that are mainly used in aquaculture farms, and may be installed by assembling the scaffolds having a plurality of water exit holes to facilitate water permeation.

The farm 50 is a component of the present invention is installed on the bottom structure 40 is fixed to the top of the bottom structure 40 by a fixing device, there is formed a space in which shellfish inhabit.

The aquaculture box 50 may be formed in various forms. As a representative example, as shown in FIG. 10, a cover 51 and a case 52 for opening and closing an opened upper surface, and a partition 53 installed inside the case. It can be configured as.

The lid 51 can also be configured to be rotatable by a hinge or the like.

It is preferable that a plurality of water outlets 52a are formed in the case 52.

That is, by allowing the seawater to move through the outlet 52a, fresh seawater is supplied to the shellfish that are farmed therein.

At this time, the size of the water outlet 52a is preferably formed so that shells inside the case 52 do not escape out of the case 52.

As shown in the figure, the partition 53 is provided by the locking jaw 54 on both sides of the inner wall of the case 52 and is inserted between the locking jaws 54.

When the partition 53 is installed, the contact area of the shellfish is widened, and a large number of shellfish can be farmed in a narrow space.

The configuration of the culture box 50 is not limited to that described above, it is possible to install a variety of forms such as a grill type, a pallet type known in the art.

The fixing device 60 may be formed in various forms.

For example, as shown in the figure is installed on the upper portion of the conscience 50, the fixing member 61 is formed with a bolt hole on one side,

After being inserted into the bolt hole of the fixing member 61, the bolt is fastened so that the fixing member 62 may be configured to fix the fixing member on the farm 50.

At this time, the lowering of the fixing rod 62 is fixed by bolting to the bottom structure (40).

This form 50 may be stacked in a plurality of layers.

At this time, after the fixing member 61 is placed on the upper side of the upper box 50, the fixing bar 62 is fixed to the fixing member 61 at the uppermost end, and the lower form is fixed to the bottom structure 40. Can be fixed

In addition, after the fixing member 61 is placed on the upper box 50 of each layer, the layered fixing member 61 may be fixed to the bottom structure 40 with the fixing rod 62.

At this time, as shown in the figure, the fixing device may fix a plurality of farms 50 at once.

The above description is only one example of various configuration methods of the fixing device 60, and may be composed of a rope or a wire that binds the upper side and the side of the culture box 50, and a plate covering the plurality of the culture box 50 upper part. After providing the plate may be formed by fixing the plate to the buoyancy structure 20 or the bottom structure 40 with a bolt or the like.

Air supply pipe 70 is a component of the present invention is connected to the buoyancy structure 20, the air supply valve 71 is installed on one side, the other side is fixed to the upper mouth (11).

The end of the air supply pipe 70 may be installed in the vertical buoyancy member 22 or the horizontal buoyancy member 21 below the buoyancy structure 20.

2 illustrates a case in which the air supply pipe 70 is installed at the lowest vertical buoyancy member 22.

At this time, in order to supply air more evenly to the lower portion of the buoyancy structure 20, a distributor for distributing the air supply to each vertical buoyancy member 22 or a rubber tube for connecting between the vertical buoyancy member 22 is installed. After connecting the air supply pipe 70 to one side of the rubber pipe or may be provided with an air supply pipe 70 in the horizontal buoyancy member (21).

Air discharge pipe 80 is a component of the present invention is connected to the buoyancy structure 20, the air discharge valve 81 is installed on one side, the other side is fixed to the upper opening (11).

The air discharge pipe 80 and the buoyancy structure 20 are connected to each other at the top of the vertical buoyancy member 22 or the horizontal buoyancy member 21 such as the first vertical buoyancy member 22a or the first horizontal buoyancy member 21a. Is connected to.

At this time, when there is no horizontal buoyancy member 21 in the upper portion may be connected to the air distribution pipe 82 after connecting between the vertical buoyancy member 22 with the air distribution pipe 82 as shown in FIG.

The other side of the air supply pipe 70 and the air discharge pipe 80 is connected to the upper side of the buckle 11, it may be installed to the outside of the buoyancy structure 20, preferably to the inside of the buoyancy structure 20 It is preferable to install and drill a hole in the upper center plate 10 to pass through the hole of the upper center plate 10 to be connected to the buckle 11.

