KR20110090540A - Structure for fish farming cage - Google Patents

Abstract

PURPOSE: A structure for a fish farming cage is provided to absorb a part of energy by water flow and obtain structure stability. CONSTITUTION: A structure for a fish farming cage includes a plurality of floor members(10), a plurality of bonding members(20), and a plurality of floating members(30). The floor members partition a space for growing fish and configure a moving path for a worker. The floor members are vertically aligned. The bonding members connect the floor members each other to form a frame which has a fixed shape. The floating members are fixed to the lower side of the floor members. The floor members, the bonding members, and the floating members are made of fiber-reinforced plastic.

Description

Structure for Fish farming Cage

The present invention relates to a cage structure for marine fishing, and more particularly to a cage structure made of fiber-reinforced plastic material that can meet the advantages of both steel and wave-resistant cages.

The domestic fish farming business has been developed in shallow waters or shallow waters, but it is seeking to enter the offshore fishing grounds with higher water quality and higher productivity due to rapid industrialization, increased wastewater due to urbanization, and increased demand. In addition, since various conditions are required according to fish, fish species, there is a need for a floating structure for fishing excellent in structural safety.

Floating structures for marine fishing include cages and rafts, which are evolving from traditional wooden cages to steel and plastics to meet structural safety against waves, tides and wind directions.

The steel cage structure is a method to expect structural safety by increasing the rigidity and strength of the structure itself, and the plastic cage is configured to adapt to the flow of water in a shockproof form by increasing the ductility of the structure.

However, steel cages are stronger than wooden cages, but often the facilities are damaged due to fatigue due to the repeated action of waves and concentrated loads at the joints, and the durability is degraded due to corrosion by seawater.

In addition, the plastic impulse resistant cage is flexible, so that the bottom of the net is frequently moved, and sensitive to the flow of blue and flowing water, the workability by the upper workshop is significantly reduced.

The present invention relates to a cage structure that can solve the above disadvantages has the following object.

An object of the present invention is to provide a frame structure of fiber-reinforced plastic material that can meet all the advantages of steel and wave resistant cages.

According to a preferred embodiment of the present invention, a marine fishing cage structure comprises: a plurality of bottom members arranged horizontally and vertically so as to constitute a moving passage of an operator while partitioning a space for farming fish; A plurality of floats fixed to the bottom of the bottom member such that a plurality of joining members connecting the plurality of bottom members to each other to form a frame of a predetermined shape and a frame composed of the plurality of bottom members and the joining members float on the water surface; It includes, the bottom member, the joining member and the floating body is composed of a fiber reinforced composite material.

In a marine fishing cage structure according to another suitable embodiment of the present invention, the bottom member is coupled to the scaffold having a plurality of ribs protruding parallel to each other downward along the longitudinal direction, and parallel to the scaffold at regular intervals with the ribs. It has a plurality of structures.

In a marine fishing cage structure according to still another preferred embodiment of the present invention, the structure is joined at both ends in the width direction of the scaffold.

In a marine fishing cage structure according to another suitable embodiment of the present invention, the scaffold and the structure are integrally formed.

In the marine fishing cage structure according to another suitable embodiment of the present invention, the floating body has a cross-sectional shape having a semi-cylindrical portion submerged in the water surface and a stepped upper coupling portion coupled to the bottom member, the length of the upper coupling portion A coupling groove into which the ribs of the bottom member are inserted at intervals from each other along the direction is formed, and the structure of the bottom member is seated on the stepped portions formed at both ends.

In the marine fishing cage structure according to another suitable embodiment of the present invention, the fixing means for connecting the float to the bottom member through the structure, the ribs and the float while the rib of the bottom member is inserted into the coupling groove of the float It includes more.

The cage structure according to the present invention is composed of fiber-reinforced plastic, which is similar to steel in terms of strength, and its stiffness is relatively small, so that it can absorb a part of energy due to the flow of running water and is structurally strong as fatigue material. It can be expected and can be used semi-permanently as a corrosion resistant material.

In addition, it is excellent in workability and can be manufactured in various forms, and it has excellent rigidity compared to the existing impulse-proof cage structure, so it is excellent in workability by workers.

The following drawings, which are attached in the present specification, illustrate exemplary embodiments of the present invention, and together with the detailed description of the present invention, serve to further understand the technical spirit of the present invention. It should not be construed as limited.
1 is a perspective view showing a cage structure for marine fishing according to the present invention.
FIG. 2 is a detailed view of the portion indicated by A in FIG. 1, (A) shows the top down obliquely from the top, and (B) shows the top view obliquely from the bottom up.
3 is a perspective view of the floating body.

