KR100971198B1 - Soil retaining method for two rows pile using soil nailing - Google Patents

Abstract

The present invention, the first row thumb pile indentation step of entering the first row thumb pile 100 along the boundary line of the excavation region (1); A second row thumb pile indentation step of entering the second row thumb pile 200 at intervals outside the first row thumb pile 100; A connection step of connecting the first row of thumb piles 100 and the second row of thumb piles by the connecting member 300 so as to be integrally behaved; An excavation structure forming step of installing excavation region 1 to form an excavation structure by installing an excavation member 10 between the first row thumb piles 100; Soil nail installation step of installing the soil nail 400 for the soil structure; by presenting a two-row thumb pile earthquake method using a soil nailing, including the earth pressure of the rearing soil even when performing a deep trench work It is to be sufficiently resistant to, and to suppress the occurrence of the overall displacement of the structure.

Crust, Thumb Pile, Soil Nail

Description

SOIL RETAINING METHOD FOR TWO ROWS PILE USING SOIL NAILING}

The present invention relates to the field of construction, and more particularly, to a thumb pile masonry method to reduce the effect of the earth pressure of the earth and sand to obtain the effect of reducing the air and construction costs.

Thumb pile earth block method is a kind of detachable earth block method. It is entered by the method of driving the thumb pile (H-Pile) or inserting it after drilling at regular intervals. It refers to a method of embedding the wall forming method, the thumb pile earth plate method, sheet pile method, SCW, CIP and the like.

Figure 1 is a schematic diagram showing the configuration of the structure of the earth block by the thumb pile earth plate method of the conventional earth block method.

It is constituted by a plurality of thumb piles (H beams) 1 installed vertically so that the mutual groove portions face each other, and an earth plate 10 inserted into the groove portion to prevent the pile of dirt from behind falling down toward the front. .

As the earth plate 10, a wood plate or a steel plate of a predetermined standard is used, and it has been common to adopt a structure in which fittings (wedges) are installed in order to form a wall by stacking them, and to fix the laminated earth plate.

Such a conventional thumb pile clogging method has been pointed out as a problem in the following points.

First, in the case of high-depth excavation work, since the H beam alone cannot resist the earth pressure of the rearing soil, a large number of support materials (Strut, Earth Anchor, Raker, etc.) must be used to reinforce it. Not only is it uneconomical, it is difficult to secure a working space and structurally inefficient, so there is a fear of subsidence.

Second, the earthquake structure according to the conventional construction method can act as an earth wall as a rigid body, but because the displacement of the upper head is relatively large, the loosening of the back ground occurs largely.

The present invention has been made to solve the above problems, even when performing a high-depth digging work to sufficiently resist the earth pressure of the rearing soil, and to suppress the occurrence of the overall displacement of the earthen structure 2 The purpose of this article is to present a ten-pile pile masonry method.

In order to achieve the object as described above, the present invention includes a first row thumb pile indentation step of indenting the first row thumb pile 100 along the boundary line of the excavation region 1; A second row thumb pile indentation step of indenting the second row thumb pile 200 at intervals outside the first row thumb pile 100; A connection step of interconnecting the first row thumb pile 100 and the second row thumb pile 200 by a connection member 300 so as to be integrated with each other; An earthquake structure forming step of forming an earthquake structure by installing the earthquake member 10 between the first row thumb piles 100 while excavating the excavation region 1; It proposes a two-row thumb pile earth block construction method using a soil nailing, including; a soil nail installation step for installing the soil nail 400 for the earth structure.

In the step of forming the soil structure and installing the soil nail, the drilling hole 410 is formed in a region between the first row thumb pile 100 and the second row thumb pile 200 so that the soil nail 400 is inserted. Perforating step; Soil nail 400 installation step of installing the soil nail 400 in the earth member 10 and the drilling hole (410); And a grouting step of injecting grout into the drilling hole 410.

The step of forming the retaining structure preferably further includes an inclined surface forming step of digging so that the inclined surface 2 facing inward is formed between the first row thumb pile 100 and the second row thumb pile 200.

The inclined surface forming step is to excavate inclined inward to the limit depth (L) to form a stable slope between the area between the first row thumb pile 100 and the second row thumb pile 200, the excavation area ( It is preferable to excavate 1) to the said limit depth L.

The inclined surface forming step includes excavating an area between the first row thumb pile 100 and the second row thumb pile 200 and the excavation region 1 to a primary design depth H1, and the second row thumb. A second row mudstone structure forming step of installing a second row mudstone member 20 between the piles 200 to form a second row mudstone structure; Below the first design depth H1, the region between the first row thumb pile 100 and the second row thumb pile 200 is inclined inwardly to a secondary design depth H2 that forms a stable slope. In addition, the excavation region 1 is excavated to the secondary design depth H2.

