KR101002006B1 - Tetrapod served as artificial fishing reef reinforced end for preventing destruction - Google Patents

Abstract

PURPOSE: An artificial fish reef and tetrapod in one is provided, which can reinforce a head unit of a leg part which is relatively more vulnerable than other place. CONSTITUTION: An artificial fish reef and tetrapod in one comprises: three leg parts which are formed radially toward the vertex of cubic while keeping constant angle among each other; four legs(11,12,13,14) consisting of a head unit which is formed on the end part of three leg parts; a through-hole which is opened in the central part to which legs are connected in four directions; and a lattice type reinforcing mesh which protects the head unit from external force.

Description

TETRAPOD SERVED AS ARTIFICIAL FISHING REEF REINFORCED END FOR PREVENTING DESTRUCTION}

The present invention relates to an artificial reef combined tetrapod, and more particularly, to an artificial reef combined tetrapod that can reinforce the head portion that is the end of the leg relatively weaker than other places by the wave force or collision.

In general, a dike or breakwater (hereinafter referred to as a dike) is provided with a sofa block on the outward side where waves are coming in. This sofa block is designed to protect the harbor by preventing the destruction of the dike caused by waves. The material is mainly made of concrete, and sofa blocks are used in various forms all over the world, and most of them use tetrapod products with almost four legs in Korea.

The tetrapod is designed to determine the size according to the wave height and wave force that is pushed into the dike, the tetrapod having a weight of about 5t ~ 60t in Korea is used. The tetrapod basically forms a tetrahedron, and four legs extend from the center of the tetrahedral toward each vertex. The tetrapods form a tetrahedron because the center of gravity of the tetrahedron is at the bottom, so that the safety is good and the same shape is always maintained even when the tetrahedron is rolled. In addition, when a plurality of tetrapods are provided, the force of the wave is lost or reduced through the empty space therebetween. The tetrapod is the most widely used to date because it has a long construction experience in Korea and the effect is verified.

The tetrapod is installed to maximize the sofa (wave height and weakening) effect, but the tetrapods are separated and stacked in an independent state so that the tetrapods are individually flowed and driven when unexpected waves are hit. As a result, it gradually moved from the initial installation place and drove to one place or was lost to the deep sea, and this would inevitably degrade the sofa effect, and the tetrapod must be reinstalled. In addition, in order to reduce such problems, tetrapods may be made larger and heavier. However, as the size of the tetrapods becomes larger than the design, it may be expensive to manufacture and install, and large tetrapods may not be expected. When hit by a large wave that has not been hit by another adjacent facility, the impact of the facility may be damaged or damage may occur.

On the other hand, tetrapods are installed with four legs supported on the coastal surface or other tetrapods. Therefore, abrasion occurs due to friction with other tetrapods or surrounding structures, and in severe cases, the legs are broken by mutual collision. In this case, the weight becomes lighter and the bonding force drops, which makes it easy to move and reaches a very dangerous state.

In addition, the reinforcement is reinforced in some sofa blocks to increase the overall strength of the sofa block. However, reinforcing bars have the disadvantage of being corroded by sea water. For example, when the reinforcing bars are exposed to the sea due to various external forces, the reinforcing bars are corroded and fractured. If there is no skeleton of the sofa block is a problem that the sofa block is broken even by a small external force.

The present invention is to solve the problems described above, the end portion to prevent the destruction that can reinforce the head portion of the bridge relatively vulnerable to other phenomena such as natural phenomena such as waves or wind or contact with the surrounding structure, etc. The objective is to provide a reinforced artificial reef combined tetrapod.

In addition, another object of the present invention is to prevent the damage to the tetrapod by replacing the skeleton of the artificial reef combined dual pods that are not eroded by sea water.

In order to prevent the destruction according to the present invention for achieving the object as described above, the artificial reef combined tetrapod reinforcing the end, three legs formed radially toward the vertex of the tetrahedron while maintaining a certain angle to each other, the Four legs each having a head portion formed at an end of the three leg portions having a triangular pyramid having a flat upper surface; A through hole formed in a central portion to which the legs are connected in four directions; It is installed so as to be exposed to the outside of the head portion of the leg, characterized in that it comprises a reinforcing net to protect the head portion from damage by external force.

