KR100964995B1 - Soil retaining method for two rows pile using raker - Google Patents

Abstract

The present invention relates to a method for manufacturing a pneumatic tire, comprising: a first row of thumb piles (100) for fitting a first row of thumb piles (100) along a boundary line of an excavation region (1); A second row of thumb thumb piles adjacent to the second row thumb pile 200 spaced apart from the first row of thumb piles 100; A connecting step in which the first row thumb pile 100 and the second row thumb pile 200 are interconnected by the connecting member 300 so as to integrally move; Forming an earth retaining structure by excavating the excavation region (1) and installing a securing member (10) between the first heat thumb piles (100) to form a securing structure; A two-row thumb pile retention method using a lacquer including a lacquer installation step in which a lacquer (400) is installed on a securing structure is proposed so that even when a severe earthquake is carried out, So that the occurrence of the overall displacement of the retaining structure can be suppressed.

Retaining wall, Thumb pile, Lakers

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a two-row pile retention method using a lacquer,

TECHNICAL FIELD The present invention relates to a construction field, and more particularly, to a thumb pile cladding method for reducing the effect of earth pressure on back soil gravel to reduce air shortening and construction cost.

Thumb pile retention is a type of retention type retention method that is applied by a method of hitting a pile (H-Pile) at regular intervals or by inserting it after perforation, and moving the soil retaining member such as soil plate between the thumb piles This is a method of forming a wall by sandwiching, such as a pile piling method, a sheet pile method, SCW, CIP, and the like.

FIG. 1 is a schematic view showing the construction of a retaining structure according to a thumb pile erosion preventing method in a conventional retaining method.

This is constituted by a plurality of thumb piles (H beams) 1 vertically installed so as to face each other with their mutual grooves facing each other, and a soil plate 10 inserted and supported in the grooves so as to prevent the rear soil from collapsing forward .

As the current plate 10, a wood plate or a steel plate of a predetermined standard is used, and it is common to employ a structure in which a wall is formed by laminating it and a wedge is provided for fixing the laminated plate.

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

First, in case of severe earthquake construction, H beam alone can not resist the earth pressure of back soil, so a lot of supporting materials (Strut, Earth Anchor, Raker, etc.) should be used to reinforce it. Not only is it not economical, it makes it difficult to secure a work space, and it is structurally inefficient and there is a fear of subsidence in the surrounding ground.

Second, although the retaining structure of the conventional method can act as a rigid body, it has a relatively large upper head displacement, so that the loosening of the backside ground occurs largely.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems and to provide a method and a system for securing sufficient resistance to the earth pressure of rear soil, The purpose of this paper is to propose a heat - staking pile cladding method.

In order to accomplish the above-mentioned object, the present invention provides a method for manufacturing a pneumatic tire, comprising: a first heat thumb pile pouring step of moving a first heat thumb pile 100 along a boundary line of an excavation region 1; A second row of thumb thumb piles adjacent to the second row of thumb thumb piles 200 spaced apart from the first row of thumb thumb piles 100; A connecting step of interconnecting the first heat thumb pile 100 and the second heat thumb pile 200 by the connecting member 300 so that the first heat thumb pile 100 and the second heat thumb pile 200 integrally move; Forming an earth retaining structure by excavating the excavation region (1) and installing a securing member (10) between the first heat thumb piles (100) to form a securing structure; And a lacquer installing step of installing a lacquer (400) on the retaining structure. The present invention proposes a two-row thumb pile retention method using a lacquer.

The lacquer installing step may include a rake top fixing step of fixing the upper end of the lacquer 400 to the securing structure; Forming a laker support part (410) on a bottom surface of the excavation area (1); And a lower lacquer fixing step of fixing the lower end of the lacquer 400 to the lacquer supporting part 410.

The rake top fixing step may include a wale installation step of installing a wale 420 in front of the first heat thumb pile 100; And fixing the upper end of the laker 400 to the wale 420.

The forming of the lacquer supporting part comprises: vertically supporting the supporting pile 411; Installing a support pile (412) in a lateral direction on the upper end of the support pile (411) to support the lower end of the laker (400); And forming a concrete block 413 by pouring concrete around the support pile 411 and the support pile 412.

The lacquer support forming step may further include injecting a reinforcing agent into the surrounding ground of the support pile 411.

The forming of the retaining structure may further include a step of forming a slope so that an inclined surface 2 facing inward between the first row of thumb piles 100 and the second row of thumb piles 200 is formed.

The inclined surface forming step may be performed such that the area between the first heat thumb pile 100 and the second heat thumb pile 200 is sloped inwardly to a critical depth L forming a stable slope, 1) to the limit depth (L).

The slope forming step may include excavating the area between the first row of thumb piles 100 and the second row of thumb piles 200 and the excavation area 1 up to the first design depth H1, Forming a second thermal retention structure by providing a second thermal retention member (20) between the piles (200) to form a second thermal retention structure; Below the primary design depth H1, the area between the first row of thumb piles 100 and the second row of thumb piles 200 is sloped inward to the second design depth H2 forming a stable slope And excavating the excavation region 1 up to the secondary design depth H2.

Preferably, the connecting step interconnects the upper portion of the first heat thumb pile 100 and the upper portion of the second heat thumb pile 200 by the anteroposterior connecting member 310.

The connecting step comprises interconnecting the first row thumb piles 100 by a first row left-right connecting member 321; Interconnecting said second row thumb piles (200) by a second row lateral linking member (322); And connecting the first row left-right direction linking member 321 and the second row left-right direction linking member 322 by the front-rear direction connecting member 310. [

The first row left-right direction connecting member 321 and the second row left-right direction connecting member 322 are installed at the upper ends of the first row thumb pile 100 and the second row thumb pile 200, Direction connecting member 310 may be installed on the first row left-right direction connecting member 321 and the second row left-right direction connecting member 322.

