KR101479684B1 - Structure for Supporting Tetrapod for Breakwater and Method for Manufacturing and Construction its - Google Patents

Abstract

The present invention relates to a support structure for preventing a tetrapod provided on a breakwater or the like from breaking or being lost by waves. The support structure includes a plurality of fixing holes formed on left and right sides in a columnar shape of a hexahedron, A support block arranged in contact; A fixing member having a lower portion coupled to the fixing hole formed in the support block and having a through hole formed in the upper portion thereof; A first wire rope connected to the through hole formed in the fixing member to fix a plurality of support blocks arranged; A lattice mesh coupled between the support block and the first wire rope; A second wire rope horizontally coupled to the lattice network at regular intervals; And an anchor rope having one end fixed to the first wire rope or the second wire rope and an anchor coupled to the other end. In the present invention, the arrangement of a plurality of support blocks made of a waste concrete tie used in a railway, the support structure of a grid network and a fixed connection of wire ropes can be simplified and simplified in construction and in manufacturing cost, It prevents the scattering of tetrapods and stones placed around the breakwater by waves such as tides and waves, typhoons and storms, minimizes the damage or loss of the tetrapods, and minimizes the loss of the breakwaters by tetrapods or stones.

Description

Technical Field [0001] The present invention relates to a tetrapod support structure for a breakwater, a structure for supporting the same,

The present invention relates to a structure for supporting a tetrapod for a breakwater, and more particularly, to a support structure for preventing a tetrapod formed on a breakwater or the like from breaking or being lost by a wave, and a method of making and constructing the same.

Generally, a revetment is a structure that is installed on the slope to protect the underpass, the coast or the dam, and to prevent the erosion of the water line by the runoff. Generally, water provider construction will be followed by the water supplier. It is divided into 3 types according to the construction site: the embankment, the low guard, and the flood waters. The name of each part of the revetment is not uniform, but the standard structure is slope cover, bottom protection It is composed of three kinds of balls.

It is a structure that protects the inner harbor by blocking the waves from the outer sea in addition to the above sea shore. Artificial harbor usually requires a breakwater. A variety of breakwaters have been built using stone or concrete to give breakwaters. Breakwaters are located according to various conditions. In other words, when the wave is placed at right angles to the direction in which the wave progresses, a wide area becomes warm with a short extension. If it is inclined a little more than a right angle, the wave impact on the breakwater becomes very weak. In sandy beaches, sand breaks into deep water to build up a breakwater to prevent sediment sedimentation. If you build a breakwater along a shallow place, the construction cost is low. When the harbor is too close to the shore, the ship collides with the shore. When the ship is passing through the port, it needs to pass 800 to 1,000 meters to the shore because it has to pass at a high speed so as not to zigzag. When the weather is bad, there should be enough inner space to accommodate all vessels under 10,000 tons. In addition, the installation condition of the breakwaters should not be directed toward the direction in which the waves travel. Make sure the ship is facing the easy access. The width is narrowed so that the ship can pass safely. Usually, the length of the ship is about the same. The entrance to the harbor is somewhat deeper because it occurs more blue than the harbor. When the breakwater comes in a long wave, it causes rapid flow and the port entrance becomes rough.

Moreover, as a method of installing breakwaters, the upright agent is a block of concrete standing upright from below, which prevents the wave well, but when the ground is weak, it may settle down or scrape the foundation. It is generally suitable for a small scale such as an aquarium. In addition, the inclining agent is a pile of stones or tetrapods. It is also built in weak grounds, which requires a lot of material in deep places, which is uneconomical. In addition, the hybrid agent is an upright agent placed on a slope agent and has been widely adopted in the country because it has both advantages of slope agent and uprightness.

Generally, most of the breakwater is surrounded by tetrapods. Ted La Pod is a concrete type block used instead of a clay stone for a blue sofa. It is made of four horns and is used in breakwaters and seawalls to weaken blue energy. This concrete deformation block is a rough surface and it has good permeability, so it can reduce the energy of wave by reducing wave pressure, wave rising and reflection wave, and blocks can be installed at sloped slopes with stable steep slopes. And it is possible to lighten the weight of the block compared to the concrete block because the center position of the block is low and stability is good, and there is no special care in construction.

