KR101164621B1 - Tetrapod binding system - Google Patents

Abstract

The present invention relates to a tetrapod binding system that can increase the binding force of tetrapods. The tetrapod binding system of the present invention is formed comprising tetrapods and connecting means.
The tetrapod binding system comprises at least two tetrapods, and a connecting means is coupled to adjacent tdrapods to bind the tetrapods. Thus, the tetrapod binding system prevents tetrapods from flowing or lost by algae or waves.

Description

TETRAPOD BINDING SYSTEM

The present invention relates to a tetrapod binding system.

In general, the breakwater is provided with tetrapods to reduce the wave force on the outer port where the wave is coming, and is made of concrete to prevent the loss and movement by the wave.

The tetrapod forms a tetrahedron and has four legs extending from the center of the tetrahedral toward each vertex. At this time, each leg forms a smooth cylindrical shape, and the diameter becomes narrower from the center to the outside. Therefore, the tetrapod can overcome the strong algae or water pressure to block the waves or tsunami and each structure can maintain a sense of stability. In addition, the tetrapods are the same in each shape even if any one of the four legs upward, the center of gravity of the tetrahedron is the lowest, so the stability is good. However, the existing tetrapods are separated and stacked in separate states, and the binding force between each other is very weak, and when the waves are strong, the tetrapods are pushed by the pressure applied and flow separately, gradually moving and being lost at the initial installation place. The case occurred. Therefore, the sofa effect due to the tetrapod installation is reduced and the installation work of the tetrapod has to be redone.

In order to reduce such a problem, each tetrapod may be large and heavy, but there is a risk of falling due to the increase in height, and there is a problem in that the production cost and the cost of installation are high. In addition, when tetrapod is pushed by a big wave and hit another adjacent facility, the impact is accompanied by various problems such as destruction of the facility or damage to life.

An object of the present invention is to provide a tetrapod binding system that can increase the binding force of the tetrapod to prevent flow and loss caused by waves.

The tetrapod binding system of the present invention for solving the above problems is a tetrapod including a first leg portion, a second leg portion, a third leg portion, a fourth leg portion formed in four directions from the center; And it characterized in that it comprises a connecting means coupled to the tetrapot.

In addition, the connecting means may be formed including a rope body portion, one end portion and the other end of the rope body portion is bent in a U-shape and U-bolt coupled to the ring portion.

In addition, the connecting means is formed at both ends of the first rope body portion and the first rope body portion surrounding any one of the first leg portion, the second leg portion, the third leg portion and the fourth leg portion of the tetrapod are coupled to each other A first connecting means having a first ring portion, a second rope body portion intersecting between the tetrapods, and a second ring portion formed at both ends of the second rope body portion and coupled to the first ring portion. It may be formed including a second connecting means.

In addition, the connecting means is a single rope body portion between one side portion of the tetrapod leg, the other side of the adjacent tetrapod leg portion, the central portion between the one side portion and the other side is located between the adjacent tetrapods and

In the process of enclosing the leg of the tetrapod portion of the single rope body portion, the first knot portion and the single rope body portion formed by binding one side end portion of the single rope body portion 50 to one side or the center portion of the single rope body portion 50a. In the process of wrapping the adjacent leg of the tetrapod, the other end of the single rope body portion may be formed to include a second knot is formed by binding to the other side or the center portion of the single rope body portion (50a). In this case, the central portion of the single rope body portion may be formed to form an obtuse angle with a direction in which the leg portion of the tetrapod wrapped around one side portion or the other portion of the single rope body portion extends from the center.

According to the tetrapod binding system of the present invention, the respective tetrapods are connected to each other by separate connection means to form a plurality of tetrapods as one tetrapod binding system, thereby preventing the loss.

1 is a perspective view of a tetrapod binding system according to an embodiment of the present invention.
2 is a plan view of a tetrapod constituting a tetrapod binding system according to an embodiment of the present invention.
3 is an enlarged view of “A” of FIG. 1.
4 is an enlarged view of a tetrapod binding system according to another embodiment of the present invention.

Hereinafter, the tetrapod binding system of the present invention will be described in more detail with reference to the accompanying drawings. 1 is a perspective view of a tetrapod binding system according to an embodiment of the present invention. 2 is a plan view of a tetrapod constituting a tetrapod binding system according to an embodiment of the present invention. 3 is an enlarged view of “A” of FIG. 1.

