KR20190060318A - Floating Fish Cage using Geodesic Dome Structure - Google Patents

Abstract

The present invention relates to a cage culture apparatus using a geodesic dome structure, in which a triangular frame of a culture member is formed in the shape of a sphere by applying the geodesic dome structure, and each triangular frame is blocked by a triangular plane, thereby having an effect that the creatures inside the triangular frame can not escape to the outside arbitrarily.

Description

Technical Field [0001] The present invention relates to a floating fish cage using a geodesic dome structure,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cage aquaculture apparatus using a geodesic dome structure, and more particularly, to a cage aquarium system using a geodesic dome structure, The present invention relates to a cage aquaculture apparatus using a dome structure.

Generally, a marine cage farm establishes a cage net on the sea, and it is a facility where various kinds of fish are confined in the sea. These cage farms have the advantage that the water in the cage is not deteriorated because the water inside and outside the cage freely passes through the space between the cage nets. Therefore, a large amount of fish can be raised in a small facility, which is very economical in terms of facilities.

In recent years, marine cage farms have become a landmark alternative to the fisheries aquaculture sector, which solves the problems of environmental problems and lack of aquacultural space through the installation of facilities in offshore areas, There is a growing interest in foreign-style fishing. In the case of these offshore cultures, it is known that large-scale fish species such as flounder, defense, and domes, as well as high value-added economic species such as tuna, can be cultured.

On the other hand, since the marine cage farm is installed in the ocean, when the marine is directly influenced by the typhoon, there is a situation where fish nets are broken due to high waves and strong winds, As in winter, when the temperature of seawater changes dramatically, aquaculture occurs in some cases. To prepare for this, if a typhoon occurs or the temperature of the seawater changes significantly, the cage net should sink down to a safe water depth and then raised to raise the cage net again. For this purpose, the existing cage farm uses a motor to raise or lower the cage net, which requires the use of a plurality of large motors, which is costly.

Since the upper and lower portions of the cage net are open, external foreign matter, nemesis, and the like can be introduced into the cage net through the open top or bottom of the cage net, and the fish trapped in the cage net can escape to the outside There is also a problem.

Korean Patent Registration No. 10-1701400 Korean Patent Registration No. 10-1673203

SUMMARY OF THE INVENTION It is an object of the present invention to provide a cage aquarium apparatus using a geodesic dome structure for easily raising or lowering an aquaculture product for culturing sea creatures.

It is another object of the present invention to provide a cage aquarium using a geodesic dome structure that prevents foreign matter from flowing into a culture medium and prevents organisms inside the culture medium from escaping arbitrarily.

In order to attain the above object, the present invention provides a cage aquaculture apparatus provided in a cage farm, comprising: a plurality of triangular frames connected to each other by a geodesic dome structure to form a sphere; And a plurality of triangular planes formed in the cage forming apparatus.

In addition, among the plurality of triangles arranged to face the selected virtual vertex among the plurality of triangles, the ends of the sides facing the vertex are spaced apart from each other, Wherein a through hole is formed at an end of the sides facing the direction of the engaging portion and a protrusion is formed at a position facing the through hole of the engaging portion so that the through hole is engaged with the engaging portion, Wherein the projections and the inner circumferences of the through holes are formed in a circular shape and the sides are rotatable in a state of being coupled to the fitting projections.

The apparatus of claim 1, further comprising a fixing member for fixing the triangular surface to the triangular frame, wherein the triangular frame is composed of three sides, the triangular surface has three sides facing three sides, The member includes a circular engagement ring formed in the side portion; And a locking part formed in a ring shape so as to engage with the coupling ring on the side facing the coupling ring. The cage forming device using the geodesic dome structure according to claim 1,

Further, the present invention provides a cage aquarium using a geodesic dome structure, wherein an opening / closing part is mounted on one of the plurality of triangular frames so as to be openable and closable.

A fluid pocket connected to the triangular frame and having a hollow space therein; A buoyant portion formed to float in water; Air supply means mounted on one side of the buoyant portion; A water supply means mounted on the other side of the buoyant portion; An air supply line connecting one side of the air supply means and the fluid pocket; And a water supply line connecting the water supply means and the other side of the fluid pocket, wherein when the air supply means supplies air to the fluid pocket through the air supply line, the frame member is raised in the sea surface direction And when the water supply means supplies water to the fluid pockets through the water supply line, the frame member is lowered below the sea level.

A plurality of fluid pockets are mounted along the outer periphery of the triangular frame formed in a spherical shape. When the air is supplied to the selected fluid pockets among the plurality of fluid pockets, the fluid pockets are raised and the triangular frame is rotated And when the water is supplied to the selected fluid pockets among the plurality of fluid pockets, the fluid pockets are lowered to rotate the triangular frame, thereby providing a cage aquarium.