However, the tetrapod installed around the breakwater has a problem in that it can withstand normal wave, but it is scattered by wave caused by strong wind such as a typhoon, and is lost or damaged, so that normal function can not be obtained.

In the prior art relating to the present invention, the seawall prevention facility of the breakwater of Korean Patent Laid-Open Publication No. 10-2001-0017964 is characterized in that, in constructing the seaweed breakwater (1) on the coast, the stones (2) (2) and the bulkhead stone (11) having a size and volume much larger than the size of the stones (2) is bundled with one end of the chain (10) The upper surface of the coated stone 3 which is covered with the coated stone 3 in a planar manner on the inclined surface of the inclined stone so as to be exposed on the upper surface of the coated stone 3 covering the surface of the inclined surface of the inclined stone is fixed in the transverse and longitudinal chains 10a, It is disclosed that a portion 12 is formed and the binding portion 12 and the tip of the chain 10 exposed on the upper surface of the coated stone 3 are bound together. This is a disadvantage in that the construction method is complicated and the construction cost is high, such as binding the clay stones to the stones by chains, and binding the stones to the stones by chains.

In addition, as a prior art, Korean Patent Laid-Open Publication No. 10-2001-0102652 discloses a facility for preventing the breakage of a temporary break head, which is a facility for preventing the collapse and loss of a breakwater toe (H) A soap block 11a (11a) (11a) is formed on the top, bottom, front and back sides of the inclined surface 10 of the head portion of the head so as to cover the slope of the breakwater head H A small metal chain 12 is tightly laid between the sofa blocks 11, 11a, 11b and 11c so as to be vertically and horizontally arranged in the space between the sofa blocks 11a, 11b and 11c, And the large metal chain 13 is overlapped on the upper end of the small metal chain 12 and the leading end of the small metal chain 13 is fixed to the sofa blocks 11 and 11c by double- And a plurality of relatively large rocks (14), which are purchased in the slag form of the breakwater (WB) Withdrawing a leading end of the other chain (15) out of the riprap embankment discloses the connection where a plurality of large metal chain 13. This is disadvantageous in that the construction method is complicated and the construction cost is high because the clay stones are bound to the stones by chains, the stones are bundled between the stones and the stones, and the plurality of sofa blocks are installed with metal chains on the upper and lower sides .

In addition, as a conventional technique, a coastal structure using the Tetrapod cape of Korean Patent Registration No. 10-0760950, a method of manufacturing the same, and a construction method using the coastal structure manufactured by the method are used as a countermeasure against natural disasters In a coastal structure such as tetrapod to be installed, a wire net having a predetermined size and shape for loading the tetrapod is formed, and the wire net is formed of a wire to bear the weight of the loaded tetrapod, Discloses that a piano steel wire, which is constructed to be opposite to a wire, is installed to increase the tensile strength against the wire mesh. This is disadvantageous in that it is difficult to move and install the wire netting together with the loading and fixing of the tetrahedron in the wire netting by installing tetrapods in a roughly triangular prismatic net.

In addition, as a conventional technique, a sofa structure construction method using a grout bag and a double layer of a tetrafold in Korean Patent Laid-Open Publication No. 10-2013-0021556 includes a step of laminating tetrapods composed of members having four legs into a plurality of layers , Three of the four legs of the tetrapod extend in the transverse direction, and a plurality of first layer tetrapods 10 are arranged in the lateral direction in such a manner that the ends thereof contact the mounting surface and the remaining one leg vertically upward ; And the plurality of second layer tetrapods 20 are lifted respectively so that the second layer tetrapod 20 is supported by the three legs of the first layer tetrapod 10 between the plurality of first layer tetrapods 10. [ And inserting between the first layer tetrapods (10) so that three of the four legs of the second layer tetrapod (20) extend in the transverse direction and the remaining one leg is arranged in the vertically upward direction By a process comprising; Discloses that a sofa structure is constructed by laminating tetrapods into a plurality of layers. This has disadvantages in that it is troublesome and costly to construct grooves in each of the tetrapod legs and to connect grout bags between the tetrapod leg recesses.

As a result, the prior arts have a problem in that the construction cost increases due to a complicated construction process and fear of damage or loss due to wave energy.