In the following the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the embodiments presented are exemplary for a clear understanding of the present invention is not limited thereto.

1 is a perspective view showing a cage structure for marine fishing according to the present invention.

Referring to FIG. 1, the marine fishing cage structure divides a space for farming fish and divides a plurality of bottom members 10 and a plurality of bottom members 10 arranged horizontally and vertically to form a moving passage of an operator. A plurality of joining members 20 and a frame composed of a plurality of bottom members 10 and a joining member 20 to float on the surface of the bottom member 10 to connect the bottom member 10 to form a predetermined shape of the bottom member 10 It includes a plurality of floats 30 fixed to the bottom.

The bottom member 10 is a length member configured to have a greater length than the width, and may be made of any material known in the art, and the plurality of bottom members 10 may be horizontally and vertically arranged to be parallel to each other at regular intervals. Can be deployed. The installation interval or the number of the bottom members 10 may be appropriately selected depending on the area of the cage farm, but is not particularly limited. The width of the bottom member 10 may have any size that allows human walking and the length may be appropriately selected in consideration of the area of the cage farm, but is not particularly limited.

The joining member 20 is installed at a point where the floor members 20 arranged horizontally and vertically cross each other to connect the bottom members 20 to each other to have a predetermined shape, and any material known in the art. It may be made and may have, for example, a plate shape, but is not limited thereto. The joint between the joining member 20 and the bottom member 10 may be joined to one another according to methods known in the art, such as bolts or welding, and a reinforcing member may be used as necessary.

As such, the bottom member 10 connected to each other by the joining members 20 and partitioning the cage space having a predetermined area on the surface of the water may maintain the floating state on the surface of the water by the floating body 30.

The float 30 can have any shape and can be fixed to the bottom of the bottom member 10. The size of the float 30 having any shape may be determined in consideration of the weight of the entire bottom member 10. The size of the floating body 30 may be determined such that at least a portion of the bottom member 10 is positioned on the water surface in consideration of the load received by each floating body 30 installed. The interior of the floating body 30 may be filled with a material such as, for example, styrofoam, but may be made into an empty space, and the floating body 30 may be made of a material known in the art, such as a synthetic resin, an alloy, or a nonferrous metal. If necessary, a coating may be performed to prevent corrosion on the surface. Floating body 30 may be installed at regular intervals along the longitudinal direction of the bottom member 10 and at least three floating body 30 may be installed to float the bottom member 10, but the installation direction and number Is not particularly limited.

Hereinafter, each component will be described in detail.

FIG. 2 is a detailed view of the portion indicated by A in FIG. 1, (a) shows an obliquely downward view from above, and (b) shows an obliquely upward upward view from below, FIG. 3 is a perspective view showing a floating body.

Referring to (a) of Figure 2, the bottom member 10 is parallel to the footrest 11 and ribs 111 having two ribs 111 protruding in parallel with each other downward along the longitudinal direction at regular intervals. It consists of two structures 12 are coupled to the scaffold (11). The structure 12 may be located between the ribs 111 but is coupled to be positioned at both ends in the width direction of the scaffold 11 in consideration of the convenience of coupling with the floating body 30. The structure 12 may be configured as a box-shaped cross section, but is not limited thereto, and may have any cross-sectional shape having a hollow therein to reduce the weight and have a required strength. The spacing or number of installations of the ribs 111 and the structure 12 may be appropriately selected to reinforce the scaffold 11 and to reinforce the strength and rigidity of the bottom member 10, but is not particularly limited. The structures 12 may be coupled to each other by bolts or by various connection methods known in the art. Alternatively, the scaffold 11 and the structure 12 may be integrally constructed. In this case, the bottom member 10 may have a cross-section in which the structure 12 and the ribs 111 are formed to be parallel to each other at a distance from each other. On the upper surface of the footrest 11, anti-slip irregularities may be formed on the surface as necessary.

And the joining member 20 is disposed above the bottom member 10 orthogonal to each other, and the joining member 20 and the bottom member 10 can be penetrated by bolts to be firmly bonded to each other.

