KR20200063853A - Floating fish cage - Google Patents

Abstract

According to one embodiment of the present invention, provided is a floating fish cage for easy movement. The floating fish cage according to one embodiment of the present invention comprises: a lower structure having a buoyancy tank that controls buoyancy by making seawater flow in and out; an upper structure spaced apart from the lower structure and positioned above the lower structure; a plurality of first connection chains connecting the lower structure to the upper structure; a cage structure including a mesh that forms a culture space by blocking a portion between the lower structure and the upper structure; and a control tower coupled to the cage structure to control the buoyancy tank and exposed to the upper porion of the sea level.

Description

Floating fish cage

The present invention relates to a cage farm, more specifically, to control the volume of the cage structure, and the separation of the control tower and the cage structure is easy to move and relates to a cage farm that can effectively cope with external forces.

In general, a cage farm refers to a facility that installs a net for a certain range in water bodies such as the coastal waters or the open sea, and farms various fish therein, and is usually installed in the coastal waters less than 3 km from the coast. . However, if a fish farm is installed in the coastal waters within 3 km, the fish will be killed by red tide, the facility will be damaged due to strong waves in bad weather such as typhoon, or oil will leak due to a ship accident to increase the damage to aquaculture. Problems frequently occurred. In order to solve these problems, recently, a cage farm is being moved to an open sea with relatively little influence of waves and currents. However, when a cage is installed in the open sea, monitoring of farmed fish and management of feed, etc. There is an easy problem. Also, in case of emergency, the street farm should be moved to a safe area, but there is a problem in that it is not easy to move because it is bulky.

As a result, it is necessary to have a cage farm with a structure in which fish can be easily managed and easily moved by a manager.

Republic of Korea Patent Publication No. 10-2012-0111313 (2012. 10. 10.)

The technical problem to be achieved by the present invention is to provide a cage farm that can control the volume of the cage structure and separate the control tower and the cage structure to facilitate movement and effectively cope with external forces.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

A cage farm according to an embodiment of the present invention for achieving the above technical problem, a substructure in which a buoyancy tank is installed to control buoyancy by flowing in and out of seawater, and a superstructure located above the substructure spaced apart from the substructure. , A plurality of first connecting chains connecting the lower structure and the upper structure, and a cage structure including a mesh forming a space to form a space by blocking between the lower structure and the upper structure, and coupled to the cage structure, It controls the buoyancy tank and includes a control tower exposed above the sea level.

The control tower and the cage structure are detachably coupled to each other, and the control tower has buoyancy, so that it can be independently floated above the sea level.

The control tower may include a residential area exposed above the sea level, and at least a portion of the buoyancy located in the water, and supporting the residential area, but passing through the upper structure to be coupled to the edge structure.

The cage farm further includes a second connecting chain penetrating through the center of the cage structure and connecting the column part and the substructure, wherein the second connecting chain is located at the seashore and the cage structure located in the water. The control tower can be connected in a spaced apart state.

The column portion may penetrate the center of the cage structure and be exposed to the bottom of the substructure.

According to the present invention, the gap between the substructure and the superstructure can be adjusted by adjusting the buoyancy of the substructure. Therefore, the size of the aquaculture space can be freely varied, and the entire volume can be adjusted to facilitate traction. In addition, it is easy to manage the fish because the control tower is provided for the manager to stay, and the control tower can be separated from the cage structure to effectively cope with external forces such as waves, currents, typhoons, and red tides.

1 is a perspective view showing a cage farm according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of the cage farm of FIG. 1 cut in the longitudinal direction.
3 is an operation diagram for explaining the operation of the cage farm.
4 is a cross-sectional view showing a cage farm according to another embodiment of the present invention.

Advantages and features of the present invention, and methods for achieving them will be clarified with reference to embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only the embodiments allow the disclosure of the present invention to be complete, and common knowledge in the technical field to which the present invention pertains. It is provided to completely inform the person having the scope of the invention, and the present invention is only defined by the scope of the claims. The same reference numerals refer to the same components throughout the specification.

Hereinafter, a cage farm 1 according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 4.

A cage farm according to an embodiment of the present invention is a facility for farming various fish, and is towed by a towing vessel and can be installed in waters such as the coastal waters or the open sea.