Korean Patent Publication No. 10-2001-0017964 (published on Mar. 5, 2001) Korean Patent Publication No. 10-2001-0102652 (published on November 16, 2001) Korean Registered Patent No. 10-0760950 (published on September 21, 2007) Korean Patent Publication No. 10-2013-0021556 (published on Mar. 03, 2013)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a support structure so that a plurality of tetrapods adjacent to a breakwater do not flow, so that they are not easily broken or lost by wave energy.

Another object of the present invention is to provide a simple structure for installation and construction by mounting a support structure on a tetrapod loaded on a breakwater and fixing the support structure on the floor with an anchor connected to the support structure by wire.

In order to achieve the above object, the present invention provides a tetrapod support structure for a breakwater, comprising: a support having a plurality of fixing holes formed on left and right sides in a pillar shape of a hexahedron, block; A fixing member having a lower portion coupled to the fixing hole formed in the support block and having a through hole formed in the upper portion thereof; A first wire rope connected to the through hole formed in the fixing member to fix a plurality of support blocks arranged; A lattice mesh coupled between the support block and the first wire rope; A second wire rope horizontally coupled to the lattice network at regular intervals; And an anchor rope having one end fixed to the first wire rope or the second wire rope, and an anchor coupled to the other end. The present invention provides a support structure for a breakwater.

Further, in the present invention, the support block includes a first support block positioned on the left side, a second support block positioned on the right side at a predetermined distance from the first support block, A first support block assembly having a first support block, a second support block, and a third support block, wherein the first support block, the second support block, and the third support block are alternately arranged vertically; And a fourth support block disposed on the left side of the support block, and a fifth support block positioned under the fourth support block, wherein the fourth support block and the fifth support block are arranged alternately up and down, A first support block assembly and a second support block assembly may be pro-connected to the lattice network and the second wire at a predetermined distance.

In addition, in the present invention, the lattice network can be coupled on the first support block assembly, on the second support block assembly, and between the first support block assembly and the second support block assembly, respectively.

In addition, in the present invention, the one side of the anchor rope is connected to the first wire rope or the second wire rope at right angles, and may be fixed with a plurality of clips.

In addition, in the present invention, the second wire rope is connected at regular intervals across the first wire rope and is wrapped at a right angle to the first wire rope, and can be fixed with a plurality of clips.

According to the present invention, the arrangement of a plurality of support blocks made of waste concrete sleeper used in a railway track, the support structure of a grid and a wire rope fixedly combined with each other can simplify the assembly structure, simplify the construction and reduce the manufacturing cost, It is possible to prevent the scattering of tetrapods or stones placed around the breakwater by wave or waves due to ordinary tides or waves, typhoons or storms, minimize the damage or loss of the tetrapods, and minimize the loss of the breakwaters due to tetrapods or stones There is an advantage.

1 is a plan view showing a tetrapod support structure for a breakwater according to an embodiment of the present invention.
2 is a perspective view showing a tetrapod support structure for a breakwater according to the present invention.
3 is a cross-sectional view showing a tetrapod support structure for a breakwater according to the present invention.
4 is a perspective view showing the construction of a support structure on a detarget for a breakwater according to the present invention.
5 is a flowchart illustrating a method for fixing and supporting tetrapod using a tetrapod support structure for a breakwater according to the present invention.

Hereinafter, embodiments of a tetrapod support structure for a breakwater according to the present invention will be described in detail with reference to the accompanying drawings.

1 and 2, the support block 10 is in the shape of a hexagonal column. The support block 10 is a concrete structure with a reinforcing bar embedded therein, and can be applied to a concrete concrete sleeping rail used for a railway support. The support block 10 has a plurality of fixing holes 16 formed on the left and right sides thereof. In other words, a pair of fixing holes 16 are formed in the left side portion and the right side portion of the support block 10. The support blocks 10 are arranged at regular intervals in the left and right as viewed in a plan view. And the support block 10 is arranged in contact with the upper and lower surfaces in a plan view.

