KR101241240B1 - Tetrapod - Google Patents

Abstract

Tetrapods are disclosed. The silver of the present invention is a tetrapod installed on the outer side of the embankment or breakwater and stacked so as to attenuate the wave power. At least one seating groove is recessed in the selected one or more regions, and the seating groove has a configuration in which a binding ring for hooking a wire or chain does not protrude to the outer surface. Therefore, since the binding ring is installed inside the seating groove of the body, damage to the binding ring can be prevented, and when a rotating structure is provided, binding can be performed in various directions. In addition, when the binding string member is installed, more stable transport and binding are possible by dispersing the load, and it is also possible to apply to the existing tetrapod.

Description

Tetrapod

The present invention relates to tetrapods, and more particularly, to a tetrapod that is easy to transport and install, and can be coupled with a solid binding force with neighboring tetrapods.

In general, tetrapods are installed on the outer side of the breakwater to prevent breakwater from breaking. These tetrapods are made of concrete and are manufactured in various scales depending on wave energy ranging from 5 tons to 60 tons.

However, even though the above-described tetrapods are installed to prevent damage to the embankment or breakwater caused by the waves, the tetrapods are separated and stacked in an independent state, so that the tetrapods individually flow or move when an unpredictable heavy wave strikes. There was a problem in that the effect of reducing blue was significantly lowered due to the case where the first installation was gradually biased to one place or lost to the deep sea, and thus tetrapods had to be additionally installed.

In order to solve or minimize this problem, tetrapods may be manufactured to be larger and heavier. However, as the volume of tetrapods becomes larger than the design, the production cost and the overall cost of installation and installation are high. However, the installation work is also difficult and difficult. In addition, when tetrapods are pushed by unexpected waves and collide with other adjacent facilities, a variety of problems occur, such as damage to the facilities or personal injury.

As a problem with the prior art, a technique in which a binding ring of adjacent tetrapods is bound to each other by a wire or a chain after the binding ring is buried in a certain area of the tetrapod has been disclosed. This technique has the effect of increasing the binding force of the tetrapods so that the flow does not occur, but has the following problems.

That is, since the binding ring buried in the tetrapod protruded to the outside, there was a problem of being damaged by interference with adjacent tetrapods during construction. In addition, when the buried ring is simply buried, when a strong lateral force acts on the buried ring, a large bending stress and pull force are generated in the fixing portion of the bundling ring, and there is also a problem of being detached from the tetrapod.

The technical problem of the present invention is to solve the problems of the prior art described above, and to provide a means to prevent the breakage of the binding ring for binding during construction and transportation of tetrapods.

Another technical problem of the present invention is to provide a means for the binding ring for the binding of the tetrapods to withstand a sufficient bending moment and pull force.

Another technical problem of the present invention is to provide a ring structure capable of more easily binding of tetrapods and sufficiently withstanding high loads during transportation.

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

The technical problem is, according to the present invention, as a tetrapod installed on the outer side of the embankment or breakwater to attenuate the wave power,

At least one seating groove is recessed in at least one area selected from the end regions of each body protruding in different directions from the center, the concave boundary regions of each body, and the outer circumferential regions of each body,

The seating groove is achieved by a tetrapod, characterized in that the binding ring for the wire or chain is not protruded to the outer surface.

At this time, the binding ring,

It is characterized in that one end is connected to the anchor inside the body.

The binding ring,

It is characterized by being formed in a swivel joint structure.

The binding ring,

One end is connected to the anchor inside the body, and the other end is characterized in that a ring portion having a fitting hole is formed so that a wire or a chain is caught.

The binding ring,

A support member having one end connected to an anchor inside the body; And

It characterized in that it comprises a ring member to maintain a state lying on the bottom of the seating groove when one side is rotatably coupled to the support member is not used.

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According to the present invention, by placing the binding ring in the recessed recessed groove in a predetermined area of the tetrapod, there is provided an effect of preventing the binding ring from being broken or deformed during construction or transportation of the tetrapod.

In addition, since the binding ring is connected to an internal anchor forming the skeleton of the body, or a binding string member is installed, it is possible to sufficiently withstand high loads during transportation or binding, and the load is distributed and stabilized by the binding string member. The effect of being able to be transported in a state is also provided.

1 is a perspective view showing a tetrapod according to a preferred embodiment of the present invention.
Figure 2 is a cross-sectional view showing the binding ring shown in Figure 1;
3A and 3B are cross-sectional views showing another embodiment of the binding ring.
4 is a perspective view showing a tetrapod according to another embodiment of the present invention.
Figure 5 is a perspective view showing another embodiment of the binding string member shown in Figure 4;
Figure 6 is a perspective view showing another embodiment of the binding string member shown in Figure 4;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the present invention, descriptions of already known functions or configurations will be omitted to clarify the gist of the present invention.

1 is a perspective view showing a tetrapod according to a preferred embodiment of the present invention, Figure 2 is a cross-sectional view showing various embodiments of the binding ring shown in FIG.

1 and 2, the tetrapod 10 according to the present embodiment includes end regions 12A of each body 12 protruding in different directions from the center, and concave boundary regions of each body 12 ( 12B), at least one or more seating grooves 14 are recessed in one or more regions selected from the outer circumferential region 12C of each body 12, and the wire or chain 20 is fastened to the seating grooves 14 The ring portion 31 of the binding ring 30 is disposed so as not to protrude to the outer surface.