The cage farm can control the buoyancy of the substructure to control the gap between the substructure and the superstructure. Therefore, the size of the aquaculture space can be freely varied, and the entire volume can be adjusted to facilitate traction. In addition, it is easy to manage the fish because it has a control tower where the manager can stay, and the control tower can be separated from the cage structure to effectively cope with external forces such as waves, currents, typhoons, and red tides.

Hereinafter, with reference to FIGS. 1 and 2, the cage farm 1 will be described in detail.

1 is a perspective view illustrating a cage farm according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view of the cage farm of FIG. 1 cut in the longitudinal direction.

The cage farm 1 according to the present invention includes a cage structure 100 and a control tower 200, and the cage structure 100 includes a lower structure 110, an upper structure 120, and a first connecting chain ( 130), and a mesh 140.

The lower structure 110 is a cylindrical member having a space formed therein, and a buoyancy tank for controlling buoyancy by flowing in and out of seawater may be installed. At this time, the buoyancy tank is formed separately from the substructure 110 or may be installed inside the substructure 110 or integrally formed with the substructure 110, and a pump for introducing and discharging seawater therein may be installed. On the drawing, the lower structure 110 is illustrated as being formed in an octagonal shape, but is not limited thereto, and the shape of the lower structure 110 may be variously modified. The upper structure 120 is located above the lower structure 110.

The upper structure 120 is a frame-shaped member composed of a plurality of buoyancy members, spaced apart from the lower structure 110 and positioned on the lower structure 110. The superstructure 120 floats on the sea level by keeping the buoyancy constant, and the distance between the superstructure 120 and the substructure 110 can be adjusted by the buoyancy of the substructure 110. For example, when seawater flows into the lower structure 110 and the buoyancy decreases, the gap between the upper structure 120 and the lower structure 110 may be widened. Conversely, when seawater is discharged outside the substructure 110 to increase buoyancy, the gap between the superstructure 120 and the substructure 110 may be narrowed. The superstructure 120 may have a planar shape that is the same as the planar shape of the substructure 110. As shown, when the substructure 110 is an octagonal cylinder shape, the superstructure 120 is an octagonal frame. It can be formed into a shape. The upper structure 120 may include a guide tube 121, a support frame 122, and a connection frame 123.

The guide tube 121 is a hollow tube into which the column portion 220 of the control tower 200 to be described later is inserted, and may be disposed at the center of the superstructure 120. The guide tube 121 is disposed in a direction perpendicular to the sea level, and a support frame 122 is disposed outside. The support frame 122 is formed of a plurality of buoyancy members to form the outer shape of the upper structure 120, and the lower structure 110 and the planar shape may be identically formed. The support frame 122 surrounds the outer circumferential surface of the guide tube 121 and may be connected to the guide tube 121 by at least one connecting frame 123. The connecting frame 123 connects between the guide tube 121 and the support frame 122, one end being fixed to the outer circumferential surface of the guide tube 121 and the other end being fixed to the inner surface of the support frame 122. In the drawing, four connection frames 123 are illustrated as connecting between the guide pipe 121 and the support frame 122, but the present invention is not limited thereto, and the number of connection frames 123 may be adjusted as necessary. . The upper structure 120 is connected to the lower structure 110 by a plurality of first connection chains 130.

The first connecting chain 130 connects between the lower structure 110 and the upper structure 120, and may be formed of a chain, rope, wire, or the like. The first connection chain 130 has one end fixed to the upper side of the lower structure 110 and the other end fixed to the upper structure 120, particularly, the lower side of the support frame 122, the upper structure 120 and the lower Tension may be adjusted according to the gap between the structures 110. For example, when the space between the upper structure 120 and the lower structure 110 is widened due to a decrease in the buoyancy of the lower structure 110, the first connection chain 130 may be stretched and the tension may increase. Conversely, when the space between the upper structure 120 and the lower structure 110 is narrowed due to an increase in the buoyancy of the lower structure 110, the first connection chain 130 may be loosely stretched to reduce tension. A plurality of such first connection chains 130 may be installed at regular intervals along the outer lines of the lower structure 110 and the upper structure 120. A plurality of first connection chains 130 are spaced apart and installed along the outer lines of the lower structure 110 and the upper structure 120, so that one side spacing and the other side between the lower structure 110 and the upper structure 120. The gap can always be kept constant. The mesh 140 is disposed outside the first connection chain 130.