The inclined surface forming step may further include a second row soil nail installation step of installing a second row soil nail 500 with respect to the second row soil structure.

The second row soil nail installation step may include a drilling step of forming a drilling hole 510 to insert the second row soil nail 500 in a region within the first design depth H1; A second row soil nail installation step of installing a second row soil nail 500 on the second row soil member 20 and the drilling hole 510; And a grouting step of injecting grout into the drilling hole 510.

In the connecting step, it is preferable to interconnect the upper portions of the first row thumb pile 100 and the second row thumb pile 200 by the front-rear connecting member 310.

The connecting step may include connecting the first row thumb pile 100 by a first row left and right connecting member 321; Interconnecting the second row of thumb piles by a second row of left and right connecting members 322; And connecting the first row left and right connecting members 321 and the second row left and right connecting members 322 to each other by the front and rear connecting members 310.

The first row of left and right connecting members 321 and the second row of left and right connecting members 322 are respectively installed on tops of the first row of thumb piles 100 and the second row of thumb piles 200, Directional connecting member 310 is preferably installed on the upper portion of the first row left and right connecting member 321 and the second row left and right connecting member 322.

The present invention proposes a two-row thumb pile clogging method to sufficiently resist the earth pressure of the rearing soil even when carrying out a high-depth excavation work, and to suppress the occurrence of the overall displacement of the clogging structure.

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

As shown in Figure 2, the thumb pile earth block method according to the present invention is basically configured by the following process.

The first row thumb pile 100 is driven along the boundary line of the excavation area 1, and the second row thumb pile 200 is inserted at intervals outside the first row thumb pile 100 (FIG. 2). ).

The first row thumb pile 100 and the second row thumb pile 200 are interconnected by the connection member 300 so as to be integrally formed (FIG. 3).

More specifically, when the upper portion of the first row thumb pile 100 and the second row thumb pile 200 is exposed to the ground by the progress of the trench, the first row of left and right connecting members 321 and Installing the second row of left and right connecting members 322, respectively, the first row of the left and right connecting members 321 and the second row of the left and right connecting members 322 to install the front and rear connecting members 310. desirable.

While excavating the excavation region 1, the earth block member 10 is sequentially installed between the first row thumb piles 100 to form the earth block structure (FIGS. 4, 5 and 6).

Soil nail 400 is installed with respect to the earth structure (FIGS. 4, 5, 6).

That is, in addition to the masonry structure in which the masonry member 10 is installed in the first column of the thumb pile 100, the second column of the thumb pile 200 is driven outside and the first column of the thumb pile 100 is behaved integrally therewith. On the other hand, it is reinforced by soil nailing to the earth structure of the first row thumb pile 100.

This has the following advantages over the conventional general clogging method.

First, by the combination of the second row thumb pile 200 and the soil nail 400, it serves as an interference pile of the slope to prevent shear destruction of the rearing soil body, it is possible to minimize the occurrence of displacement of the earth structure.

Second, the first row thumb pile 100, the second row thumb pile 200, the connecting member 300, the soy nail 400 is integrally behave, so that the strength of each member can be sufficiently exhibited, the same It is economical because high-depth destruction is possible while using strength and quantity of materials.

Third, while performing a high-definition earthquake construction method, it is possible to secure a sufficient working space because no separate support material such as a strut is needed.

Fourth, compared to the general earthquake construction method using only the soil nail, it is possible to reduce the near-entry of the soil nail due to the load of the second row thumb pile 200, it is possible to minimize the impact on the adjacent structure.

Hereinafter, specific embodiments of the construction of the soil nail 400 will be described.

Soil nail 400 for the construction of the soil structure will be various, but in the case of the method according to the present invention because the second row of the pile 200 is located behind the first row of the pile 100, In order to avoid interference, it is preferable to apply a method of forming a drill hole 410 in the region between the first row thumb pile 100 and the second row thumb pile 200, and constructing the soil nail 400. .

The present embodiment will be described with reference to FIGS. 4 to 6.

The hole nail 410 is formed in an area between the first row thumb pile 100 and the second row thumb pile 200 so that the small nail 400 is inserted therein.

Soil nail 400 is installed in the soil blocking member 10 and the drilling hole 410, and the grout is injected into the drilling hole 410.

As a method of fixing the head of the soil nail 400 with respect to the soil member 10, a fixing hole is formed in the soil member 10, and the soil nail 400 is inserted into the soil nail member 10 to fix the head of the soil nail member 10. The edge portion may be supported by the head of the sole nail 400 or any other method.

As a result, the soil nail structure 400 having a solid structure in which the sole nail 400, the strip 420, the first row thumb pile 100, the connection member 300, and the second row thumb pile 200 are integrally installed may be obtained.

Hereinafter, with reference to FIGS. 7-9, the Example regarding the case where the inclined surface 2 was formed is demonstrated.

