KR102188713B1 - the improved farming cages structure for variable lifting control - Google Patents

Abstract

The present invention is for cage farming of marine organisms including fish,
A cage assembly unit 100 in which the marine organisms are cultured;
A buoyancy pipe 200 installed under the cage cage assembly unit 100;
A buoyancy body 400 connected to the buoyancy pipe 200 and the buoyancy hose 300 and floating on the water surface;
A main rope (MR) forming a polygonal grid underwater;
An anchor AC fixed to the sea floor by diagonally connected to the edge of the main rope MR by a rope R;
The main buoyancy body 500 is vertically connected to the edge of the main rope (MR) and the rope (R) floating on the water surface;
A clearance rope (SR) connecting the edge of the main rope (MR) and the edge of the cage cage assembly unit 100;
It is composed including,
Normally, the cage cage assembly unit 100 is submerged underwater by its own weight,
When air is introduced into the buoyant hose 300 connected to the buoyant hose fixed buoyancy body 400, air is introduced into the buoyancy pipe 200 so that the cage cage assembly unit 100 floats to the water surface by buoyancy. It provides an improved cage structure capable of variable flotation control.

Description

The improved farming cages structure for variable lifting control

The present invention is for cage farming of marine organisms including fish, and it is possible to cultivate even in distant seas off the coast, and by controlling the depth of water to avoid weather changes such as water temperature rise, waves, typhoons, etc. by using buoyancy, It relates to an improved cage structure capable of variable flotation control.

1 is a photograph of a conventional surface structure.

The structure of the surface layer is generally referred to as a cage, and is a sub-bridge type.

The surface structure has the advantage that facility management is easy and economical, but due to its structure, it is not possible to install it in the open sea, which is a distant sea, and has a disadvantage in that it is less responsive to typhoons, warming, and internal currents.

Figure 2 is a photograph of a conventional railroad structure.

The railroad frame structure is economical and has a strong advantage against tidal currents, but it has a disadvantage in that its structure is narrow and, like the surface structure, it cannot be installed in the open sea, which is a distant sea, and its responsiveness to typhoons and warming is poor.

3 is a photograph of a conventional wave-resistant cage structure.

The wave-resistant cage structure has the advantage that it can be farmed in the open sea, unlike the surface-layer cage structure or the railroad edging structure in a sub-bridge method, but there is still a high risk of warming damage and there is a problem that theft concern increases when installed in the open sea.

Accordingly, the inventors compensate for all the shortcomings of the above-described conventional cage structure so that cultivation is possible in distant seas off the coast, and by using buoyancy, the water depth is adjusted to avoid weather changes such as water temperature rise, waves, typhoons, etc. It came to the development of an improved cage structure capable of variable flotation control.

[Document 1] Republic of Korea Utility Model Registration No. 20-0484611'Gaduri for abalone farming', September 22, 2017 [Document 2] Korean Patent Registration No. 10-1172032'Marine Fishing Fence Structure', August 1, 2012

The present invention is presented in order to solve all the conventional problems as described above. Its purpose is to cultivate the cages of marine organisms including fish, and it is possible to cultivate in the far seas off the coast, and by using buoyancy, the water depth is adjusted to avoid weather changes such as water temperature rise, waves, typhoons, etc. It is intended to provide an improved cage structure capable of variable flotation control.

In order to solve the above technical problem, the present invention is for cage cultivation of marine organisms including fish,

A cage assembly unit 100 in which the marine organisms are cultured;

A buoyancy pipe 200 installed under the cage cage assembly unit 100;

A buoyancy body 400 connected to the buoyancy pipe 200 and the buoyancy hose 300 and floating on the water surface;

A main rope (MR) forming a polygonal grid underwater;

An anchor AC fixed to the sea floor by diagonally connected to the edge of the main rope MR by a rope R;

The main buoyancy body 500 is vertically connected to the edge of the main rope (MR) and the rope (R) floating on the water surface;

A clearance rope (SR) connecting the edge of the main rope (MR) and the edge of the cage cage assembly unit 100;

It is composed including,

Normally, the cage cage assembly unit 100 is submerged underwater by its own weight,

When air is introduced into the buoyant hose 300 connected to the buoyant hose fixed buoyancy body 400, air is introduced into the buoyancy pipe 200 so that the cage cage assembly unit 100 floats to the water surface by buoyancy. It provides an improved cage structure capable of variable flotation control.