In addition, it is preferable to bundle the two pipes with a coupling or the like, and to provide an air supply valve 71 and an air discharge valve 81 on the side connected to the buckle 11.

In the above configuration,

In the above configuration, as shown in FIG. 4, the anchoring weight 91 and the anchor 90 may be further installed on the buoyancy structure 20 or the bottom structure 40.

Fixing weight 91 is connected to the buoyancy structure 20 by a rope or chain rope serves to assist in fixing the position of the buoyancy structure (20).

The time point at which the anchoring weight 91 is connected to the buoyancy structure 20 or the bottom structure 40 may be installed after the cage facility of the present invention is positioned in the water, and the buoyancy structure 20 and the bottom structure 40 may be installed. You can also connect first and then set the location of the cage facility.

Therefore, it is preferable that the fixed weight 91 is firmly connected to the cage facility after the installation.

Anchor 90 is connected to the buoyancy structure 20, such as ropes or chains, similar to the fixed weight 91, is to prevent the buoyancy structure 20 to move by the flow of underwater currents.

In the above configuration, the net 24 can be installed on the outside of the buoyancy structure.

As shown in the figure, the mesh 24 may be provided only on the upper side of the buoyancy structure.

Of course, the entire buoyancy structure may be installed in such a way as to cover all but since the bottom is blocked by the footrest of the bottom structure 40, it is good to install up to the bottom structure 40 position.

The method of fixing the mesh 24 may be fixed by using each joint portion of the buoyancy structure 20 or by using a string or a ring.

The net 24 has various effects, first of which serves as an assistant to prevent external intrusion into the water.

That is, it is difficult to steal shellfish from the outside by the mesh 24 and the fixing device 60 and the like.

In addition, when the net spacing of the net 24 is small, even if the shellfish in the aquaculture box 50 is separated out of the aquaculture box 50 may be prevented from escaping to the outside by the net 24.

In particular, when forming a small gap of the net 24 may be formed in the form without a cover instead of the above form (50).

In other words, due to the nature of the nocturnal shellfish, it is to be active in the habitat space inside the buoyancy structure at night and to return to the culture box (50) during the day.

In the configuration as described above, it is preferable to install the self-powered lamp or luminous plate as is known, the buckle 11 is easy to grasp the position of the cage facility at night.

In addition, by attaching a marking object at regular intervals between the upper core plate 10 and the line connecting the buckle 11, it is possible to easily determine how many meters the underwater position of the buoyancy structure 20.

Referring to the operation of the present invention configured as described above are as follows.

First of all, the process of assembling continues by first assembling the horizontal buoyancy member 21 to the vertical buoyancy member 22 and then fixing the vertical buoyancy member 22 of the buoyancy structure 20 to the upper center plate 10. Afterwards, the lower center plate 30 may be fixed to the vertical buoyancy member 22 at the bottom thereof.

The installation of the air supply pipe 70 and the air discharge pipe 80 may be installed regardless of whether the buoyancy structure 20 is installed before or after the installation.

At this time, the air supply pipe 70 and the air discharge pipe 80 is to be connected to the air supply pipe 70 and the air discharge pipe 80 and the upper opening 11 through the hole after drilling a hole in the upper center plate (10) It is desirable to prevent damage from the outside.

When the cage is settled to a predetermined position in the water as installed above, the air inside the buoyancy structure 20 is discharged to the outside through the air discharge valve 81 when the settled after opening the upper air discharge valve 81. As the water flows in from the bottom of the buoyancy structure 20, the buoyancy structure 20 is settled.

When the desired depth is reached, the air discharge valve 81 is locked to prevent the air from escaping any more, and then the anchor 90 and the fixing weight 91 are attached to the lower portion of the buoyancy structure 20 so that the buoyancy structure ( 20) do not flow.

In this case, if the sedimentation continues after a certain depth, the air supply valve 71 may be opened and air may be blown from the outside until the cage facility no longer sinks.

When the cage is to be raised above the water surface, the air supply valve 71 is opened and the air supply valve 81 while closing the air supply valve is raised.

At this time, it is good to configure the buoyancy structure so that the position of the aquaculture tank 50 is somewhat higher than the sea level when the cage is raised after the shellfish of the aquaculture tank 50 is fully grown.

