KR102435451B1 - Retaining wall having raker and construction method thereof - Google Patents

Abstract

The present invention relates to a retaining structure installed to surround the excavation area (1) formed by the excavation, the retaining wall (10); The upper end is coupled to the upper portion of the retaining wall (10), the lower end is installed inclined downwardly to the bottom of the excavation area (1) raker member (100); Coupled to the central portion of the raker member 100 to resist the soaring of the raker member 100, spaced apart from the retaining wall 10 inwardly and installed along the vertical direction, the lower end of the excavation area (1) Tensile reinforcement member 200 buried in the bottom of the; One end is coupled to the central portion of the retaining wall 10, and the other end is inclined or installed along the horizontal direction to be coupled to the raker member 100 or the tension reinforcing member 200; By presenting the retaining structure with the characteristic raker reinforcement structure, construction is easy, material saving and recycling are possible, slab reinforcement work of underground structures, waterproofing work, etc. are easy, and the possibility of occurrence of defects is small. , to facilitate excavation work by securing a working space in the vicinity of the lower part of the retaining structure.

Description

Retaining structure having a raker reinforcement structure and its construction method

The present invention relates to the field of construction, and more particularly, to a retaining structure having a raker reinforcement structure and a construction method thereof.

The retaining structure means a temporary structure or a permanent structure installed to surround the excavation area 1 formed by excavation for underground construction, and there are thumb pile earth plate construction method, C.I.P. construction method, S.C.W. construction method, and the like.

When the depth of excavation increases, reinforcing structures such as earth anchors, rakers, and struts are installed in order to increase the resistance of the retaining structure to earth pressure.

The earth anchor has the advantage that it has little effect on the excavation area 1 formed by the excavation, but when the construction of the earth anchor is impossible due to the surrounding structures, rakers, struts, etc. are inevitably installed, which are formed by the excavation. There is a problem in that it is exposed to the excavation area (1) to be used and affects the work.

1 and 2 are schematic diagrams of a conventional raker method.

In order to support the retaining structure 10, the raker member 20 is installed inclinedly, the upper end of the raker member 20 is coupled to the retaining structure 10, and the lower end is a support block (kicker block) 40 by is supported

When the depth of excavation is further increased, a plurality of raker members 21 and 22 are installed so as to be supported by one support block 40 and have different inclinations from each other, and additionally by another support block 41 Another supported raker member 23 is also installed.

When working with the slab 60 of the underground structure, a plurality of block-out parts 61 should be formed in the section where the plurality of raker members 21 and 22 and the conflicting section occur, and the floor slab 70 and the support block ( 40 and 41), there is also a conflict (Fig. 2).

This conventional raker method has the following problems.

First, the raker member installed at an angle should form a plurality of block-out parts 61 due to the collision during the slab operation of the underground structure, and a part of the raker member is buried in the slab, and the remaining exposed parts must be cut. , construction is difficult, material waste is large, and material recycling is impossible.

Second, since the raker member installed inclinedly conflicts with the installation position of the slab of the underground structure, it is difficult to support the slab, waterproof work, etc., and the possibility of occurrence of defects is high.

Third, a structure in which a plurality of raker members 21 and 22 are supported on one support block 40 and a structure in which a plurality of support blocks 40 and 41 are installed increases the contact area with the floor slab 70, It adversely affects the workability, structural stability, and waterproofing performance of the floor slab.

Fourth, as the number of installed raker members increases, the working space of the adjacent part of the lower part of the retaining structure becomes narrower, so that the excavation operation becomes difficult.

Reference numerals in the prior art are limited only to the description of the prior art.

The present invention was derived in order to solve the above problems, and it is easy to construct, it is possible to save and recycle materials, and it is easy to install a slab of an underground structure, a waterproofing work, etc., and the possibility of occurrence of defects is small. The purpose of the present invention is to present a retaining structure having a raker-reinforced structure that secures a working space in the vicinity of the lower part of the retaining structure and facilitates excavation work, and a construction method thereof.