It is further contemplated that the apparatus further comprises a fluid discharge valve mounted in the fluid pocket for selectively exiting the existing fluid contained within the fluid pocket, wherein the air supply means supplies air to the fluid pocket through the air supply line, Wherein when the water supply means supplies water to the fluid pockets through the water supply line, the fluid discharge valve is opened and the existing fluid accommodated in the fluid pockets is discharged to the outside. To provide a cage aquaculture device.

Since the buoyant force of the fluid pocket can be adjusted by supplying seawater or air into the fluid pocket, it is possible to easily raise or lower the position of the aquarium according to the marine conditions such as typhoon and temperature.

In addition, the triangular frame of aquaculture member is formed into a spherical shape by applying a geodesic dome structure, and each triangular frame is blocked by a triangular surface, so that the organism inside the triangular frame can not escape arbitrarily outside.

In addition, since the sides of the triangular frame are rotatably coupled to the coupling portion, even if a strong external force is applied to the triangular frame due to waves or the like, the sides of the triangular frame are rotated slightly while being supported by the coupling portion, So that it is possible to firmly support the light emitting diode.

In addition, since the triangular frame is configured to be openable and closable by the opening and closing part, various kinds of equipment or living creatures can be easily inserted into or pulled out from the inside of the triangular frame.

Further, there is an effect that the triangular face and the triangular frame are securely fixed to each other by using the fixing member having a simple structure having the coupling ring and the engaging portion.

In addition, there is an effect that, when air is injected into one selected fluid pocket among a plurality of fluid pockets and water is injected into another fluid pocket, the form member can be easily rotated.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view for explaining a configuration of a cage aquaculture apparatus using a geodesic dome structure according to a preferred embodiment of the present invention. FIG.
FIG. 2 and FIG. 3 are views for explaining a coupling part to be coupled to a triangular frame of a cage aquarium using a geodesic dome structure according to a preferred embodiment of the present invention.
4 is a view illustrating an opening / closing part of a cage aquarium using a geodesic dome structure according to a preferred embodiment of the present invention.
5 is a view illustrating a fixing member of a cage aquarium using a geodesic dome structure according to a preferred embodiment of the present invention.
6 is a view for explaining a state in which a plurality of form members of a cage aquarium apparatus using a geodesic dome structure according to a preferred embodiment of the present invention are interconnected.
7 is a view for explaining the upper and lower movable members of the cage aquarium apparatus using the geodesic dome structure according to the preferred embodiment of the present invention.
FIG. 8 is a schematic view for explaining a process of rotating a culturing member of a cage aquarium using a geodesic dome structure according to a preferred embodiment of the present invention.

Hereinafter, a cage aquarium using a geodesic dome structure according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view for explaining a configuration of a cage aquaculture apparatus using a geodesic dome structure according to a preferred embodiment of the present invention. FIG.

Referring to FIG. 1, a cage aquarium system 10 (FIG. 7) using a geodesic dome structure according to a preferred embodiment of the present invention is applied to a cage farm for culturing sea creatures such as fishes, 100) and a shoe easel (200: Fig. 7). The fishing equipment 100 is installed, for example, at an outer sea of the sea, and a space for culturing the fish is formed therein. The forming member 100 includes a plurality of triangular frames 110 connected to each other in a geodesic dome structure and a plurality of triangular frames 110 formed to cover the respective triangular frames 110, Surface 120. The surface 120 of FIG.

Here, the geodetic dome structure is known to have been first built by Walther Bauersfeld in 1922, and later by Buckminster Fuller, the methodology and theories have been elaborated in detail to form the official term geodetic dome. These geodesic domes are made by dividing the corners of a regular twentieth side by n. At this time, five triangles are gathered at the vertex (P) of the right twentieth face, but six triangles are gathered at the newly created vertex (P).

The triangular frame 110 of the present invention is formed in a spherical shape by applying the geodesic dome structure. Since the geodesic dome structure is conventional, a detailed description of the geodesic dome structure will be omitted. The space inside the triangular frame 110 is configured to cultivate various living things. The triangular surface 120 is formed in a triangular shape so as to cover each triangular frame 110. The triangular surface 120 is formed in a net or mesh structure so that the organisms inside the triangular frame 110 are prevented from escaping to the outside while a clean current including oxygen is introduced into the triangular frame 110, So that various kinds of debris in the mold 110 can be discharged quickly.