The configuration of lowering and rising in the above manner is that the buoyancy structure 20 is settled in the desired position since the air inside the buoyancy structure 20 is equally filled from the top during sedimentation or ascent.

In addition, even after positioning the buoyancy structure 20 in a desired position, the net is fixed by the horizontal buoyancy member 21 and the vertical buoyancy member 22 made of a rigid material, so that the net does not swing due to waves or currents, and balances. It can be maintained.

The method of feeding the shellfish in the aquaculture box 50 may raise the cage facility as described above to feed the inside of the aquaculture box 50 directly, or form a feed supply line to support the cage without raising the cage facility. It is also possible to feed the bin 50.

According to the present invention, shellfish inside the cage can be protected from climatic factors caused by red tide, waves and the like and natural enemies mainly on the sea bottom.

In addition, the supply and discharge of air and water in the buoyancy structure pipe to lower or raise the cage to a certain position, it is possible to maintain a good balance during the rise or fall.

In addition, by fixing a plurality of aquaculture vessels inside the buoyancy structure, it is possible to farm a number of shellfish without the threat of theft and loss.

Claims (7)

In the cage facility, An upper center plate to which side parts are connected to one side; A plurality of horizontal buoyancy members and vertical buoyancy members of a hollow material is assembled with a form space inwardly, but the horizontal buoyancy members and the vertical buoyancy members communicate with each other, and a water outlet is formed at one side of the lower side. A buoyancy structure having an upper end fixed to the upper center plate and configured to move up and down in water according to the amount of air in the horizontal buoyancy member and the vertical buoyancy member; A lower center plate fixed to the lower portion of the buoyancy structure and formed of a material having a large mass to hold the center of gravity of the buoyancy structure; A bottom structure installed horizontally inside the buoyancy structure and having a scaffold provided thereon; A plurality of aquaculture vessels installed on the bottom structure and fixed to the top of the bottom structure by a fixing device and having a space in which shellfish live therein; One side is connected to the lower buoyancy structure, the air supply valve is installed, the other side and the air supply pipe is fixed to the buckle; One side is connected to the buoyancy structure upper portion, the air discharge valve is installed, the other side is an air discharge pipe is fixed to the float; Shell cage facility.  The method of claim 1, The buoyancy structure or the lower center plate, characterized in that the anchor and fixing is installed, Shell cage facility. The method according to claim 1 or 2, Characterized in that the net is installed on the outside of the buoyancy structure, Shell cage facility. The method according to claim 1 or 2, The buoyancy structure is formed by assembling a pipe made of a material having a higher specific gravity than water and a pipe made of a material having a specific gravity less than water. The buoyancy structure rises above the surface when the air is filled inside the pipe. When it entered this inside, it was fixed to a fixed position of the water, characterized by the above-mentioned, Shell cage facility. The method according to claim 1 or 2, The buoyancy structure, A plurality of first vertical buoyancy members, the upper portion of which is fixed to the upper center plate and the lower portion of which is inclined out of the habitat space; A first horizontal buoyancy member fixed to an upper portion of the first vertical buoyancy member and installed in a tube shape along a circumference of the habitat space; A second vertical buoyancy member having an upper portion fixed to the first horizontal buoyancy member and having a lower portion vertically formed from the first horizontal buoyancy member; A second horizontal buoyancy member fixed to an upper portion of the second vertical buoyancy member and installed in a tube form along a circumference of the habitat space; A third vertical buoyancy member having an upper portion fixed to the second horizontal buoyancy member and having a lower portion vertically formed from the second horizontal buoyancy member; A third horizontal buoyancy member fixed to the third vertical buoyancy member and installed in a tube form along the circumference of the habitat space; And a fourth vertical buoyancy member having an upper portion fixed to the third horizontal buoyancy member, a lower portion formed to be inclined into the habitat space, and a lower end fixed to the lower center plate. Shell cage facility. The method according to claim 1 or 2, The bottom structure and the outer frame is fixed inside the horizontal buoyancy member; Characterized in that consisting of; a plurality of connecting members installed inside the outer frame; Shell cage facility. The method according to claim 1 or 2, Characterized in that the aquaculture box is stacked in multiple layers, Shell cage facility.

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