In order to solve the above problems, the present invention is a retaining structure installed to surround the excavation area (1) formed by the excavation, retaining wall (10); The upper end is coupled to the upper portion of the retaining wall (10), the lower end of the raker member (100) is installed inclined downwardly to be coupled to the bottom of the excavation area (1); It is coupled to the central portion of the raker member 100 to resist the soaring of the raker member 100, and is spaced apart from the retaining wall 10 inwardly and installed along the vertical direction, the lower end of the excavation area (1) Tensile reinforcement member 200 buried in the bottom of the; One end is coupled to the central portion of the retaining wall 10, and the other end is inclined or installed along the horizontal direction to be coupled to the raker member 100 or the tension reinforcing member 200; Presents a retaining structure having a raker reinforcement structure characterized in that.

The inclination of the intermediate reinforcing member 300 is preferably smaller than the inclination of the raker member 100 .

The inclination of the intermediate reinforcing member 300 is preferably in the opposite direction to the inclination of the raker member 100 .

The tensile reinforcing member 200 includes an outer tensile reinforcing member 200a and an inner tensile reinforcing member 200b installed to be spaced apart from each other, and the intermediate reinforcing member 300 has one end at the center of the retaining wall 10 . An upper intermediate reinforcing member (300a) coupled to the upper portion and installed along the horizontal direction so that the other end is coupled to the raker member (100) or the outer tension reinforcing member (200a); One end is coupled to the lower center of the retaining wall 10, and the other end is installed along the horizontal direction to be coupled to the raker member 100 or the inner tension reinforcing member 200b; it is preferable

The intermediate reinforcing member 300 includes a horizontal intermediate reinforcing member 300c installed along the horizontal direction; The lower end is coupled to the lower part of the retaining wall 10, and the upper inclined intermediate reinforcing member (300d) is installed to be inclined upwardly so that the upper end is coupled to the horizontal intermediate reinforcing member (300c) or the tensile reinforcing member (200); desirable.

The tension reinforcing member 200 is preferably a steel bar, a steel pipe, or a steel wire.

An auxiliary member 410 having an inclined portion 411 formed to be coupled to the inclined upper surface of the raker member 100 and a horizontal portion 412 formed on the inclined portion 411 to form a horizontal plane; A fixing member 420 coupled to the upper portion of the auxiliary member 410 so that the upper end of the tension reinforcing member 200 is fixed, the other end of the intermediate reinforcing member 300 is the raker member 100 It is preferable to bind to

The raker member 100 includes one side raker member 110 and the other side raker member 120 installed to be spaced apart from each other along the side, and the intermediate reinforcing member 300 is one side intermediate reinforcing member installed to be spaced apart along each side. 310 and the other side intermediate reinforcing member 320, the one side intermediate reinforcing member 310 is coupled to the one side raker member 110, and the other side intermediate reinforcing member 320 is the other side raker member 120 ), and the fixing member 420 is installed to be supported in common by the one side raker member 110 and the other side raker member 120, and the tension reinforcing member 200 is the one side raker member 110. It is preferable to be installed between the and the other side raker member (120).

The fixing member 420 includes a pair of "C"-shaped steel 421 installed at a distance from each other so as to form an "I"-shaped structure as a whole; It is preferable to include; while the installation hole 423 of the tension reinforcing member 200 is formed in the core, the fixing plate 422 installed on the upper portion of the pair of "C"-shaped steel 421;

The fixing member 420 is preferably installed so as to be supported in common by the plurality of raker members 100 installed at a distance from each other as well as being formed long along the width direction.

The present invention provides a construction method of the retaining structure, comprising: burying the retaining wall 10 or thumb stakes along the edge of the excavation area (1); excavating a part of the excavation area (1) to secure an installation position of the tension reinforcing member (200) and burying the tension reinforcing member (200); Excavating a part of the excavation area (1) so that the installation position of the raker member 100 is secured, as well as installing the raker member 100; A part of the excavation area 1 is excavated so that the installation position of the intermediate reinforcing member 300 is secured, and the intermediate reinforcing member 300 is installed, and the other end of the intermediate reinforcing member 300 is cut with the raker Combining the member 100 or the tension reinforcing member 200; combining the tension reinforcing member 200 and the raker member 100; It proposes a construction method of a retaining structure having a raker reinforcement structure comprising; excavating the remainder of the excavation area (1).

The present invention is easy to construct, saves and recycles materials, facilitates laying work for slabs in an underground structure, waterproof work, etc., has a small possibility of defects, and secures a working space adjacent to the lower part of the retaining structure. A retaining structure having a raker reinforcement structure that facilitates excavation work and a construction method thereof are presented.