In the above structure structure forming step, it is preferable to further include a step of excavating so that the inclined surface (2) toward the inner side is formed between the first row thumb pile 100 and the second row thumb pile 200.

In this way, when performing the earthquake construction, it is possible to form the earthquake structure as shown in Figures 7 to 9, which is the first row thumb pile 100 and the second row thumb pile 200 compared to the conventional soil structure It is characteristic in that the inclined surface 2 is formed in the upper part in between.

That is, in the case of applying the method according to the present embodiment, a structure in which the ingots corresponding to the upper region S of the inclined surface 2 is removed as compared with the conventional structure can be obtained. In case of using the material of high strength, it is possible to obtain a high-definition earthquake structure, and when constructing a high-definition earthquake structure, the material can be saved.

In more detail, the operation of forming the inclined surface 2, the area between the first row thumb pile 100 and the second row thumb pile 200 is formed to a limit depth L that forms a slope of a stable slope. It is preferable to excavate at an inclined angle, and to excavate the excavation area | region 1 to the limit depth L (FIG. 8).

After the limit depth L, the earth-block member 10 is installed in the first row thumb pile 100, and the soil nail 400 is installed to excavate to the design depth (FIG. 9).

10 to 12 show another embodiment of the two-row thumb pile earth construction method in the present invention.

The basic process is the same as in the above embodiment, but the inclined surface forming step is slightly different.

The inclined surface forming step in this embodiment is constituted as follows.

Excavating the area between the first row thumb pile 100 and the second row thumb pile 200 and the excavation region 1 to the primary design depth H1, and between the second row thumb pile 200 A two-row mudguard member 20 is installed (FIG. 10).

Below the primary design depth H1, the area between the first row thumb pile 100 and the second row thumb pile 200 is inclined inwardly to a secondary design depth H2 that forms a stable slope and In addition, the excavation region 1 is excavated to the secondary design depth H2 (FIG. 11).

Below the 2nd design depth H2, the earth-block member 10 is installed in the 1st row | middle thumb pile 100, and it excavates to design depth while installing the soil nail 400 (FIG. 12).

In this way, when performing the earthquake construction, it is possible to form the earthquake structure as shown in Figure 12, which is on the upper inclined surface (2) between the first row thumb pile 100 and the second row thumb pile 200 Another second row mudstone structure is formed.

Since the second row soil structure serves to stabilize the inclined surface 2 formed between the first row thumb pile 100 and the second row thumb pile 200, the upper region S of the inclined surface 2. To make it larger.

Therefore, compared with the embodiment of FIG. 9, since a structure in which more ingots in the region S are removed can be obtained, a greater earth pressure reduction effect can be obtained, and thus, a higher depth when using materials of the same strength is obtained. It is possible to obtain the structure of the earthquake, and when constructing the earthquake structure of the same depth, it is possible to obtain a greater effect of saving material.

Figure 13 shows another embodiment of a retaining method according to the present invention.

The basic process is the same as in the above embodiment, but it is added that the second row soil nail 500 is also installed for the second row soil structure formed on the second row thumb pile 200.

In this case, the structural stability of the second row mudstone structure in the above embodiment can be further strengthened, so that the upper region S of the inclined surface 2 can be made larger, and thus a greater earth pressure reduction effect can be obtained. Therefore, it can be obtained by further maximizing the effect according to the above embodiment.

In the case of constructing the second row soil nail 500 for the second row soil structure, unlike the construction in the first row of the pile 100, there is no structure that interferes with the rear, so more free construction is possible. Do.

That is, the perforation hole 510 is formed to insert the second row soil nail 500 in the region within the primary design depth H1, and the second row is formed in the second row soil member 20 and the perforation hole 510. After installing the soil nail 500, the second row soil nail 500 is constructed by injecting grout into the drilling hole 510.

Hereinafter, an embodiment of the connection member 300 applied to the above connection step will be described with reference to FIGS. 3 and 4.

Since the connecting member 300 connects the first row thumb pile 100 and the second row thumb pile 200 to be integrated with each other, a structure for connecting them in the front-rear direction is required, and the upper head of the above-mentioned mud member structure In order to minimize the occurrence of the displacement, it is preferable to take a structure that interconnects the first row thumb pile 100 and the second row thumb pile 200 by the front and rear connecting member 310.

The front and rear connecting member 310 may take a structure for interconnecting each of the thumb piles 100 and 200 of the plurality of first row thumb piles 100 and the second row thumb piles 200, In order to increase the structural stability, it is more preferable to take the structure integrated as follows.

That is, the first row thumb pile 100 is interconnected by the first row of left and right connecting members 321, and the second row thumb pile 200 is interconnected by the second row of left and right connecting members 322. After that, the first row of left and right connecting members 321 and the second row of left and right connecting members 322 are interconnected by the front and rear connecting members 310.