Mesh 140 is to form a space between the lower structure 110 and the upper structure 120 to form a cultured space, and it is a common mesh (net) that repeatedly entangles strings, wires, or wires to make holes in several noses. Can be. That is, the lower structure 110 forms the bottom surface of the aquaculture space, and the upper structure 120 forms the ceiling surface of the aquaculture space. One side of the mesh 140 is coupled to the upper side of the lower structure 110, the other side is coupled to the upper side of the upper structure 120, and the tension can be adjusted as in the first connecting chain 130. For example, when the first connection chain 130 is pulled taut and the tension is increased, the mesh 140 may also be taut and the tension may be increased. Conversely, when the first connection chain 130 is loosely stretched and the tension is reduced, the mesh 140 may also be loosely stretched to decrease the tension. That is, in the cage structure 100 of the present invention, the size of the aquaculture space formed by the mesh 140 may be adjusted according to the separation distance between the upper structure 120 and the lower structure 110.

Meanwhile, a control tower 200 may be coupled to the edge structure 100. The control tower 200 is a structure provided with a control system that can control a buoyancy tank and monitor fish farmed, a residence space where a manager can stay, and a storage space where feed to be supplied to fish is stored. Can be exposed. By combining the control tower 200 with the cage structure 100, the manager can stay and continuously monitor the fish, and the supply of feed can be smoothly performed, so that the management of the fish is easy. The control tower 200 is detachably coupled to the cage structure 100 and has its own buoyancy, so that it can independently float above sea level. Since the control tower 200 and the cage structure 100 are detachably combined with each other, only the cage structure 100 can be lowered into the deep sea in case of bad weather such as typhoon, effectively preventing fish death and damage to facilities. . The control tower 200 includes a residence 210 and a column unit 220.

The residence 210 is a structure provided with the above-described control system, residence space, storage space, and the like, and is exposed above the sea level. On the drawing, the residence 210 is shown as being formed in a hexahedron shape, but is not limited thereto, and the shape of the residence 210 may be variously modified. The column 220 is coupled to the lower portion of the residence 210. The column unit 220 is a pillar-shaped structure that supports the residence 210, and has buoyancy, so that at least a portion thereof may be located in the water. The column unit 220 may be exposed to the lower portion of the lower structure 110 through the center of the edge structure 100 through the upper structure 120 and coupled to the edge structure 100. As illustrated, the column portion 220 is formed in an inverted cone shape with a lower end portion so that it can be easily inserted and penetrated into the guide tube 121 of the upper structure 120. The second connection chain 230 is coupled to the lower portion of the column 220.

The second connection chain 230 penetrates the cage structure 100 and connects between the column unit 220 and the substructure 110, and may be formed of a chain, rope, wire, or the like. The second connection chain 230 is fixed to the lower end of the column part 220, the other end is fixed to the lower surface of the lower structure 110, and the length is sufficiently extended to form a cage structure 100 located in the water and The control tower 200 located at the sea level can be connected in a spaced state. In other words, the cage structure 100 and the control tower 200 are separated from each other, and the cage structure 100 is located in the water and the control tower 200 is located at sea level, while the second connecting chain 230 is the cage structure ( 100) and the control tower 200. For example, when the cage structure 100 and the control tower 200 are coupled to each other, the second connection chain 230 is stretched under the lower structure 110, the column 220 and the lower structure 110 ). On the contrary, when the cage structure 100 and the control tower 200 are separated from each other, the second connecting chain 230 is pulled upward with one end connected to the column part 220 to penetrate the cage structure 100. The column unit 220 and the lower structure 110 may be connected. By connecting the second connection chain 230 between the column unit 220 and the lower structure 110, the cage structure 100 is lost or the control tower 200 is completely separated from the cage structure 100 Can be prevented.

Hereinafter, the operation of the cage farm 1 will be described in more detail with reference to FIG. 3.

3 is an operation diagram for explaining the operation of the cage farm.

The cage farm 1 according to the present invention can adjust the buoyancy of the lower structure 110 to control the distance between the lower structure 110 and the upper structure 120. Therefore, the size of the aquaculture space can be freely varied, and the entire volume can be adjusted to facilitate traction. In addition, it is easy to manage the fish because the control tower 200 is provided for the manager to stay, and the control tower 200 can be separated from the cage structure 100 to be applied to external forces such as waves, currents, typhoons, and red tides. You can cope effectively.