1 and 2 are schematic diagrams of a conventional retaining structure.
3 shows an embodiment of the retaining structure according to the present invention,
Fig. 3 is a block diagram of the first embodiment;
Fig. 4 is a block diagram of the second embodiment;
Fig. 5 is a block diagram of the third embodiment;
Fig. 6 is a configuration diagram of a fourth embodiment;
Fig. 7 is a configuration diagram of a fifth embodiment;
Fig. 8 is a block diagram of the sixth embodiment;
Fig. 9 is a configuration diagram of a seventh embodiment;
Fig. 10 is a block diagram of the eighth embodiment;
11 is a detailed view of the eighth embodiment;
Fig. 12 is a plan view of the 8-1 embodiment;
Fig. 13 is a plan view of an 8-2 embodiment;
14 is a plan view of the raker member and the auxiliary member.
15 is a perspective view of an auxiliary member;
16 to 24 are process diagrams of the construction method of the retaining structure.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3, the present invention basically relates to a retaining structure installed to surround the excavation area (1) formed by the excavation.

This is a retaining wall 10 by the thumb pile earth plate construction method, the C.I.P. method, the S.C.W. method, etc.; The upper end is coupled to the upper portion of the retaining wall 10, and the lower end is installed inclined downwardly to the bottom of the excavation area (1) raker member (100); It is coupled to the central portion of the raker member 100 to resist the soaring of the raker member 100, is spaced inward from the retaining wall 10 and installed along the vertical direction, and the lower end is buried in the bottom of the excavation area (1) tension reinforcing member 200; One end is coupled to the central portion of the retaining wall 10, and the other end is inclined or installed along the horizontal direction to be coupled to the raker member 100 or the tension reinforcing member 200;

That is, in the prior art, when the supporting force by one raker member is insufficient, there was the above-described problem as a plurality of raker members of an inclined structure are installed as shown in FIGS. 1 and 2, but in the present invention, a plurality of raker members Instead of installing the intermediate reinforcing member 300 is installed.

However, when taking a structure in which one end of the intermediate reinforcing member 300 is coupled to the central portion of the retaining wall 10 and the other end of the intermediate reinforcing member 300 is coupled to the raker member 100 as described above, the intermediate reinforcing member 300 There is a problem that the spitting phenomenon may occur excessively at the coupling portion of the and raker member 100 .

Tensile reinforcing member 200 is a tensile pile structure so as to resist the soaring of the raker member 100 as above, it is possible to maintain the stability of the overall retaining structure.

Since one end of the intermediate reinforcing member 300 coupled to the central portion of the retaining wall 10 is supported by the raker member 100, the other end of which is increased by the reinforcement of the tensile reinforcing member 200 in this way, the retaining wall 10 ) to prevent the phenomenon of fullness in the central part.

However, in this case, since the axial stress of the raker member 100 increases, it is necessary to increase the supporting force of the support block 40 installed at the lower end of the raker member 100 .

The other end of the intermediate reinforcing member 300 is coupled to the raker member 100 or the tensile reinforcing member 200, and the coupling position is adjacent to the coupling site of the raker member 100 and the tensile reinforcing member 200. It is preferable in terms of minimizing the occurrence of stress.

That is, in the present invention, when the supporting force by the simple support structure of the raker member 100 is insufficient, instead of installing an additional raker member as in the prior art, the tension reinforcing member 200 is installed along the vertical direction, It takes a structure for reinforcing by installing the intermediate reinforcing member 300 along the inclined or horizontal direction.

For reinforcement of a retaining structure having a large depth of excavation, a plurality of tensile reinforcement members 200 and intermediate reinforcement members 300 may be combined with respect to one raker member 100. (FIG. 4)

This has the following effects.

First, the intermediate reinforcing member 300 installed instead of the raker member can be installed to avoid the installation position of the slab 60 of the underground structure, and thus the block-out portion 61 of the slab 60 can be minimized. , construction is easy, materials can be saved, and materials can be recycled by separating after installation of the slab (Fig. 5).

Second, since the intermediate reinforcing member 300 can be installed to avoid the installation position of the slab of the underground structure, it does not interfere with the reinforcement work and the waterproofing work of the slab, so the workability is excellent and the possibility of occurrence of defects is small.