More specifically, the support block 10 is arranged in two ways. That is, the support block 10 can be divided into a first support block assembly 100 and a second support block assembly 200. The first support block assembly 100 includes a first support block 11 positioned on the left side, a second support block 12 positioned on the right side at a predetermined distance from the first support block, And a third support block 13 positioned in contact with the second support block 12. The first support block assembly 100 includes a first support rope 30 and a second support rope 30 so that the first support block 11, the second support block 12, and the third support block 13 arranged in the left- ). The fixing hole 16 formed on the right side of the first supporting block 11 and the fixing hole formed on the left side of the third supporting block 13 are fixedly coupled with the first wire rope 30 so as to be aligned with each other, The fixing hole 16 formed on the left side of the block 12 and the fixing hole 16 formed on the right side of the third supporting block 13 are fixedly coupled with the first wire rope 30 so as to be positioned in a straight line. The fixing hole 16 formed on the left side of the first supporting block 11 and the fixing hole 16 formed on the left side of the first supporting block 11 arranged again across the third supporting block 13, And is fixed to the right side of the second support block 12 which is fixedly connected to the rope 30 and is arranged rearwardly with the fixing hole 16 formed on the right side of the second support block 12 and the third support block 13. [ Hole 16 and the first wire rope 30, respectively.

In addition, the second support block assembly 200 is provided with a fourth support block 14 positioned on the left side and a fifth support block 15 positioned in contact with the fourth support block. And the fourth support block 14 and the fifth support block 15 are fixedly coupled with the first wire rope 30 so as to be arranged alternately up and down. The fixing hole 16 formed on the right side of the fourth supporting block 14 and the fixing hole 16 formed on the left side of the fifth supporting block 15 are fixedly coupled with the first wire rope 30 so as to be aligned with each other . A fixing hole 16 formed on the left side of the fourth supporting block 14 and a fixing hole 16 formed on the left side of the fourth supporting block 14 arranged rearranging the fifth supporting block 15, And is fixed to the right side of the fifth support block 15 which is fixedly connected to the fifth support block 15 by the rope 30 and is arranged rearwardly with the fixing hole 16 formed on the right side of the fifth support block 15 and the fourth support block 14. [ Hole 16 and the first wire rope 30, respectively.

The fixing member 17 is formed with a through hole 18 which is coupled to the fixing hole 16 formed in the support block 10 at the lower portion and penetrates the upper portion. That is, the lower portion of the fixing member 17 is fixed to the support block 10, and a through hole 18 is formed in the exposed upper portion. The fixing member 17 can be engaged with and detached from the fixing hole 16. For example, the fixing member 17 may be composed of bolts and nuts and may be fastened to the through holes of the support block 10.

The first wire rope 30 is integrally fixed to a plurality of support blocks 10 which are inserted through a through hole 18 formed in the fixing member 17 and are arranged in a plurality. That is, the through holes 18 of the fixing member 17 coupled to the fixing holes 16 of the support block 10 arranged in the left-right and up-and-down directions on the plane, to integrally fix the plurality of support blocks 10 . The first wire rope 30 integrally fixedly connects the first support block 11, the second support block 12 and the third support block 13 and the first wire rope 30 integrally secures the fourth wire rope 30, And the support block 14 and the fifth support block 15 are integrally fixed to each other.

3, the lattice network 20 is coupled between the plurality of support blocks 10 and the first wire rope 30. The lattice nets 20 may be woven into a certain mesh and shape, that is, a square structure or a honeycomb structure having a predetermined rigidity. The first grating mesh 21 is coupled to the first support block assembly 100 as the grating mesh 20 and the second grating mesh 22 is coupled to the second support block assembly 200, A third mesh network 23 is coupled between the block assembly 100 and the second support block assembly 200.

It is further contemplated that a pair of first support block assemblies 100 may be disposed on either side of the third grid grid 23 or a pair of second support block assemblies 200 may be disposed between the third grid grid 23 And the first support block assembly 100 and the second support block assembly 200 may be selectively disposed on both sides of the third mesh network 23.

The first support block assembly 100 and the second support block assembly 200 are connected to each other by a third wire mesh 23 and a second wire rope 31 at a predetermined distance.

The second wire rope 31 is laterally joined to the grid 20 at regular intervals. That is, the second wire rope 31 connects the first support block assembly 100 and the second support block assembly 200 in the transverse direction and prevents deformation with the support of the lattice nets 20, To provide lateral rigidity to the structure.