Tetrapod binding system 10 according to an embodiment of the present invention, with reference to Figures 1 to 3, is formed including a tetrapod 20 and the connecting means 30.

The tetrapod binding system 10 comprises at least two tetrapods 20, and the connecting means 30 are coupled to the tetrapods 20 adjacent to each other to couple the tetrapods 20. Thus, the tetrapod binding system 10 prevents the tetrapod 20 from flowing or lost by algae or waves.

The tetrapod 20 includes a first leg 20a, a second leg 20b, a third leg 20c and a fourth leg 20d. Hereinafter, when it is not necessary to distinguish the position of the leg portion to be referred to as a leg portion.

The tetrapod 20 is formed entirely of concrete, and may be formed by including reinforcing bars therein. In addition, the tetrapod 20 may be formed of various materials such as reinforced plastic.

The first leg portion 20a, the second leg portion 20b, the third leg portion 20c, and the fourth leg portion 20d extend in four directions from the center of the tetrapod 20. The first leg portion 20a, the second leg portion 20b, the third leg portion 20c, and the fourth leg portion 20d may be radially formed to have a constant angle from each other. In addition, the first leg 20a, the second leg 20b, the third leg 20c and the fourth leg 20d may be formed to maintain different angles from the center portion. On the other hand, the tetrapod 20 may be formed in various forms having four legs extending from the center.

In addition, the first leg portion 20a, the second leg portion 20b, the third leg portion 20c, and the fourth leg portion 20d each have a substantially cylindrical shape, so that the diameter becomes narrower from the center to the outside. Is formed.

The connecting means 30 is formed including a first connecting means 31 and a second connecting means 32.

The first connecting means 31 and the second connecting means 32 have the same or similar basic construction and differ in function. The first connecting means 31 surrounds at least one leg 20a, 20b, 20c, 20d of the tetrapod 20 and is directly coupled to the tetrapod 20. In addition, the second connection means 32 is indirectly coupled to the tetrapod 20 while both sides are coupled to two first connection means 31 which are respectively coupled to adjacent tetrapods 20. Thus, the first connecting means 31 and the second connecting means 32 are mutually coupled to the tetrapod 20 adjacent to each other.

The first connecting means 31 and the second connecting means 32 are basically formed to include a rope body portion, a ring portion and a U bolt. Hereinafter, the configurations of the first connecting means 31 and the second connecting means 32 will be described. However, when the first connecting means 31 and the second connecting means 32 do not need to be separated separately, the names of the connecting means, the rope body portion, the ring portion or the U bolt will be used.

The first connecting means 31 is formed to include a first rope body portion 31a, a first ring portion 31b and a first U bolt 31b.

The first rope body portion 31a is formed of a general rope having rigidity. The first rope body portion 31a may be used ropes used in a construction site. The first rope body portion 31a may be formed to have an appropriate length and thickness according to the size of the tetrapod 20 or the required rigidity. The first rope body part 31a is coupled to the tetrapod 20 while surrounding at least one leg of the tetrapod 20 or the central portion of the tetrapod 20.

The first ring portion 31b is formed such that both ends of the first rope body portion 31a are bent in a U shape to form a ring shape. The first ring portion 31b is coupled to the ring portion of the other connecting means so that adjacent connecting means are coupled to each other.

The first U bolt 31c is formed of a commonly used U bolt. The first U bolt 31c is coupled to the opening of the first ring portion 31b so that the first ring portion 31b forms an intact ring. More specifically, the first U bolt 31c couples the end portion of the first ring portion 31b to the first rope body portion 31a. The first U bolt 31c may be coupled to the first ring portion 31b first, or the first ring portion 31b may be coupled to the first ring portion 31b after the ring portion of the adjacent connecting means is coupled. .

The second connecting means 32 is formed including a second rope body portion 32a, a second ring portion 32b, and a second U bolt 32c. The second connecting means 32 is coupled to the first connecting means 31 which traverse the space between adjacent tetrapods 20 and are respectively coupled to the tetrapods 20.

The second rope body portion 32a is formed the same as or similar to the first rope body portion 31a. The second rope body portion 32a is formed to cross the adjacent tetrapod 20. The second rope body portion 32a may be formed to have an appropriate length according to the distance between adjacent tetrapods 20. However, since the second rope body portion 32a crosses the adjacent tetrapod 20, the length of the second rope body portion 32a may be shorter than that of the first rope body portion 31a.