That is, one end of the binding ring 30 is installed inside the seating groove 14 that is recessed in the body 12.

The binding ring 30 is one end of which is connected to the iron structure or the anchor 16 inside the body 12, and the other side is formed with a ring 31 formed with a fitting hole 31a, the tetrapod 10 When molding, the steel structure 16 is connected to each binding ring 30 and then molded into concrete using a formwork, so that one end of the binding ring 30 is embedded in the concrete and the internal steel structure 16 It is connected to. At this time, as shown in FIG. 2, if the tetrapod 10 is a non-muscular structure, after installing the anchor 16, the binding ring 30 is connected to the anchor 16, and if the steel structure exists, the steel structure Connect to. In addition, after extending the end of the binding ring 30, it can also be produced after placing it inside the tetrapod 10 and then the tetrapod 10.

Then, the seating groove 14 is formed by forming a protrusion for forming a seating groove inside the formwork of the area corresponding to the binding ring 30 when forming the tetrapod 10, and then forming the tetrapod 10 into concrete to form a binding ring ( 30) is formed around, such that the seating groove 14 is such that the binding ring 30 does not protrude from the outer surface of the body 12.

The operation of the present embodiment configured as described above is as follows.

The seating groove 14 is formed in a predetermined region of the body 12, for example, an end region 12A, a concave boundary region 12B, or an outer peripheral region 12C, or in any one or more regions. , When the binding ring 30 is disposed inside the seating groove 14, the binding ring 30 is not protruding than the outer surface of the body 12.

In this state, a towing ring or the like is connected to the selected binding ring 30 to transport the tetrapods 10 to stack each at a desired position. As described above, in the process of laminating after transporting the tetrapod 10, the ring portion 31 of the bundling ring 30 is installed inside the seating groove 14, thereby causing damage due to indirect contact with the neighboring tetrapod 10. Deformation is prevented.

That is, since the ring portion 31 of the binding ring 30 does not protrude to the outer surface of the body 12, it is prevented from being damaged or deformed by the impact by hitting the other tetrapod 10 by the lamination operation.

Then, after passing the wire or chain 20 through the fitting hole 31a of each binding ring 30, the tetrapod 10 is firmly connected to each other by connecting to the binding ring 30 of the adjacent tetrapod 10 It is possible to maintain a solid state.

On the other hand, as shown in Figure 2, because one end of the binding ring 30 is connected to the anchor 16 fixed to the inside of the body 12 or an iron structure by various coupling means, the wire to the binding ring 30 Even when the back is lifted by connecting the back, the phenomenon that the binding ring 30 is detached from the body 12 is prevented. That is, since the ring according to the prior art was fixed in a state where one end was buried in concrete, when the ring of the crane is connected to the ring and lifted, the load of about 50 tons is concentrated on the ring, so the ring is broken or tetrapod (10 ), but according to the present embodiment, one end of the link ring 30 is connected to the anchor 16 so that even when the load is concentrated on the link ring 30, the link ring 30 can withstand enough Will be.

On the other hand, Figure 3a, 3b in the accompanying drawings shows another embodiment of the binding ring.

First, Figure 3a is made of a swivel joint (Swivel Joint) structure in which the binding ring 30 is rotatable. That is, the rotating body 32 having a hook hole through which the wire or the chain 20 passes is fixed to the fixed support member 34 having one end coupled to the anchor 16 so as to be rotatably coupled. At this time, the end portion of the rotating body 32 does not protrude from the outer surface of the body 12. As such, since the binding ring 30 is freely rotated, the operation of binding by passing through the wire or the chain 20 can be easily performed in various directions.

And, Fig. 3b is that the ring member 38 is rotatably coupled to the support member 36, one end of which is fixed to the anchor 16 by the binding ring 30. As such, since the ring member 38 is rotatably coupled to the support member 36, the operation of binding through the wire or the chain 20 as described above can be easily performed in various directions, and the ring member 38 ), so the seating groove 14 may be shallow.

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As described above, since the binding ring 30 is installed inside the seating groove 14 of the body 12, damage to the binding ring 30 can be prevented. It becomes possible.

In the foregoing, although specific embodiments of the present invention have been described and illustrated, the present invention is not limited to the described embodiments, and it is common knowledge in the field of this technology that various modifications and modifications can be made without departing from the spirit and scope of the present invention. It is obvious to those who have it. Therefore, such modifications or variations should not be individually understood from the technical spirit or viewpoint of the present invention, and the modified embodiments should belong to the claims of the present invention.

10: Tetrapod 12: body
14: seating groove 16: anchor
20: wire or chain 30: binding ring
34, 36: support member 38: ring member

Claims (10)

delete delete delete delete Tetrapods installed on the outer side of embankments or breakwaters and stacked to attenuate wave power.
At least one seating groove is recessed in one or more regions selected from the end regions of each body protruding in different directions from the center, the concave boundary regions of each body, and the outer circumferential regions of each body,
The seating groove is arranged so that the binding ring for the wire or chain does not protrude to the outer surface,
The binding ring,
Swivel joint structure or
Tetrapod characterized in that it comprises a support member that is connected to the anchor inside the body once and one side rotatably coupled to the support member to maintain a state lying on the bottom of the seating groove when not in use.

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