According to the present invention, it is for cage cultivation of marine organisms including fish, and it is possible to cultivate in distant seas off the coast, and by using buoyancy, the water depth is adjusted to avoid weather changes such as water temperature rise, waves, typhoons, etc. It provides an improved cage structure capable of variable flotation control.

1 is a photograph of a conventional surface structure.
Figure 2 is a photograph of a conventional railroad structure.
3 is a photograph of a conventional wave-resistant cage structure.
4 is a conceptual diagram of an improved cage structure capable of variable flotation control of the present invention.
Figure 5 shows a state in the underwater subsidence the improved cage structure capable of variable flotation control of the present invention.
FIG. 6 is a view showing an emphasis on the underwater structure in FIG. 5.
7 is an enlarged view of FIG. 5.
8 is an enlarged view of FIG. 6.
9 is a view showing a state in which the improved cage structure capable of variable flotation control of the present invention is injured on the surface.
10 is an enlarged view of FIG. 9.
11 is a view of FIG. 9 viewed from a distance.
12 shows the structure in FIG. 11 with emphasis.
13 shows a state in which the improved cage structure capable of variable flotation control of the present invention is submerged in water.
14 to 24 show sequentially the appearance of a ship approaching the improved cage structure capable of variable flotation control of the present invention, floating to the surface, harvesting and leaving.
Figure 25 shows an upper frame constituting the cage cage assembly unit in the present invention.
26 shows a connector when the upper frame is configured in units of the present invention.
27 is a plan view, a right side view, a front view, and a rear view of the cage assembly unit according to the present invention in order.
28 is a plan view and a side view of an improved cage structure capable of variable flotation control of the present invention installed in a distant sea.
29 is a plan view and a side view of an improved cage structure capable of variable flotation control of the present invention installed on the coast.
30 and 31 show the coupling relationship between the buoyancy body and the rope.
FIG. 32 shows an embodiment of the connector in FIG. 26.

Hereinafter, the present invention will be described in more detail through embodiments in which the concept of the present invention as described above is preferably implemented together with the accompanying drawings.

4 is a conceptual diagram of an improved cage structure capable of variable flotation control of the present invention.

As shown,

The improved cage structure capable of variable flotation of the present invention is for cage cultivation of marine organisms including fish,

A cage assembly unit 100 in which the marine organisms are cultured;

A buoyancy pipe 200 installed under the cage cage assembly unit 100;

A buoyancy body 400 connected to the buoyancy pipe 200 and the buoyancy hose 300 and floating on the water surface;

A main rope (MR) forming a polygonal grid underwater;

An anchor AC fixed to the sea floor by diagonally connected to the edge of the main rope MR by a rope R;

The main buoyancy body 500 is vertically connected to the edge of the main rope (MR) and the rope (R) floating on the water surface;

A clearance rope (SR) connecting the edge of the main rope (MR) and the edge of the cage cage assembly unit 100;

It is composed including,

Normally, the cage cage assembly unit 100 is submerged underwater by its own weight,

When air is introduced into the buoyant hose 300 connected to the buoyant hose fixed buoyancy body 400, air is introduced into the buoyancy pipe 200 so that the cage cage assembly unit 100 floats to the water surface by buoyancy. It is characterized.

The anchor (AC) uses a conventional anchor or a concrete structure.

5 is a view showing a state in which the improved cage structure capable of variable flotation control of the present invention is submerged in water, and FIG. 6 is a view showing an emphasis on the underwater structure in FIG. 5.

7 is an enlarged view of FIG. 5 and FIG. 8 is an enlarged view of FIG. 6.

9 is a view showing the state of the improved cage structure capable of variable flotation control of the present invention when the surface is injured, and FIG. 10 is an enlarged view of FIG.

FIG. 11 is a view of FIG. 9 viewed from a distance, and FIG. 12 shows the structure in FIG. 11 with emphasis.

13 shows a state in which the improved cage structure capable of variable flotation control of the present invention is submerged in water.

14 to 24 show sequentially the appearance of a ship approaching the improved cage structure capable of variable flotation control of the present invention and floating on the surface and feeding the fish to be cultured or harvesting and leaving mature fish.

Specifically,

(1) As shown in Fig. 14, a ship approaches the improved cage structure capable of variable flotation control of the present invention, which is submerged by its own weight.