When moving the cage farm 1, as shown in Figure 3 (a), it is possible to reduce the overall volume of the cage structure (100). When the seawater stored inside the substructure 110 is discharged to the outside, the buoyancy of the substructure 110 increases, and the gap between the superstructure 120 and the substructure 110 is narrowed. At this time, the first connection The chain 130 and the mesh 140 may be loosely stretched. When the gap between the upper structure 120 and the lower structure 110 is narrow, the entire volume of the cage structure 100 decreases and is located near the sea level, so that the cage farm 1 can be easily moved by the tow line. It can be done.

When operating the cage farm 1, as shown in FIG. 3(b), the size of the farm can be increased. When an appropriate amount of seawater is introduced into the substructure 110, the buoyancy of the substructure 110 decreases, thereby widening the gap between the substructure 110 and the superstructure 120 floating on the sea level. The first connection chain 130 and the mesh 140 may be pulled taut. When the distance between the upper structure 120 and the lower structure 110 is widened, the size of the aquaculture space is also widened to accommodate a large amount of fish.

When a wave occurs due to bad weather such as a typhoon or when a red tide occurs, as shown in FIG. 3(c), the control tower 200 and the cage structure 100 may be separated. When the maximum amount of seawater is introduced into the substructure 110, the buoyancy of the substructure 110 is further reduced, thereby increasing the gap between the substructure 110 and the superstructure 120, and at the same time, the superstructure 120 and The lower structure 110 may be separated from the column unit 220 and descend to the deep sea. At this time, the second connecting chain 230 connecting between the column unit 220 and the lower structure 110 may be disposed in a state that is pulled upward and penetrates the cage structure 100. When the upper structure 120 and the lower structure 110 descend to the deep sea, even if typhoons, waves, red tides, and ocean currents occur, it is possible to prevent the death of fish and damage to facilities.

Hereinafter, a cage farm 1 according to another embodiment of the present invention will be described in detail with reference to FIG. 4.

4 is a cross-sectional view showing a cage farm according to another embodiment of the present invention.

The cage farm 1 according to another embodiment of the present invention further includes a winch part 221 to wind or unwind the second connection chain 230. The cage farm 1 according to another embodiment of the present invention is substantially the same as the above-described embodiment, except that it further includes a winch portion 221 to wind or unwind the second connection chain 230. Therefore, this will be mainly described, unless otherwise stated, the description of the remaining components will be replaced by the above.

The column unit 220 may have a winch unit 221 installed therein. The winch part 221 is to adjust the length by winding or loosening the second connection chain 230, and may be installed close to the lower end of the column part 220. That is, one end of the second connection chain 230 is wound around the winch part 221, and the other end penetrates the column part 220 and is coupled to the lower structure 110. By installing a winch 221 to wind or unwind the second connecting chain 230 inside the column 220, the length of the second connecting chain 230, and between the control tower 200 and the cage structure 100 It is possible to easily adjust the interval of the, thereby, when the typhoon, waves, red tide, currents, etc., the cage structure 100 can only be lowered to an appropriate depth.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, a person skilled in the art to which the present invention pertains may be implemented in other specific forms without changing the technical concept or essential features of the present invention. You will understand. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

1: Street farm
100: Street structure 110: Substructure
120: superstructure 121: guide tube
122: support frame 123: connecting frame
130: first connection chain 140: mesh
200: control tower 210: residence
220: column section 221: winch section
230: second connection chain

Claims (5)

A substructure having a buoyancy tank that controls buoyancy by flowing in and out of seawater,
An upper structure spaced apart from the lower structure and positioned above the lower structure;
A plurality of first connection chains connecting the substructure and the superstructure, and
A cage structure including a mesh forming a culture space by blocking between the lower structure and the upper structure, and
A cage farm that is coupled to the cage structure to control the buoyancy tank, and includes a control tower exposed above the sea level. According to claim 1,
The control tower and the cage structure are detachably coupled to each other,
The control tower has buoyancy, so it is possible to independently float above sea level. According to claim 2, The control tower,
Habitats exposed above sea level,
A cage farm having a buoyancy, and at least a part of which is located in the water, and includes a column portion that supports the residence but penetrates the superstructure and is coupled to the cage structure. According to claim 3,
Further comprising a second connecting chain penetrating through the center of the rim structure to connect between the column portion and the sub-structure,
The second connecting chain is a cage farm that connects the cage structure located in the water and the control tower located at the sea level in a spaced state. According to claim 4,
The column part is a cage farm that penetrates through the center of the cage structure and is exposed to the bottom of the substructure.

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