Since the triangular frame 110 is formed in a spherical shape by applying the geometric dome structure and each triangular frame 110 is cut off by the triangular surface 120, ) There is an effect that an inside creature can not escape to outside arbitrarily.

Also, Geodetic  And formed into a dome structure The triangular frame 110  Therefore, it is possible to reduce the number of The buoyancy portion (shown in Fig. 7) Towing is possible by using . As a result, the amount of wastes due to repeated food feeds and added fish species is above a certain level If To other places without waste The triangular frame 110  It is possible to move the position, and it is possible to actively cope with marine pollution.

FIG. 2 and FIG. 3 are views for explaining a coupling part to be coupled to a triangular frame of a cage aquarium using a geodesic dome structure according to a preferred embodiment of the present invention.

Referring to FIGS. 1 to 3, for example, in the case of six triangular frames 110 arranged to face a virtual vertex P among a plurality of triangular frames 110, a pair of triangular frames 110, (110) jointly use one side (112) disposed between them. As a result, the sides 112 facing the vertex P are composed of six. The ends P of the side edges 112 may be integrally connected with each other or may be spaced apart from each other. When the corner P and the ends of the opposite sides 112 are separated from each other, a plate-like engaging portion 115 is provided at the vertex P. A through hole 112a is formed at an end of the side 112 facing toward the coupling part 115 and the through hole 112a is formed at a position opposite to the through hole 112a on one side of the coupling part 115 Six fitting protrusions 115a are formed to fit together. The inner periphery of the fitting projection 115a and the through hole 112a is formed in a circular shape so that the sides 112 are configured to be rotatable in a state of being coupled to the fitting projection 115a. Since the sides 112 are rotatably coupled to the engaging portions 115 so that even when a strong external force is applied to the triangular frame 110 by waves or the like, It is possible to firmly support the pressure of the wave while being slightly rotated in the state of being supported by the support shaft 115.

4 is a view illustrating an opening / closing part of a cage aquarium using a geodesic dome structure according to a preferred embodiment of the present invention.

Referring to FIG. 4, the opening / closing part 140 is mounted on a selected one of the plurality of triangular frames 110. The opening and closing part 140 includes an opening and closing frame 142 formed in a triangular shape along the inner peripheral surface of the triangular frame 110 and an opening and closing face 144 covering the opening and closing frame 142. The opening / closing surface 144 is formed in the shape of a net or a mesh like the triangular surface 120. One side of the opening and closing frame 142 is hinged by the triangular frame 110 and the hinge part 146 so that the opening and closing part 140 opens and closes the triangular frame 110. Since the triangular frame 110 is configured to be openable and closable by the opening and closing part 140, various kinds of equipment or living creatures can be easily inserted into or removed from the inside of the triangular frame 110.

5 is a view illustrating a fixing member of a cage aquarium using a geodesic dome structure according to a preferred embodiment of the present invention.

Referring to FIG. 5, the triangular surface 120 and the triangular frame 110 may be configured to be fixed to each other by a fixing member 130. Here, since the triangular frame 110 is composed of three sides 112, the triangular side 120 has three sides facing the three sides 112. The fixing member 130 includes a coupling ring 132 formed on each side of the triangular surface 120 and a locking portion 134 formed on a side 112 of the triangular frame 110 opposed to the coupling ring 132, . The engaging ring 132 is formed in a circular shape and the engaging portion 134 is formed in an annular shape so that when the engaging ring 132 is engaged with the engaging portion 134 when the triangular face 120 is engaged with the triangular frame 110, As shown in Fig. As described above, the present invention has the effect of firmly fixing the triangular surface 120 and the triangular frame 110 using the fixing member 130 having a simple structure having the coupling ring 132 and the locking portion 134.

Figure 6 is a graph of the In the embodiment  Following Geodetic  A plurality of cage aquariums using a dome structure The absence of culture  Lt; RTI ID = 0.0 > interconnected < / RTI >

Referring to FIG. 6, Geodetic  And formed into a dome structure The triangular frame 110  Regardless of the size, it is formed in the same dome structure, The forming member 100  They can be linked together in a cluster format. In other words, The forming member 100  A plurality of, for example, two, are arranged side by side, [0030]  Facing each other The triangular frame 110  By using the connecting portion 150, Connect . At this time, In the triangular frame 110, draw (140: Figure 4) and The triangular surface 120  It is not mounted. The connection portion 150 may include a plurality of triangles The frame 110 To connect.  Of course, be formed.

As described above, The forming member 100  They can be arranged in a cluster format, and they can be connected to each other by using the connection unit 150, so that there is an effect that they can be operated flexibly according to the culture environment.