Third, only one raker member 100 can be supported on one support block 40 , and the number of installed support blocks 40 can be reduced, so that the support block 40 and the floor slab 70 conflict with each other As the area decreases, the workability, structural stability, and waterproofing performance of the floor slab increase.

Fourth, since the number of installed raker members can be reduced, it is possible to sufficiently secure the working space of the adjacent part of the lower part of the retaining structure 10, so that the excavation work is easy.

3 to 9 are exemplary embodiments in which the H file is applied as the tension reinforcing member 200 .

These are basically, the top is coupled to the upper portion of the retaining wall (10), the lower end is installed inclined downwardly to the bottom of the excavation area (1) raker member (100); It is coupled to the central portion of the raker member 100 to resist the soaring of the raker member 100, is spaced inward from the retaining wall 10 and installed along the vertical direction, and the lower end is buried in the bottom of the excavation area (1) a tension reinforcing member 200; One end is coupled to the central portion of the retaining wall 10, and the other end is inclined or installed along the horizontal direction to be coupled to the raker member 100 or the tension reinforcing member 200;

Figure 3 is an embodiment when the intermediate reinforcing member 300 is installed along the horizontal direction, the other end is coupled to the raker member (100).

4,5 is an embodiment in which a plurality of tension reinforcing members 200 and intermediate reinforcing members 300 are combined with respect to one raker member 100 for reinforcement of a retaining structure having a large depth of excavation.

Here, the tensile reinforcing member 200 is configured to include an outer tensile reinforcing member 200a and an inner tensile reinforcing member 200b installed to be spaced apart from each other.

The intermediate reinforcing member 300 is an upper intermediate reinforcing member ( 300a); One end is coupled to the lower center of the retaining wall 10, and the other end is installed along the horizontal direction so as to be coupled to the raker member 100 or the inner tension reinforcing member 200b; .

The central portion of the lower intermediate reinforcing member 300b may be supported by being coupled to the central portion of the outer tension reinforcing member 200a.

6 is an embodiment when the present invention is applied to the retaining wall 11 by the two-row thumb pile earth plate method.

7 is an embodiment in which the intermediate reinforcing member 300 is installed to be inclined upward, and the other end thereof is coupled to the raker member 100 .

Even if the intermediate reinforcing member 300 is installed inclined as shown in FIG. 7 , the inclination is small compared to the inclination of the raker member 100 , so it is possible to install it avoiding the slab installation position of the underground structure.

The intermediate reinforcing member 300 may be installed in the same direction as the inclination of the raker member 100, and may be installed in the opposite direction to the inclination of the raker member 100 as shown in FIG. more advantageous with

FIG. 8 is an embodiment in which one tensile reinforcing member 200 and a plurality of intermediate reinforcing members 300 are coupled with respect to one raker member 100 .

Here, the intermediate reinforcing member 300 includes a horizontal intermediate reinforcing member 300c installed along the horizontal direction; The lower end is coupled to the lower part of the retaining wall 10, and the upper inclined intermediate reinforcing member (300d) is installed to be inclined upwardly so that the upper end is coupled to the horizontal intermediate reinforcing member (300c) or the tensile reinforcing member (200); do.

9 is an embodiment of the case in which one tension reinforcing member 200 and the intermediate reinforcing member 300 are coupled with respect to a plurality of raker members 100a and 100b.

10 to 15 are exemplary embodiments in which a steel bar, a steel pipe, or a steel wire is applied as the tension reinforcing member 200 .

The tension reinforcing member 200 is installed along the vertical direction, but since it is a tension member that resists the soaring of the raker member 100, there is no need to necessarily use an expensive material such as an H file, and a steel bar, steel pipe or steel wire is used. It is enough though.

If necessary, a plurality of steel bars, steel pipes, and steel wires may be used to increase the tensile resistance.

In the case of this embodiment, since it is difficult to couple the intermediate reinforcing member 300 to the tensile reinforcing member 200 , the other end of the intermediate reinforcing member 300 is coupled to the raker member 100 .

The raker member 100 is to be installed obliquely, and since the tension reinforcing member 200 is installed along the vertical direction, it is preferable that the auxiliary member 410 and the fixing member 420 are installed for their stable coupling. (FIGS. 11 to 15)

The auxiliary member 410 includes an inclined portion 411 formed to be coupled to the inclined upper surface of the raker member 100, and a horizontal portion 412 formed on the upper portion of the inclined portion 411 to form a horizontal plane. (FIG. 14) ,15)

The fixing member 420 is coupled to the upper portion of the auxiliary member 410 so that the upper end of the tension reinforcing member 200 is fixed (Figs. 11, 12, 13).