In addition, the second rope body portion 32a preferably has an obtuse angle and a direction in which the leg portions 20a, 20b, 20c, and 20d of the tetrapod 20 wrapped around the first rope body portion 31a extend from the center. It is formed to achieve. That is, when the first rope body portion 31a encloses the leg portions 20a, 20b, 20c, and 20d extending in any one direction, the second rope body portion 32a is formed in the direction of extension of the leg portion. It is formed to achieve an angle of more than degrees. In this case, peeling off of the ring portion 31b of the first rope body portion 31a from the leg portions 20a, 20b, 20c, 20d of the tetrapod 20 is minimized.

The second ring portion 32b is formed such that both ends of the second rope body portion 32a are bent in a U shape to form a ring shape. The second ring portion 32b is coupled to the ring portion of the other connecting means so that adjacent connecting means are coupled to each other.

The second U bolt 32c is formed the same as or similar to the first U bolt 32c. Thus, the second U bolt 32c is coupled to the opening of the second ring portion 32b so that the second ring portion 32b forms an intact ring. The second U bolt 32c may first be coupled to the second ring portion 32b or may be coupled to the second ring portion 32b after the ring portion of the connecting means adjacent to the second ring portion 32b is coupled. .

The following describes the binding method and operation of the tetrapod binding system 10 according to an embodiment of the present invention.

First, a plurality of tetrapods 20 are formed by stacking each other. The first connecting means 31 is coupled to the tetrapod 20 such that the first rope body portion 31a surrounds a specific leg or central portion of the tetrapod 20. At this time, the first connecting means 31 has a first U bolt 31c is coupled to the first ring portion 31b of both ends, or a first U bolt to the first ring portion 31b of at least one end thereof. 31c may be coupled. Alternatively, the first connecting means 31 may not be coupled to the first U bolt 31c at both ends.

Next, both ends of the second connecting means 32 are respectively coupled to the first connecting means 31 which are coupled to the adjacent tetrapod 20. More specifically, the second connecting means 32 is inserted into the first ring portion 31b of the first connecting means 31 adjacent to each other so that the second ring portions 32b at both ends are coupled to each other. At this time, according to whether the first U bolt 31c of the first connecting means 31 is coupled, the second connecting means 32 is determined in the coupling order of the second U bolt (32c). For example, when the first U bolt 31c is coupled to the first ring portion 31b to which the second ring portion 32b of the second connecting means 32 is coupled, the second ring portion ( 32b) is coupled to the second U bolt 32c after being inserted into the first ring portion 31b. In addition, when the first U bolt 31c is not coupled to the first ring portion 31b to which the second ring portion 32b is coupled, the second ring portion 32b is first used as the second U bolt 32c. ) Is coupled, then the first ring portion 31b is inserted. Alternatively, after the second ring portion 32b is inserted into the first ring portion 31b, the first U bolt 31c and the second U bolt 32c are sequentially coupled.

On the other hand, the first ring portion 31b formed at both ends of the first connecting means 31 are coupled to each other, the second ring portion of the second connecting means 32 to any one of the first ring portion 31b 32b may be combined. Alternatively, the second ring portion 32b of the second connecting means 32 may be simultaneously coupled to the first ring portion 32b of both ends.

The first connecting means 31 and the second connecting means 32 combine adjacent tetrapods 20 to increase the binding force. Accordingly, the tetrapod binding system 10 can prevent the loss of the tetrapod 20 and maintain the installation state.

The following describes a tetrapod binding system 40 according to another embodiment of the present invention.

4 is an enlarged view of a tetrapod binding system according to another embodiment of the present invention.

The tetrapod binding system 40 according to another embodiment of the invention comprises a tetrapod 20 and a connecting means 50. The tetrapod binding system 40 of another embodiment of the present invention uses the same reference numerals as the tetrapod 20 is formed identically to the tetrapod 20 of one embodiment according to FIGS. 1 to 3, and the detailed description thereof will be omitted.

The connecting means 50 is formed including a single rope body portion 50a, a first knot portion 50b and a second knot portion 50c. The connecting means 50 combines adjacent tetrapods 20 with each other to increase binding force.

The single rope body portion 50a is used as a general rope having rigidity, and may be formed to have an appropriate length and thickness according to the size of the tetrapod 20 or the required rigidity. The single rope body portion 50a may have a different length depending on the distance between adjacent tetrapods 20.