As shown in FIG. 3, the floating body 30 has a cross-sectional shape having a semicircular column portion 31 submerged in the water surface and a stepped upper coupling portion 32 coupled to the bottom member 10. Coupling grooves 321 are formed on the upper surface of the upper coupling portion 32 and the ribs 111 of the bottom member 10 are inserted at intervals along the length direction, and the bottom member 10 is formed on the stepped portions 322 formed at both ends thereof. ) Structure 12 is seated.

Referring to Figure 2 (b), the floating body 30 is fixed to the bottom of the bottom member 10 at intervals from each other, the rib of the bottom member 10 in the coupling groove 321 of the floating body 30. The floating body 30 can be fixed to the bottom member 10 by penetrating the structure 12, the ribs 111, and the floating body 30 through the fixing means 40 in the state where the 111 is inserted. The fastening means 40 is not particularly limited as long as it has a length that can penetrate the structure 12, the ribs 111, and the floating body 30, but is made of a fiber reinforced composite material to prevent corrosion by salt damage. It is preferable that it is shaped.

On the other hand, in the present invention, the bottom member 10, the joining member 20 and the floating body 30 can ensure a superior material performance compared to the steel material, it is very excellent in corrosion environments such as salt and harmful environment It is preferable to construct a fiber reinforced composite material (FRP) that can be used semi-permanently. Fiber-reinforced composite consists of resin and reinforcing fiber, and resin is used to transfer stress (load) between reinforcing fibers, to prevent buckling of reinforcing fibers, to protect reinforcing fibers from harmful environments, to protect reinforcing fibers from mechanical wear, and to interlaminar shear Epoxy, polyester, vinyl esters, phenol and the like may be used as it serves as a resistance. Reinforcing fibers are the main element that resists loads and their properties vary greatly depending on the type and arrangement of reinforcing fibers. As the reinforcing fibers, carbon fibers, aramid fibers, glass fibers and the like may be used. The production method of the fiber-reinforced composite material is pulverization, filament winding, hand layup, etc. In the present invention, the pulverization method produces the cross-sectional shape of each member described above. The pultrusion method is produced through a mold that determines the cross-sectional shape by drawing molding. It can be produced indefinitely without limitation in the longitudinal direction, and the reinforcing fibers are mainly arranged in the longitudinal direction.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention . The invention is not limited by these variations and modifications, but is only limited by the scope of the appended claims.

10: floor member
11: footrest
111: rib
12: structure
20: joint member
30: floating body
31: semicircle column
32: upper coupling
321: coupling groove
322: step
40: fixing means

Claims (6)

A plurality of floor members 10 arranged horizontally and vertically to configure a moving passage of the worker while partitioning a space for farming fish;
A plurality of joining members 20 connecting the plurality of bottom members 10 to each other to form a frame of a predetermined shape; And
And a plurality of floats 30 fixed to the bottom of the bottom member 10 such that a frame composed of a plurality of bottom members 10 and a joining member 20 floats on the water surface.
The bottom member (10), the joining member (20) and the floating body (30) is a cage structure for marine fishing, characterized in that composed of fiber-reinforced composite material. The method according to claim 1,
The bottom member 10,
A footrest 11 having a plurality of ribs 111 protruding in parallel with each other downward along the longitudinal direction, and a plurality of structures 12 coupled to the footrest 11 in parallel with the ribs 111 at regular intervals. Sea fishing cage structure, characterized in that it comprises a. The method according to claim 2,
The structure 12 is
Cage structure for marine fishing, characterized in that coupled to both ends in the width direction of the scaffold (11). The method according to claim 2,
Scaffolding (11) and the structure (12) is a cage structure for marine fishing, characterized in that it is configured integrally. The method according to claim 2,
Floating body 30,
The semi-cylindrical part 31 submerged in the water surface and the upper engaging portion 32 having a stepped portion coupled to the bottom member 10 are formed in a cross-sectional shape, and the upper surface of the upper engaging portion 32 is spaced apart from each other along the longitudinal direction. For example, a coupling groove 321 is formed into which the rib 111 of the bottom member 10 is inserted, and the stepped portion 322 formed at both ends is mounted with the structure 12 of the bottom member 10. structure. The method according to claim 5,
The floating body 30 penetrates through the structure 12, the ribs 111, and the floating body 30 in a state where the rib 111 of the bottom member 10 is inserted into the coupling groove 321 of the floating body 30. Cage structure for marine fishing, characterized in that it further comprises a fixing means (40) for connecting to the bottom member (10).

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