7 is a view for explaining the upper and lower movable members of the cage aquarium apparatus using the geodesic dome structure according to the preferred embodiment of the present invention.

Referring to FIG. 7, the upper and lower movable members 200 move up and down the forming member 100 located below the sea surface. The upper and lower movable members 200 and 300 are disposed in the fluid pocket 210, the buoyant portion 220, the air supply means 230, Means 240, an air supply line 250 and a water supply line 260.

The fluid pockets 210 are integrally connected to one or a plurality of the triangular frames 110, and an independent void space is formed therein. One or more fluid pockets 210 may be coupled to the triangular frame 110, depending on the size of the forming member 100. The fluid pockets 210 may be formed of a cloth material that can not escape to the outside due to air or water flowing into the fluid pockets 210. A drain hole 210c is formed in an upper portion or a lower portion of the fluid pocket 210 so that an existing fluid accommodated in the fluid pocket 210 is discharged and a fluid discharge valve 216 to be described later is mounted on the drain hole 210c .

The buoyant portion 220 is formed so as to float in water, and may be constituted by, for example, a barge, a boat, or the like. The buoyant portion 220 may be configured to float on the sea surface while being positioned adjacent to the aquarium member 100.

The air supply means 230 is mounted on one side of the buoyancy portion 220 and is composed of, for example, a compressor capable of injecting air. The water supply means 240 includes a water supply portion 242 such as a pump mounted on the other side of the buoyancy portion 220 and a water connection pipe 242 connected to the water supply portion 242 on one side and to be submerged in the downward direction 244). Meanwhile, in one embodiment of the present invention, the water connection tube 244 is positioned below the sea surface and is configured to supply seawater to the water supply 242, but it should be understood that the invention is not limited thereto, The buoyant portion 220 may be provided with a water tank (not shown), and the water connection pipe 244 may be locked to the water tank. The water tank may contain seawater or may contain water having a specific gravity larger than sea water.

The air supply line 250 is composed of a tube that interconnects the air supply means 230 and one side of the fluid pocket 210. An air supply hole 210a is formed at one side of the fluid pocket 210 and an air supply line 250 is connected to the air supply hole 210a. The water supply line 260 is constituted by a pipe connecting the water supply part 242 and the other side of the fluid pocket 210 with each other. A water supply hole 210b is formed on the other side of the fluid pocket 210 and a water supply line 260 is connected to the water supply hole 210b. The air supply hole 210a is provided with an air supply valve 212 for selectively opening and closing the air supply hole 210a and a water supply hole 210b is provided with a water supply hole 210b for selectively opening and closing the water supply hole 210b. A valve 214 is mounted and a drain valve 210c is mounted with a fluid drain valve 216 to selectively open and close the drain hole 210c.

The air supply valve 212 is opened, the water supply valve 214 is closed, and the fluid discharge valve 216 is opened. In this state, when the air supply means 230 supplies air to the fluid pockets 210 through the air supply line 250, air is supplied to the fluid pockets 210 and at the same time, 210 in the direction of the sea surface. At this time, the existing fluid contained in the fluid pocket 210 through the fluid discharge valve 216 is discharged, for example, seawater. When the aquarium member 100 is raised to a predetermined height, air supply to the fluid pockets 210 is blocked, and the air supply valve 212 and the fluid discharge valve 216 are closed.

Conversely, in order to lower the forming member 100, first, the air supply valve 212 is closed, the water supply valve 214 is opened, and the fluid discharge valve 216 is opened. In this state, when the water supply section 242 is operated, seawater sucked through the water connection pipe 244 is supplied to the fluid pocket 210 through the water supply line 260. Then, the seawater is supplied to the fluid pocket 210. At this time, an existing fluid contained in the fluid pocket 210 is discharged to the outside through the fluid discharge valve 216 due to the pressure of the seawater supplied to the fluid pocket 210. Then, the fluid pocket 210 gradually sinks as buoyancy is reduced. When the aquarium member 100 is lowered to a predetermined height, the supply of seawater to the fluid pockets 210 is blocked, and the water supply valve 214 and the fluid discharge valve 216 are closed.

As described above, since the buoyancy of the fluid pockets 210 can be controlled by supplying seawater or air to the fluid pockets 210, Marine due Condition According to the seasons, The triangular frame 110  The position can be easily raised or lowered. In addition, when the marine pollution such as red tide is used, The triangular frame 110  So that it can actively cope with marine pollution.

FIG. 8 is a schematic view for explaining a process of rotating a culturing member of a cage aquarium using a geodesic dome structure according to a preferred embodiment of the present invention.