One side of the single rope body portion 50a surrounds any one of the first leg portion, the second leg portion, the third leg portion and the fourth leg portion 20a, 20b, 20c, and 20d of the tetrapod 20. The other side surrounds any one of the first leg, the second leg, the third leg, and the fourth leg 20a, 20b, 20c, and 20d of the adjacent tetrapod 20. In addition, the single rope body portion 50a is positioned between the tetrapods 20 adjacent to each other with a central portion between one side portion and the other side portion. Therefore, the single rope body portion 50a surrounds the leg portions 20a, 20b, 20c, and 20d of the tetrapod 20 on one side and forms a ring on one side, and the leg portion 20a of the adjacent tetrapod 20 on the other side. , 20b, 20c, 20d) to surround the other side to form a ring, the central portion is to connect the ring. Thus, the single rope body portion 50a binds to each other while surrounding the tetrapods 20 adjacent to each other.

The central portion of the single rope body portion 50a preferably extends from the center of the leg portions 20a, 20b, 20c, 20d of the tetrapod 20 that one side or the other portion of the single rope body portion 50a wraps. It is formed to have an obtuse angle with the direction. That is, when one side portion of the tetrapod 20 surrounds the leg portions 20a, 20b, 20c, and 20d extending in any one direction, the central portion of the single rope body portion 50a is the leg portions 20a, 20b, 20c and 20d) to form an angle of 90 degrees or more. For example, in FIG. 4, the central portion of the single rope main body forms an obtuse angle with the extending direction of 20a, the leg of the tetrapod 20 located on the left side. In this case, it is minimized that the ring portion of the single rope body portion 50a is peeled off from the legs 20a, 20b, 20c, 20d of the tetrapod 20.

On the other hand, the single rope body portion 50a is similar to the configuration in which the first rope body portion 31a and the second rope body portion 32a of the embodiment of FIGS. 1 to 3 are integrally formed.

The first knot 50b has a single rope main body 50a enclosing the leg of the tetrapod 20, and one side end of the single rope main body 50a is one side of the single rope main body 50a or It is formed while binding to the center part. That is, the first knot portion 50b is formed in a ring portion formed by the single rope body portion 50a surrounding the leg portions 20a, 20b, 20c, and 20d. The first knot 50b is formed while the one end of the single rope body 50a is bundled at least once. The first knot 50b may be formed by various knot methods that are generally used to bind ropes.

The second knot 50c surrounds the leg portions 20a, 20b, 20c, and 20d of the adjacent tetrapod 20, and the other end of the single rope body portion 50a of the single rope body portion 50a. It is formed while binding to the other side or the center. That is, the second knot portion 50c may be formed in substantially the same manner except that the second knot portion 50c is formed at a position different from that of the first knot portion 50b. In addition, the second knot portion 50c may have a knot formed in a different manner from the first knot portion 50b.

It is apparent to those skilled in the art that the present invention is not limited to the above embodiments and may be variously modified and modified without departing from the technical spirit of the present invention. It is.

10, 40: tetrapod binding system 20: tetrapod
20a: first leg 20b: second leg
20c: third leg 20d: fourth leg
30, 50: connection means
31: first connecting means 31a: first rope body portion
31b: first ring portion 31c: first U bolt
32: second connecting means 32a: second rope body portion
32b: 2nd ring part 32c: 2nd U bolt
50a: single rope body 50b: first knot
50c: second knot

Claims (5)

A tetrapod comprising a first leg portion, a second leg portion, a third leg portion, and a fourth leg portion radially formed in four directions from the central portion; And
It comprises a connecting means coupled to the tetrapod,
The connecting means
U-shaped first rope main body portion, at least one end portion and the other end portion of the tetrapod surrounding the at least one of the central portion, the first leg portion, the second leg portion, the third leg portion and the fourth leg portion, respectively. First connecting means having a first ring portion bent and formed with a first U bolt coupled to the first ring portion;
A second loop portion and a second loop portion coupled to the first loop portion are formed by bending a second rope body portion and one end portion and the other end portion of the second rope body portion that cross each other between the tetrapods and the first ring portion. A second connecting means having a second U bolt coupled to the
The first leg portion, the second leg portion, the third leg portion and the fourth leg portion is formed so that the diameter becomes smaller toward the outside from the center of the tetrapod,
The second rope body portion is formed so as to form an obtuse angle with an extension direction of any one leg portion of the first leg portion, the second leg portion, the third leg portion and the fourth leg portion wrapped around the first rope body portion. Tetrapod binding system. delete delete delete delete

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