According to the tetrapod combined artificial reef reinforcement to prevent the destruction by the present invention, by installing a reinforcing net on the surface of the head portion, the end of the bridge, the natural phenomenon such as friction or waves with the surrounding structure through the tensile force of the reinforcing net It is possible to prevent damage to the head portion (abrasion, erosion, etc.) due to, and to prevent spreading to other portions even if damage to the head portion can be prevented, so durability of the tetrapod can be improved. Here, when the reinforcing net is connected to the internal reinforcing material to form the reinforcement as a support base or plate-shaped cross-section is fixed in the composition, such as concrete, the support base of the reinforcing net can be more robust to reinforce the head portion more effectively.

When the reinforcement inside is exposed to the outside due to the erosion of the legs other than the head, the reinforcement does not cause corrosion even when the reinforcement is in contact with seawater, thereby preventing the tetrapod from being broken by external force.

1 is a perspective view of an artificial reef combined tetrapod reinforcing end to prevent destruction by the present invention.
Figure 2 is a plan view of the artificial reef combined tetrapod reinforcing the end to prevent destruction by the present invention.
Figure 3 is an enlarged plan view of the head portion applied to the artificial reef combined tetrapod reinforcing end to prevent destruction by the present invention.
Figure 4 is an enlarged front view of the head portion applied to the artificial reef combined tetrapod reinforcement end to prevent destruction by the present invention.
5 is an enlarged view of the installation state of the reinforcing network applied to the artificial reef combined tetrapod according to the present invention.
Figure 6 is a perspective view of the reinforcing material applied to the artificial reef combined tetrapod according to the present invention.
Figure 7 is a block diagram of the reinforcing material applied to the artificial reef combined tetrapod according to the present invention.
8 is a plan view showing a construction example of the artificial reef combined tetrapod according to the present invention.

As shown in Fig. 1 and Fig. 2, the artificial reef combined tetrapod 10 reinforcing the end portion in order to prevent destruction by the present invention, the first to radially formed to the vertex of the tetrahedron while maintaining a certain angle between each other; Fourth legs 11, 12, 13 and 14; The first to fourth legs 11, 12, 13, 14 are formed in the through hole 15 is formed to open in four directions in the central portion connected.

The tetrapod 10 may be attenuated by the seawater passing through the through hole 15 and the wave force is not transmitted to the tetrapod 10 as it is, thereby preventing the flow (emergency) of the tetrapod 10 due to the wave force, and the flow of the tetrapod 10. There is no need to overweight the tetrapod 10 for prevention. In other words, it is possible to reduce the amount of concrete used for the production of the tetrapod 10.

The first leg 11 has a shape in which the first to third leg portions 11A, 11B, and 11C extend while maintaining the same angle in plan view, and a head portion 11D is formed at an end portion thereof.

 The first to third leg portions 11A, 11B, and 11C are enlarged in cross-sectional area while going to the head portion 11D.

The head portion 11D is, for example, in the form of a triangular pyramid (exactly, as shown in the drawing, the vertex portion of the triangle is formed in the shape of a chamfer and is formed in a hexagon, and the top is formed in a flat hexagon).

3 is a bottom view illustrating the structure of the head portion 11D and the first to third leg portions 11A, 11B, and 11C, and the first to third leg portions 11A, 11B, and 11C are head portions ( It is connected to each other at the center of 11D and extends toward the vertex of the head portion 11D, respectively, and does not protrude out of the head portion 11D.

The head portion 11D is applied with a reinforcing net 11E for preventing wear and cracking of the head portion 11D due to an impact such as a wave force. The reinforcement net 11E is provided on the surface of the head portion 11D in which wear and the like are the most severe. For example, the reinforcing net 11E is laid on the head portion 11D by pressing the reinforcing net 11E before the filling material such as concrete is cured during the pouring of the tetrapod 10 by the installation method of the reinforcing net 11E. It can install by making it insert into the surface of the part 11D.