The anchor rope 32 has one end fixed to the first wire rope 30 or the second wire rope 31 and the anchor 34 or anchor connected to the other end. The anchor 34 is not fixed to a separate fixing means on the seabed so that it can be fixed arbitrarily. The anchor 34 is formed with projections such as hooks in approximately four directions so that it can be easily caught on the rough surface of the seabed or the reef. Thus, the anchor 34 coupled to the ends of the anchor ropes 32 connected in plurality to the support structure provides the function of tightly securing the support structure.

One side of the anchor rope (32) is connected to the first wire rope (30) or the second wire rope (31) at right angles and fixed by a plurality of clips (33). The second wire rope 31 is connected at regular intervals across the first wire rope 30 and is wrapped around the first wire rope 30 at right angles and fixed with a plurality of clips 33. The clip 33 is intended to rotate around the first wire rope 30 and the second wire rope 31 to securely fasten the anchored rope 32.

The construction of the tetrapod support structure for the breakwater of the present invention and the construction method for fixing and supporting the tetrapod using the support structure will be described with reference to a perspective view showing the construction of FIG. 4 and a flowchart of FIG.

4, first, the supporting structure of the present invention minimizes the flow of the trough 2, the stones, etc. installed on the shore, especially the surface of the breakwater 1, so as to minimize breakage or loss due to the wave, The support structure is installed so as to be covered on the tetrapod 2. In this case,

In FIG. 5, a plurality of support blocks 10 must be prepared in order to manufacture the support structure 300 of the present invention (S10). The support block (10) can be made into a rectangular columnar shape or a trapezoidal shape by using reinforcing bars and concrete, or can utilize a waste concrete railroad tie which was previously used for railway. Waste concrete sleepers used for railway had difficulties in disposal. In the present invention, it is preferable to recycle waste concrete treads, but it may be manufactured in various sizes and shapes as needed.

The support structure 300 includes a first support block assembly 100 coupled to one side and a second support block assembly 200 coupled to the other side. That is, the first support block assembly 100 includes the first support block 11 and the second support block 12 arranged at regular intervals, and the first support block 11 and the second support block 12 The third support block 13 is brought into contact with and disposed (S11). The first support block 11 and the second support block 12 are disposed at regular intervals below the third support block 13. At this time, the fixing hole 16 formed on the right side of the first supporting block 11 is fixed on the left side of the second supporting block 12 with the fixing hole 16 formed on the left side of the third supporting block 13 aligned. And the fixing hole 16 formed on the right side of the third supporting block 13 is positioned in a straight line. The first support block 11 and the third support block 13 are disposed under the first support block 11 and the second support block 12 so that they are alternately arranged.

When the first support block 11, the second support block 12, and the third support block 13 are alternately arranged, the first grating mesh 21 is placed thereon (S12). Then, the fixing member 17 is engaged with each fixing hole 16 of the first supporting block 11, the second supporting block 12 and the third supporting block 13. At this time, the fixing member 17 may be already fixed to the fixing hole 16 of each support block 10. The first wire rope 30 is inserted into the through hole 18 formed in the upper portion of each fixing member 17 (S13). The first wire rope 30 is connected to the fixing members 17 fixed in the vertical direction, that is, on the left side of the first supporting block 11 in a line, and fixed to the right side of the second supporting block 12, And the fixing member 17 fixed to the left side of the third supporting block 13 are connected in a line and the fixing member 17 fixed to the left side of the second supporting block 12 and the fixing member 17 fixed to the right side of the third supporting block 13 And the fixing members 17 fixed to the right side of the second support block 12 are connected in a line. Therefore, the first lattice net 21 is fixedly coupled to the first support rope 30 on the first support block 11, the second support block 12, and the third support block 13.

In addition, the second support block assembly 200 contacts and arranges the fifth support block 15 under the fourth support block 14 (S14). At this time, the fixing hole 16 formed on the right side of the fourth support block 14 is positioned in a straight line with the fixing hole 16 formed on the left side of the fifth support block 15. In this way, the fifth support block 15 is arranged under the fourth support block 14 so that the fifth support block 15 is alternately arranged.