(2) As shown in Fig. 15, the ship introduces air into the buoyancy hose 300 connected to the buoyancy body 400 fixed to the buoyancy hose.

(3) As shown in Figs. 16 to 18, the cage cage assembly unit 100 floats as the buoyancy increases.

(4) As shown in FIG. 19, the cage assembly unit 100 finally floats on the water surface.

(5) As shown in Figs. 20 to 24, after feeding or ending the harvest of fish, air is discharged to the buoyancy hose 300 connected to the buoyancy hose fixed buoyancy body 400, and then the boat leaves.

Figure 25 shows an upper frame constituting the cage assembly unit in the cage in the present invention,

26 shows a connector when the upper frame is configured in units of the present invention.

And FIG. 27 is a plan view, a right side view, a front view, and a rear view of the cage assembly unit according to the present invention in order.

The cage cage assembly unit 100,

The upper frame 110 of the upper;

A lower weight ring 190;

An upper net 160 covering the upper frame 110;

A lower net 180 covering the weight ring 190;

A mesh net 170 surrounding side surfaces of the upper frame 110 and the weight ring 190;

Including,

The buoyancy pipe 200 is installed in the upper frame 110,

The upper frame 110 and the weight ring 190 have a heavy self-weight,

The upper frame 110 and the weight of the weight ring 190 is characterized in that in normal times, the cage assembly unit 100 is submerged in the water by its own weight.

In addition, the mesh mesh 170 may be made of a wire mesh or resin mesh having excellent durability and corrosion resistance.

Conventionally, PE pipes were mainly used in consideration of only corrosion resistance as the upper frame 110, but in the present invention, steel pipes coated with aluminum are mainly used in order to provide corrosion resistance and induce submersion by its own weight.

In addition, the upper frame 110 as shown in FIG. 25 may be manufactured and connected as members of several unit units, and at this time, the triangular connector 150 shown in FIG. 26 serves to connect members of several unit units.

In addition, as shown in FIG. 25, the upper frame 110 is preferably designed in a triangular shape with an inclined upper vertex in the same manner as the connector 150 in order to install the footrest 130 to be used by workers.
FIG. 32 shows an embodiment of the connector in FIG. 26.
In addition, the upper frame 110 has a triangular-shaped connector 150 in which the upper vertex is inclined inward; the members of the unit unit are connected, and the first pipe 111 is installed at the upper vertex, and an obtuse angle is provided. Since the second pipe 113; is installed at the vertex and the third pipe 115; is installed at the remaining vertices, the scaffolding 130 on the second pipe 113 and the third pipe 115 It is characterized in that it can be installed.

The buoyancy pipe 200 is shown in Figs. 27 (a) and (b) in an embodiment installed at the front and rear sides of the upper frame 110, but the installation position and number of installations can be adjusted according to the situation of the field. .

And between the upper frame 110 and the weight ring 190, by installing a traction rope (PR) as shown in Figures 27 (b) and ⓒ, pulling or loosening the traction rope (PR), the mesh net 170 The height of the can be adjusted, and in particular, pulling the pulling rope (PR) is advantageous when harvesting fish inside the aquaculture mappin.

The present invention controls the amount of air introduced into the buoyancy pipe 200,

The cage cage assembly unit 100 is characterized in that it is possible to adjust the settlement depth of the cage cage assembly unit 100 according to weather changes including typhoons by controlling the buoyancy. Specifically, when air is introduced into the buoyancy pipe 200, buoyancy increases and rises, and when water is introduced, buoyancy decreases and sinks. At this time, a conventional check valve or the like is installed in the buoyancy pipe 200 to play its role.

Typically, the temperature of seawater shows a rapid temperature change in the surface layer, and the width of the temperature change decreases sharply as it deepens.

Therefore, the improved cage structure capable of variable flotation of the present invention maintains a depth of about 10m in order to reduce high-temperature damage in normal times, and in case of emergency such as a typhoon or a storm, it is possible to minimize damage by sinking to a depth of 20m or less.

At this time, the depth of the subsidence may be measured with the length of the buoyancy hose 300, but may be operated by attaching a separate depth gauge.

28 is a plan view and a side view of an improved cage structure capable of variable flotation control of the present invention installed in a distant sea, and FIG. 29 is a plan view and a side view of the improved cage structure capable of variable flotation control of the present invention installed on the coast.