7 and 8, a plurality of, for example, four fluid pockets 210 are mounted counterclockwise along the outer periphery of a triangular frame 110 formed in a spherical shape, 210A, a second fluid pocket 210B, a third fluid pocket 210C and a fourth fluid pocket 210D. For example, air is supplied to the first fluid pocket 210A and the fourth fluid pocket 210D, and water is supplied to the second fluid pocket 210B and the third fluid pocket 210C, The pocket 210A and the fourth fluid pocket 210D are configured to partially float above the sea level.

In this state, if it is desired to repair the triangular frame 110 or the triangular surface 120 around the third fluid pocket 210C which is locked below the sea level, air is injected into the third fluid pocket 210C, Water is injected into the first fluid pocket 210A. The third fluid pocket 210C then floats above the sea surface and the first fluid pocket 210A sinks below the sea level and at the same time the triangular frame 110 is rotated counterclockwise to the third fluid pocket The triangular frame 110 located in the vicinity of the sea surface 210C floats above the sea surface.

As described above, when air is injected into one selected fluid pocket 210 of the plurality of fluid pockets 210 and water is injected into the other fluid pocket 210, the form member 100 can be easily rotated There is an effect to be.

Also, [0030]  During maintenance and repair, ensure that damaged areas are exposed above sea level. The forming member 100  So that it is possible to perform maintenance in a safe and convenient environment.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined in the appended claims. It should be understood that the technical idea belonging to the scope of the claims also belongs to the present invention.

10: Cage aquaculture device using geodesic dome structure
100: aquaculture member 110: triangular frame
112: side 112a: through hole
115: engaging portion 115a:
120: triangular face 130: fixing member
132: coupling ring 134:
140: opening and closing part 142: opening and closing frame
144: opening / closing surface 146:
200: Shanghai easel 210: Fluid pocket
210a: air supply hole 210b: water supply hole
210c: drain hole 212: air supply valve
214: water supply valve 216: fluid discharge valve
220: Buoyant portion 230: Air supply means
240: water supply means 242: water supply portion
244: Water connector 250: Air supply line
260: Water supply line P: Corner

Claims (7)

A cage aquaculture apparatus provided in a cage farm,
A plurality of triangular frames formed in a spherical shape connected with a geodesic dome structure and a plurality of triangular frames formed in a net shape so as to cover the respective triangular frames, Cage aquaculture device using geodesic dome structure.
The method according to claim 1,
A plurality of triangles arranged to face a selected virtual vertex among the plurality of triangles are disposed such that the ends of the sides facing the vertex are spaced apart from each other, Respectively,
A through hole is formed in an end portion of the sides facing the direction of the coupling portion, a fitting protrusion is formed at a position facing the through hole of the coupling portion to fit the through hole,
Wherein the fitting protrusions and the inner circumference of the through holes are formed in a circular shape so that the sides are rotatable in a state of being coupled to the fitting protrusions.
The method according to claim 1,
And a fixing member for fixing the triangular surface to the triangular frame,
Wherein the triangular frame comprises three sides,
Wherein the triangular face has three sides facing three sides,
Wherein:
A circular engagement ring formed on the side portion; And
And a locking part formed in a ring shape so that the coupling ring is engaged with the side opposite to the coupling ring.
The method according to claim 1,
Wherein the opening / closing part is mounted on one of the plurality of triangular frames so that the triangular frame can be opened and closed.
The method according to claim 1,
A fluid pocket connected to the triangular frame and having a hollow space therein;
A buoyant portion formed to float in water;
Air supply means mounted on one side of the buoyant portion;
A water supply means mounted on the other side of the buoyant portion;
An air supply line connecting one side of the air supply means and the fluid pocket; And
Further comprising a water supply line connecting the water supply means and the other side of the fluid pocket,
When the air supply means supplies air to the fluid pockets through the air supply line, the frame member is raised in the sea level direction. When the water supply means supplies water to the fluid pockets through the water supply line, Wherein the member is lowered below the sea level.
6. The method of claim 5,
A plurality of fluid pockets are mounted along the outer circumference of the triangular frame formed in a spherical shape,
When air is supplied to the selected fluid pockets among the plurality of fluid pockets, the fluid pockets are raised to rotate the triangular frame,
Wherein when the water is supplied to the selected fluid pockets among the plurality of fluid pockets, the fluid pockets are lowered to rotate the triangular frame.
6. The method of claim 5,
Further comprising a fluid discharge valve mounted in the fluid pocket for selectively discharging an existing fluid contained within the fluid pocket,
When the air supply means supplies air to the fluid pockets through the air supply line or when the water supply means supplies water to the fluid pockets through the water supply line, And the existing fluid accommodated in the pocket is discharged to the outside.

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