When the fourth support block 14 and the fifth support block 15 are alternately arranged, the second grid 22 is placed thereon (S15). Then, the fixing member 17 is engaged with the fixing holes 16 of the fourth support block 14 and the fifth support block 15. At this time, the fixing member 17 may be already fixed to the fixing hole 16 of each support block 10. The first wire rope 30 is inserted into the through hole 18 formed in the upper portion of each fixing member 17 (S16). The first wire rope 30 connects the fixing members 17 fixed in the vertical direction, that is, on the left side of the fourth supporting block 14 in a line, and the fixing member 17 fixed to the right side of the fourth supporting block 14 And the fixing members 17 fixed to the left side of the fifth supporting block 15 are connected in a line and the fixing members 17 fixed to the right side of the fifth supporting block 15 are connected in a line. The second grid 22 is fixedly connected to the first wire rope 30 on the fourth support block 14 and the fifth support block 15. [

The fixing member 17 fixed to the right side of the second supporting block 12 with the third grating 23 between the first supporting block assembly 100 and the second supporting block assembly 200 is provided with a first wire The first wire rope 30 is engaged with the fixing member 17 fixed to the left of the fourth support block 14 in step S17. The first support block assembly 100 and the second support block assembly 200 are fixedly coupled with the first and second lattice nets 21 and 22 and the first and second support block assemblies 100 and 200, The third grating network 23 may be fixedly coupled between the second support block assembly 200 or the first support block assembly 100 and the second support block assembly 200 and the first support block assembly 100 A single lattice network may be fixedly connected to each first wire rope 30 over the entire area including between the second support block assemblies 200. [

In addition, the lattice nets 20 may be fixedly coupled between the first support block assembly 100 and the second support block assembly 200 without a gap. This is achieved by arranging the first support block 11, the second support block 12 and the third support block 13 in the same manner as the arrangement of the first support block 11, the second support block 12 and the third support block 13 and then fixing the grid net 20 to the first wire rope 30 It will be able to combine.

After the first support block assembly 100 and the second support block assembly 200 and the lattice nets 20 are fixedly coupled to the first wire rope 30, The two-wire rope 31 is fixedly engaged (S18). The second wire rope 31 may be used to securely support the tetrapod 2 or the stones by the third lattice nets 23 between the first and second support block assemblies 100, will be.

When the first support block assembly 100 and the second support block assembly 200 and the lattice nets 20 and the like are integrally manufactured, the first wire rope 30 and / The anchor rope 32 is wound on one side and fixedly engaged with the plurality of clips 33 (S19). The anchor rope 32 has a predetermined length and an anchor 34 is coupled to the end.

Thus, assembly and fabrication of the tetrapod support structure are completed (S20). When the tetrapod 2 or the stones are installed around the breakwater 1 with a predetermined length and width, the support structure is covered with the support structure 300 (S21). Furthermore, the support structure 300 may be covered on the tetrapod 2 or the stones already installed around the breakwater 1.

After the support structure 300 is covered on the tetrapod 2 or the stones, the anchors 34 connected to the support structure 300 by the plurality of anchor ropes 32 are thrown on the sea floor (S22). At this time, the anchor 34 may be fixed to the detritus 2 or the supporting structure 300 on the breakwater 1, not on the sea floor. Therefore, the anchor 34 is fixed to the seabed surface by the flow of the tide or the wave. The anchor 34 will have a greater force to secure the support structure 300 when a larger weight is applied.

The weight of the integrally assembled first and second support block assemblies 100 and 200 and the mesh of the lattice nets 20 and the second wire ropes 31, Will act like one unit structure.

Therefore, the supporting structure of the present invention is simple in structure, simple construction, and reduced in manufacturing cost, and it is also possible to prevent the formation of tetrapods or stones scattered around the breakwater due to wave or wave caused by ordinary tides, And minimizes the breakage or loss of the tetrapods and minimizes the loss of the breakwaters due to tetrapods or stones.

While the invention has been shown and described with respect to the specific 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 as defined by the appended claims. Anyone who has it will know it easily.