The reinforcement net 11E is covered by concrete and generates tensile force in the head portion 11D, thereby preventing damage due to impact when a local impact of the head portion 11D is applied, and at this time, the head portion 11D. It should not be separated from, for this purpose it may be formed of a plate-shaped cross section that is fixed to the inside of the head portion (11D). Alternatively, a separate fastener may be connected to the bottom of the reinforcing net 11E. The fastener is connected to the reinforcing net 11E through the connecting member, the cross section is formed larger than the connecting member is fixed to the head portion.

The reinforcing net 11E may remove the bubbles generated during the pouring curing of the concrete.

The reinforcing mesh 11E may be provided only on the surface of the head portion 11D or alternatively, as shown in FIG. 4, the circumference portion over the head portion 11D to the first to third leg portions 11A, 11B, 11C. It may also be installed to span.

The leg 11 has a radial structure of three leg portions 11A, 11B, and 11C, and a groove is formed between the three leg portions 11A, 11B, and 11C, through which seawater bridges 11 Can flow along.

So far, only the first leg 11A has been described, but since the second to fourth legs 11B, 11C, and 11D are configured in the same manner as the first leg 11A, the second to fourth legs 11B, 11C, and 11D are the same. ), The detailed description is omitted, and the same reference numerals are used as in the first leg 11A.

For convenience of explanation, the first to fourth legs 11, 12, 13, and 14 are divided, but in practice, the legs 11, 12, 13, and 14 are connected to each other, and thus, the tetrapod 10 To describe differently, a total of six legs are formed in the form of tetrapod 10 by connecting three at each vertex.

Tetrapod 10 has been reinforced conventionally for reinforcing the reinforcement, in the present invention, in order to solve the strength degradation due to corrosion of the reinforcing bar, as shown in Figure 1, the fiber reinforcement 20 is applied.

Fiber reinforcement 20 is inserted into the first to fourth legs (11, 12, 13, 14) to reinforce the strength of each of the legs (11, 12, 13, 14) and each leg (11) , 12,13,14) are connected to each other to expand the support base.

The fiber reinforcing material 20 is made of glass fiber or carbon fiber or aramid fabric and consists of a reinforcing bar 21 such as a circular cross section. The reinforcing bar 21 such as glass fiber has a great strength but is difficult to process in a curved shape, and thus is manufactured along the shape of the tetrapod 10 through the connector 22. The connector 22 is configured to connect two or more reinforcing bars 21 at various angles.

The connector 22 may have a tubular structure in which a fastening groove is formed therein, and the reinforcing bar 21 is inserted into and fixed to the fastening groove of the connector 22.

Fiber reinforcement 20 of such a configuration may be coupled to the reinforcing net (11E). For example, the fiber reinforcing material 20 is formed with a connecting member 23 at the end. The connecting member 23 is made of a hard material (for example, the same material as the fiber reinforcing material 20) to be spaced apart from the reinforcing material 11E from the fiber reinforcing material 20, and can be fixed in various ways to the reinforcing network 11E. Can be.

As shown in FIG. 8, when viewed from above, three tetrapods 10A, 10B, and 10C are constructed in a triangular composition in which one leg is inserted between the legs of another tetrapod, so that the legs of the three tetrapods 10A, 10B and 10C are viewed. Are collected from each other, and the joint member 30 is installed at the collected portion so that the three tetrapods 10A, 10B, and 10C are bound to each other. In this way a large number of tetrapods can be bound. The joint member 30 may be configured in various ways such as being inserted into holes formed in the tetrapods 10A, 10B, and 10C, respectively, and tightened with bolts.

The present invention may also include a measuring instrument that measures data including wave force and communicates with a monitor system on the ground. The meter may be installed at intervals of, for example, 50 m based on the installation state without having to be installed in all tetrapods. The measuring device may also be a camera that informs the image data. The measuring instrument transmits the measured data by wired or wireless communication with the monitor system on the ground to the monitor system, and the administrator can check the monitor system to grasp the situation underwater in the distance and the ground.