Even with this structure, in order to solve the above-mentioned problem of the upper head displacement, the first row of left and right connecting members 321 and the second row of left and right connecting members 322 are respectively arranged in the first row of the thumb pile 100. ) And the second row of thumb piles 200, and the front and rear connecting members 310 are installed on the first row of left and right connecting members 321 and the second row of left and right connecting members 322. It is desirable to take the configuration.

Since the above has been described only with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention, as is well known, should not be construed as limited to the above embodiments, the present invention described above It will be said that both the technical idea and the technical idea which together with the base are included in the scope of the present invention.

1 is a perspective view of a conventional thumb pile earth structure.

2 to 13 is a view for explaining a two-row thumb pile earth construction method according to the present invention,

2 to 4 are process diagrams of the first embodiment.

5 is a cross-sectional view of the retaining structure according to the first embodiment.

Figure 6 is a partial perspective view of the retaining structure according to the first embodiment.

Figure 7 is a partial perspective view of the retaining structure according to the second embodiment.

8 and 9 are process diagrams of the second embodiment.

10 to 12 are process diagrams of a third embodiment.

13 is a cross-sectional view of the retaining structure according to the fourth embodiment.

DESCRIPTION OF REFERENCE NUMERALS

1: excavation area 2: slope

10: earth block member 100: first row thumb pile

200: second row thumb pile 300: connection member

310: front and rear connecting member 321: first row left and right connecting member

322: second row left and right connecting member 400: Soil Nail

410: punched hole 500: second row soil nail

510: hole punch L: limit depth

H1: 1st design depth H2: 2nd design depth

Claims (10)

A first row thumb pile indentation step of indenting the first row thumb pile 100 along a boundary line of the excavation region 1; A second row thumb pile indentation step of indenting the second row thumb pile 200 at intervals outside the first row thumb pile 100; A connection step of interconnecting the first row thumb pile 100 and the second row thumb pile 200 by a connection member 300 so as to be integrated with each other; An earthquake structure forming step of forming an earthquake structure by installing the earthquake member 10 between the first row thumb piles 100 while excavating the excavation region 1; Soil nail installation step for installing the soil nail 400 for the earthen structure; includes, The earth block structure forming step Further comprising an inclined surface forming step of excavating such that the inclined surface (2) toward the inner side between the first row thumb pile 100 and the second row thumb pile 200 is formed, The inclined surface forming step While digging the area between the first row thumb pile 100 and the second row thumb pile 200 and the excavation region 1 to the first design depth H1, the second row thumb pile 200 A second row soil structure forming step of installing a second row soil member 20 between the second row soil structure; Below the first design depth H1, the region between the first row thumb pile 100 and the second row thumb pile 200 is inclined inwardly to a secondary design depth H2 that forms a stable slope. And digging the excavation region 1 to the secondary design depth H2. The inclined surface forming step The second row soil pile construction method using a soil nailing, characterized in that it further comprises a second row soil nail installation step for installing a second row soil nail 500 for the second row soil structure. The method of claim 1, The earth block structure forming step and the Soil Nail installation step A drilling step of forming a drilling hole 410 in a region between the first row thumb pile 100 and the second row thumb pile 200 so that the soil nail 400 is inserted; Soil nail 400 installation step of installing the soil nail 400 in the earth member 10 and the drilling hole (410); Grouting step of injecting grout into the drilling hole (410); Two-row thumb pile earthwork using a nail nailing method comprising a. delete delete delete delete The method of claim 1, The second row soil nail installation step A perforation step of forming a perforation hole (510) to insert the second row soil nail (500) in an area within the first design depth (H1); A second row soil nail installation step of installing a second row soil nail 500 on the second row soil member 20 and the drilling hole 510; Grouting step of injecting grout into the drilling hole (510) Two-row thumb pile earthquake method using a soy nailing, characterized in that it comprises. The method according to any one of claims 1, 2 or 7, The connecting step A two-row thumb pile mudstone construction method using a soil nailing, characterized in that the interconnection of the upper portion of the first row thumb pile 100 and the second row thumb pile 200 by the front and rear connecting member 310. The method of claim 8, The connecting step Interconnecting the first row of thumb piles by a first row of left and right connecting members 321; Interconnecting the second row of thumb piles by a second row of left and right connecting members 322; Connecting the first row left and right connecting members 321 and the second row left and right connecting members 322 to each other by the front and rear connecting members 310; Two-row thumb pile earthquake method using a soy nailing, characterized in that it comprises. 10. The method of claim 9, The first row of left and right connecting members 321 and the second row of left and right connecting members 322 are respectively installed on tops of the first row of thumb piles 100 and the second row of thumb piles 200. The front and rear direction connecting member 310 is a two-row thumb pile mud using a soil nailing, characterized in that installed on the top of the first row left and right connecting member 321 and the second row left and right connecting member 322. Method.

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