The tension reinforcing member 200 may be installed to penetrate the raker member 100, but two raker members 100 are installed adjacently, and one tension reinforcing member 200 is installed therebetween, or around it. It is preferable to install a plurality of tension reinforcing members 200 for workability and structural stability.

In this case, the raker member 100 is configured to include one raker member 110 and the other raker member 120 installed to be spaced apart along each other, and the intermediate reinforcing member 300 is one side installed to be spaced apart from each other along the side. It is configured to include an intermediate reinforcing member 310 and the other intermediate reinforcing member 320 .

The other end of one intermediate reinforcing member 310 is coupled to one raker member 110 , and the other end of the other intermediate reinforcing member 320 is coupled to the other raker member 120 .

Auxiliary member 410 is installed on the upper part of one raker member 110 and the other raker member 120, respectively (FIG. 14), and the fixing member 420 is one raker member 110 and the other raker member 120. It is installed on the upper side of the auxiliary member 410 so as to be supported in common by the

Tension reinforcing member 200 may be installed between one raker member 110 and the other raker member 120, (FIG. 12) a plurality of tension reinforcing member 200 is one raker member 110 and the other raker It may be installed on the outside of the member 120 (FIG. 13).

The fixing member 420 includes a pair of "C"-shaped steel 421 installed at a distance from each other so as to form an "I"-shaped structure as a whole; The installation hole 423 of the tension reinforcing member 200 is formed in the core, and the fixing plate 422 installed on the upper portion of a pair of "C"-shaped steel 421 can be implemented by a structure including; .(Fig. 11,12,13)

The fixing member 420 is formed to be long along the width direction, and is installed to be supported in common by a plurality of raker members 100 installed at a distance from each other, thereby increasing the overall strength of the reinforcing structure.

Hereinafter, the construction method of the retaining structure according to the present invention will be described.

A retaining wall 10 or a thumb stake is embedded along the edge of the excavation area 1 (FIG. 16).

A part of the excavation area 1 is excavated so that the installation position of the tension reinforcing member 200 is secured, and the tension reinforcing member 200 is buried (FIG. 17).

A part of the excavation area 1 is excavated to form an inclined surface so that the installation position of the raker member 100 is secured. (FIG. 18)

Install the support block 40 at the lower end of the inclined surface. (FIG. 19)

Install the raker member 100 to be supported by the support block 40. (FIG. 20)

A part of the excavation area 1 is excavated so that the installation position of the intermediate reinforcing member 300 is secured, and an excavation surface (flat surface or inclined surface) equal to the inclination of the intermediate reinforcing member 300 is formed. (FIG. 21)

Install the intermediate reinforcing member 300, and combine the other end of the intermediate reinforcing member 300 with the raker member 100 or the tensile reinforcing member 200 (FIG. 22).

The auxiliary member 410 and the fixing member 420 are installed, and the tension reinforcing member 200 and the raker member 100 are combined. (FIG. 23)

The remainder of the excavation area 1 is excavated (FIG. 24).

Since the above has only been described with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention as noted above should not be construed as being limited to the above embodiments, and It will be said that the technical idea and the technical idea with the root are all included in the scope of the present invention.

1: excavation area 10: retaining wall
100,100a,100b,110,120: Raker member
200,200a,200b: Tensile reinforcing member
300,300a,300b,300c,300d,310,320: intermediate reinforcing member
410: auxiliary member 411: inclined portion
412: horizontal part 420: fixing member
421: "C" shaped steel 422: fixing plate
423 : installer

Claims (11)