As shown in Figs. 28 and 29, the present invention can be variously applied in distant seas and coasts by varying the installation position of the anchor AC and the length of the rope R according to the depth of water.

30 and 31 show the coupling relationship between the buoyancy body and the rope.

Specifically,

In FIG. 30(a), dotted lines A and B show the rope connected to the main buoyancy body 500, and FIG. 30(b) is an enlarged view of the dotted line A, and FIG. 30(c) is an enlarged view of the dotted line B. .

In particular, in FIG. 30(c), a number of ropes such as a main rope (MR) and a rope (R) are bound under the main buoyancy body 500, and in this case, as shown in FIG. 31, a circular ring RR is used.
In addition, a circular ring (RR) with irregularities formed on the surface is installed under the main buoyancy body 500, and the main rope (MR) and the rope (R) approach the circular ring (RR) from several directions. Thus, even if it is bound, it is characterized in that the local load is reduced and the entire load is distributed to the binding portion due to the circular shape of the circular ring RR, and the binding portion is not released due to the irregularities.

The present invention has been described in connection with a preferred embodiment as mentioned above, but various modifications and variations can be made without departing from the gist of the present invention, and can be used in various fields.

Accordingly, the claims of the present invention include modifications and variations that fall within the true scope of the invention.

AC: anchor
MR: Main rope
R: rope
RR: ring
SR: clearance rope
100: cage cage assembly unit
110: upper frame
111: first pipe
113: second pipe
115: third pipe
130: footrest
150: connector
160: upper net
170: mesh net
180: lower net
190: weight ring
200: buoyancy pipe
300: buoyancy hose
400: buoyancy hose fixed buoyancy body

Claims (4)

It is for cage farming of marine life including fish,
A cage assembly unit 100 in which the marine organisms are cultured;
A buoyancy pipe 200 installed under the cage cage assembly unit 100;
A buoyancy body 400 connected to the buoyancy pipe 200 and the buoyancy hose 300 and floating on the water surface;
A main rope (MR) forming a polygonal grid underwater;
An anchor AC fixed to the sea floor by diagonally connected to the edge of the main rope MR by a rope R;
The main buoyancy body 500 is vertically connected to the edge of the main rope (MR) and the rope (R) floating on the water surface;
A clearance rope (SR) connecting the edge of the main rope (MR) and the edge of the cage cage assembly unit 100;
It is composed including,
Normally, the cage cage assembly unit 100 is submerged underwater by its own weight,
When air is introduced into the buoyant hose 300 connected to the buoyant hose fixed buoyancy body 400, air is introduced into the buoyancy pipe 200 so that the cage cage assembly unit 100 floats to the water surface by buoyancy. But as a feature,
The cage cage assembly unit 100,
The upper frame 110 of the upper;
A lower weight ring 190;
An upper net 160 covering the upper frame 110;
A lower net 180 covering the weight ring 190;
A mesh net 170 surrounding side surfaces of the upper frame 110 and the weight ring 190;
Including,
The buoyancy pipe 200 is installed in the upper frame 110,
The upper frame 110 and the weight ring 190 have a heavy self-weight,
With the weight of the upper frame 110 and the weight ring 190, the cage assembly unit 100 is usually submerged in the water by its own weight,
The upper frame 110,
A triangular-shaped connector 150 with the upper vertex inclined inward; a unit unit member is connected, a first pipe 111 is installed at the upper vertex, and a second pipe 113 at the obtuse vertex; It is installed, and since the third pipe 115; is installed at the rest of the outer vertices, the scaffold 130 can be installed on the second pipe 113 and the third pipe 115,
Under the main buoyancy body 500, a circular ring RR with irregularities formed on the surface is installed, so that the main rope MR and the rope R approach the circular ring RR from several directions and are bound Due to the circular shape of the circular ring (RR), the local load is reduced and the entire load is distributed to the binding portion, and the binding portion is not released due to the irregularities.
delete delete In claim 1,
By adjusting the amount of air introduced into the buoyancy pipe 200,
An improved cage structure capable of variable flotation, characterized in that the cage cage assembly unit 100 can adjust the depth of settlement of the cage cage assembly unit 100 according to weather changes including typhoons by adjusting the buoyancy force.

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