According to the tetrapod combined artificial reef reinforcing the end to prevent destruction by the present invention configured as described above, the head portion (11D, 12D, 13D, 14D) is made of a composition such as concrete, the surface is reinforcement net (11E, 12E) , 13E, 14E).

When the tetrapod is installed on the shore or the like, the head portions 11D, 12D, 13D, and 14D are subjected to external forces due to various causes.

For example, when the tetrapod is installed, an external force is applied to the head portions 11D, 12D, 13D, and 14D due to collisions with other tetrapods or surrounding structures, or external forces such as wave forces, which are natural phenomena, are applied to the head portions 11D, 12D, 13D, 14D). As such, when an external force is applied to the head portions 11D, 12D, 13D, and 14D, the composition, such as concrete, may erode or fall off. In this case, the reinforcement nets 11E, 12E, 13E, and 14E may be pulled out by their own tensile force. Since the head portions 11D, 12D, 13D, and 14D are supported, even if a composition such as concrete of the head portions 11D, 12D, 13D, and 14D is eroded, only a portion thereof is eroded away from the erosion. Do not

When the reinforcing nets 11E, 12E, 13E, and 14E are connected to the reinforcing member 20 inside the tetrapod, the reinforcing nets 11E, 12E, 13E, and 14E are based on the reinforcing member 20 and the head portions 11D and 12D. Since the installation state can be firmly maintained at the 13D and 14D, the head portions 11D, 12D, 13D, and 14D can be further reinforced.

In particular, since the reinforcing meshes 11E, 12E, 13E, and 14E are provided on the surface without being inserted into the head portions 11D, 12D, 13D, and 14D, the surfaces of the head portions 11D, 12D, 13D, and 14D are provided. This wear can be prevented and, ultimately, all parts of the tetrapod can be protected by preventing the progress of wear of the head portions 11D, 12D, 13D, and 14D.

On the other hand, the reinforcement 20 is supported so that the tetrapod is not broken by the external force, when the reinforcement 20 is exposed to seawater due to erosion of the tetrapod, the reinforcement 20 does not cause corrosion due to seawater due to the characteristics of the material Thus, the shape of the tetrapod can be maintained.

10: tetrapod, 11, 12, 13, 14: legs
11D, 12D, 13D, 14D: Head, 11E, 12E, 13E, 14E: Reinforcement net
20: reinforcing material, 21: reinforcing bar
22: connector, 23: connecting member
30: joint member,

Claims (6)

Three legs formed radially toward the vertices of the tetrahedron while maintaining a certain angle to each other, and the head portions 11D, 12D, 13D, and 14D formed on the ends of the three legs in the form of triangular pyramids, respectively. Four legs 11, 12, 13 and 14;
A through hole 15 formed in a central direction to which the legs are connected in four directions;
The end portion of the head portion of the leg is provided so as to be exposed to the outside to protect the head portion from damage caused by external force, the grid reinforcement net 11E, 12E, 13E, 14E Reinforced artificial reef combined with tetrapods. The fiber reinforcement material of claim 1, wherein a plurality of reinforcing bars 21 made of glass fiber, carbon fiber, or aramid fabric are connected to each other so as to change angles through the connector 22, and the fiber reinforcement 20 is installed in the tetrapod. Tetrapod combined artificial reef with reinforced ends to prevent destruction, characterized in that it comprises a). The method according to claim 2, wherein the fiber reinforcement is an artificial reef combined with the reinforcement end to prevent fracture, characterized in that it comprises one or more connecting members (23) connected to the reinforcing net. The method of claim 2, wherein the reinforcing net is formed of a plate-shaped cross-section so as to be embedded in the artificial reef combined tetrapod to prevent the destruction, characterized in that the. The method according to claim 2 or 4, wherein the bottom of the reinforcing net includes a fastener fixed through the connecting member and embedded in the leg, the fastener is formed in a larger cross-sectional area than the connecting member to support the reinforcing net Tetrapod combined with artificial reefs with reinforced ends to prevent destruction. The artificial fish of claim 1, further comprising a measuring device installed in the tetrapod and measuring data including wave force to communicate with a monitor system on the ground. Super combined tetrapod.

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