In the retaining structure installed to surround the excavation area (1) formed by the excavation,
retaining wall 10;
The upper end is coupled to the upper portion of the retaining wall (10), the lower end of the raker member (100) is installed inclined downwardly to be coupled to the bottom of the excavation area (1);
It is coupled to the central portion of the raker member 100 to resist the soaring of the raker member 100, is spaced apart from the retaining wall 10 inwardly and is installed along the vertical direction, and the lower end is the excavation area (1) Tensile reinforcement member 200 buried in the bottom of the;
One end is coupled to the central portion of the retaining wall 10, the other end is inclined or installed along the horizontal direction to be coupled to the raker member 100 or the tension reinforcing member 200 intermediate reinforcing member 300;
Auxiliary member 410 having an inclined portion 411 formed to be coupled to the inclined upper surface of the raker member 100, and a horizontal portion 412 formed on the upper portion of the inclined portion 411 to form a horizontal plane;
A fixing member 420 coupled to the upper portion of the auxiliary member 410 so that the upper end of the tension reinforcing member 200 is fixed;
The tension reinforcing member 200 is a steel bar, a steel pipe or a steel wire,
The other end of the intermediate reinforcing member 300 is a retaining structure having a raker reinforcement structure, characterized in that coupled to the raker member (100). According to claim 1,
Retaining structure having a raker reinforcement structure, characterized in that the slope of the intermediate reinforcing member 300 is smaller than the slope of the raker member 100. According to claim 1,
The inclination of the intermediate reinforcing member 300 is a retaining structure having a raker reinforcement structure, characterized in that in the opposite direction to the inclination of the raker member 100. According to claim 1,
The tensile reinforcing member 200 includes an outer tensile reinforcing member 200a and an inner tensile reinforcing member 200b installed to be spaced apart from each other,
The intermediate reinforcing member 300,
One end is coupled to the upper center of the retaining wall 10, the other end is installed along the horizontal direction to be coupled to the raker member 100 or the outer tension reinforcing member (200a) upper intermediate reinforcing member (300a);
One end is coupled to the lower center of the retaining wall 10, and the other end is installed along the horizontal direction so as to be coupled to the raker member 100 or the inner tension reinforcing member (200b) lower intermediate reinforcing member (300b);
Retaining structure having a raker reinforcement structure, characterized in that it includes. According to claim 1,
The intermediate reinforcing member 300,
Horizontal intermediate reinforcing member (300c) installed along the horizontal direction;
The lower end is coupled to the lower part of the retaining wall 10, and the upper end is inclined upwardly inclined intermediately to be coupled to the horizontal intermediate reinforcing member 300c or the tensile reinforcing member 200 (300d);
Retaining structure having a raker reinforcement structure, characterized in that it includes. delete delete According to claim 1,
The raker member 100 includes one side raker member 110 and the other side raker member 120 installed to be spaced apart along the side,
The intermediate reinforcing member 300 includes one intermediate reinforcing member 310 and the other intermediate reinforcing member 320 installed to be spaced apart from each other along the sides,
The one side intermediate reinforcing member 310 is coupled to the one side raker member 110,
The other side intermediate reinforcing member 320 is coupled to the other side raker member 120,
The fixing member 420 is installed to be supported in common by the one side raker member 110 and the other side raker member 120,
The tensile reinforcing member 200 is a retaining structure having a raker reinforcement structure, characterized in that it is installed between the one side raker member 110 and the other side raker member 120. 9. The method of claim 8,
The fixing member 420 is,
A pair of "C"-shaped steel 421 installed at a distance from each other to form an "I"-shaped structure;
An installation hole 423 of the tension reinforcing member 200 is formed in the core, and a fixing plate 422 installed on the upper portion of the pair of "C"-shaped steel 421;
Retaining structure having a raker reinforcement structure, characterized in that it includes. 9. The method of claim 8,
The fixing member 420 is formed long along the width direction, and a retaining structure having a raker reinforcement structure, characterized in that it is installed to be supported in common by a plurality of the raker members 100 installed at a distance from each other. As a construction method of any one of claims 1 to 5, 8 to 10, the retaining structure,
burying the retaining wall 10 or thumb stakes along the edge of the excavation area (1);
excavating a part of the excavation area (1) to secure an installation position of the tensile reinforcing member (200) and burying the tensile reinforcing member (200);
Excavating a part of the excavation area (1) so that the installation position of the raker member 100 is secured, as well as installing the raker member 100;
A part of the excavation area 1 is excavated so that the installation position of the intermediate reinforcing member 300 is secured, and the intermediate reinforcing member 300 is installed, and the other end of the intermediate reinforcing member 300 is cut with the raker Combining the member 100 or the tension reinforcing member 200;
combining the tension reinforcing member 200 and the raker member 100;
excavating the remainder of the excavation area (1);
Construction method of retaining structure having a raker reinforcement structure, characterized in that it includes.

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