1: Breakwater 2: Tetrafford 10: Support block 11: First support block 12: Second support block 13: Third support block 14: Fourth support block 15: Fifth support block 16: Fixing hole 17: Fixing member 18: A first wire rope 31, a second wire rope 32, an anchor rope 33, a clip 34, an anchor 100, a first support member 30, a second support member 30, Block assembly 200: second support block assembly 300: support structure

Claims (7)

In a tetrapod support structure for a breakwater,
A support block in which a plurality of fixing holes are formed on left and right sides in a pillar shape of a hexahedron, arranged at regular intervals in a left and right direction on a plane,
A fixing member having a lower portion coupled to the fixing hole formed in the support block and having a through hole formed in the upper portion thereof;
A first wire rope connected to the through hole formed in the fixing member to fix a plurality of support blocks arranged;
A lattice mesh coupled between the support block and the first wire rope;
A second wire rope horizontally coupled to the lattice network at regular intervals; And
And an anchor rope having one end fixed to the first wire rope or the second wire rope and an anchor connected to the other end,
The support block includes a first support block positioned on the left side, a second support block positioned on the right side at a predetermined distance from the first support block, and a second support block positioned below the first support block and the second support block, A first support block assembly having a first support block, a first support block, a second support block, and a third support block, the first support block assembly being pro-fixedly coupled to the first wire such that the first support block, the second support block, and the third support block are arranged alternately up and down; And
The support block includes a fourth support block located on the left side and a fifth support block positioned below the fourth support block, and the fourth support block and the fifth support block are alternately arranged vertically, A second support block assembly is constructed to be pro-
Wherein the first support block assembly and the second support block assembly are projacently coupled to the lattice network and the second wire at a predetermined distance.
delete 2. The tetrapod support structure of claim 1, wherein the support block comprises a waste concrete tread for railways.
2. The tetrapod support structure of claim 1, wherein the lattice network is coupled between a first support block assembly, a second support block assembly, and a first support block assembly and a second support block assembly, respectively.
[2] The tetrapod support structure for a breakwater according to claim 1, wherein one side of the anchor rope is connected to the first wire rope or the second wire rope at right angles and is fixed with a plurality of clips.
2. The tetrapod support structure for a breakwater according to claim 1, wherein the second wire rope is connected at regular intervals across the first wire rope and is wrapped at a right angle to the first wire rope and secured with a plurality of clips.
A method of manufacturing and constructing a tetrapod support structure for a breakwater,
(a) preparing a plurality of support blocks;
(b) arranging the second support block at a predetermined distance on the right side of the first support block when viewed in plan, placing the third support block in contact with the first support block under the second support block, The first support block and the second support block are brought into contact with each other at a predetermined distance below the support block so that the fixation member fixedly coupled to the right side of the first support block and the fixation member fixedly coupled to the left side plane of the third support block, And a fixing member fixedly coupled to the left side flat surface of the second support block and a fixing member fixedly coupled to the right side flat surface of the third support block are arranged so as to be aligned with each other and arranged under the first support block and the second support block After the third support blocks are arranged alternately up and down, the first grating network is extended from the first support block to the fixed member fixedly coupled to the left-hand side of the first support block and the fixed member fixedly coupled to the right- 3 above the support block Forming first support block assemblies by connecting first and second wires to the fixing members fixedly coupled to the right and left sides of the first to third support blocks, respectively;
(c) placing the fourth support block in contact with the fourth support block at the lower right side of the fourth support block, placing the fourth support block in contact with the fourth support block at a predetermined distance from the left side of the fifth support block, A fixing member fixedly coupled to the block right side plane and a fixing member fixedly coupled to the left side flat surface of the fifth support block are arranged so as to be aligned with each other and the fifth support blocks are arranged alternately up and down below the right side of the fourth support block, 2 grating network is installed so as to cover the fourth support block and the fifth support block together with the fixing member fixedly coupled to the left side plane of the fourth support block and the fixing member fixedly coupled to the right side plane of the fifth support block, Forming a second support block assembly by connecting the second wire rods to the fixing member fixedly coupled to the right side of the fourth support block and the left side of the fifth support block, respectively;
(d) installing a third grid between the first support block assembly and the second support block assembly and passing a second wire rope across the first wire rope coupled to the first support block assembly and the second support block assembly, Connecting and combining;
(e) assembling an anchor rope having an anchor coupled to the first wire rope or the second wire rope to manufacture a supporting structure; And
(f) installing the support structure on a plurality of tetrapods provided around the breakwater, and throwing an anchor connected to the anchor rope on the seabed.

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