The present invention proposes a two-row thumb pile cladding method which can sufficiently resist the earth pressure of the back soil and suppress the occurrence of the overall displacement of the cladding structure even when performing a severe trenching operation.

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

As shown in FIG. 2 and subsequent drawings, the thumb pile retention method according to the present invention is basically composed of the following processes.

The first row thumb pile 100 is inserted along the boundary line of the excavation region 1 and the second row thumb pile 200 is inserted at the outer side of the first row thumb pile 100 ).

The first row of thumb piles 100 and the second row of thumb piles 200 are interconnected by a connecting member 300 so as to act integrally (FIG. 3).

More specifically, when the first row of thumb piles 100 and the upper portion of the second row thumb pile 200 are exposed on the ground by the progress of the tearing, the first row left-right direction connecting member 321 and the first row left- And the front-rear direction connecting member 310 is installed on the upper portion of the first row left-right direction connecting member 321 and the second row left-right direction connecting member 322, desirable.

The excavation region 1 is excavated and the earth retaining member 10 is sequentially installed between the first row thumb piles 100 to form a retaining structure (FIGS.

The lacquer 400 is installed on the retaining structure (Figs. 4 and 5).

That is, in addition to the retaining structure in which the earth retaining member 10 is installed on the first row thumb pile 100, the second row thumb pile 200 is inserted into the outer side and the first row thumb pile 100 is moved in unison with the retaining structure And the lacquer 400 is installed on the retaining structure of the first row thumb pile 100 to reinforce it.

This has the following advantages as compared with the conventional conventional earth retaining method.

First, since the second row thumb pile 200 serves as a constraining pile for preventing the shear failure of the rear soil body, the displacement of the retaining structure can be minimized.

Secondly, the composite structure of the second row thumb pile 200 and the lacquer 400 minimizes the reinforcement to the back surface, while the overall construction of the retaining pillar 200 and the lacquer 400, The structural stability of the structure can be sufficiently secured.

Third, the first row thumb pile 100, the second row thumb pile 200, the connecting member 300, and the lacquer 400 behave as a single body so that the strength of each member can be sufficiently exhibited, And it is economical because it is possible to use a high-grade tough material while using a positive material.

Hereinafter, concrete examples of the construction of the lacquer 400 will be described.

The lacquer installing step basically includes a rake top fixing step of fixing the upper end of the lacquer 400 to the securing structure; Forming a laker support part (410) on a bottom surface of the excavation area (1); And a lower lacquer fixing step of fixing the lower end of the lacquer 400 to the lacquer supporting portion 410.

The method of installing the lacquer 400 on the retaining structure may be either a method of installing the lacquer 400 on the wale band or a method of directly installing the lacquer 400 on the first row thumb pile 100 without wales. Since the first row of thumb piles 100 is loaded with a large load by the second row thumb pile 200 and the connecting member 300, And the lacquer 400 is installed thereon.

That is, it is preferable to provide a wristband 420 in front of the first row of thumb piles 100 and fix the upper end of the lacquer 400 to the wristband 420 (FIGS. 4 and 5).

5, the lacquer supporting portion 100 is constructed such that the supporting pile 411 is vertically inserted and the supporting pile 412 is installed in the upper portion of the supporting pile 411 in the left and right direction, It is preferable that the concrete block 413 is formed by placing concrete around the support pile 411 and the support pile 412 and that the lower end of the lakere 400 is supported by the upper support pile 412, Do.

In the case of a soft ground, it is advisable to add a step of strengthening the ground by injecting a strengthening agent into the surrounding ground of the support pile 411.

Hereinafter, referring to Figs. 6 and 7, description will be given of an embodiment relating to the case where the inclined surface 2 is formed.

It is preferable to further include a step of excavating the inclined surface 2 facing inward between the first row thumb pile 100 and the second row thumb pile 200 in the formation of the upper retaining structure.

7, it is possible to form a retaining structure between the first row of thumb piles 100 and the second row of thumb piles 200 in comparison with the conventional retaining structure, And the inclined surface 2 is formed on the upper portion.

In other words, when the method according to the present embodiment is applied, the structure in which the masses corresponding to the upper region S of the slope 2 are removed can be obtained as compared with the conventional structure, When a material having a high strength is used, a more advanced retention structure can be obtained, and when the retention structure with the same depth is used, the material can be saved.

The region between the first row of thumb piles 100 and the second row of thumb thumb piles 200 is formed in the inner side to a limit depth L forming a slope having a stable inclination, It is preferable to excavate the excavation region 1 to its limit depth L (Fig. 6).

After the limit depth L, the soil retaining member 10 is installed on the first row thumb pile 100 and the lakers 400 are installed as described above (FIG. 7).

8 to 10 illustrate another embodiment of the two-row thumb pile cladding method according to the present invention.

This is basically the same as the above embodiment, but the step of forming the inclined surface is somewhat different.

The inclined plane forming step in this embodiment is configured as follows.

The area between the first row thumb pile 100 and the second row thumb pile 200 and the excavation area 1 are excavated up to the first design depth H1, And a two-column earth retaining member 20 is installed (Fig. 8).

Below the first design depth H1, the area between the first row of thumb piles 100 and the second row of thumb piles 200 is inclined inward to the second design depth H2, which forms a stable slope, In addition, the excavation area 1 is excavated up to the secondary design depth H2 (FIG. 9).

Below the secondary design depth H2, the soil retaining member 10 is installed on the first row of thumb piles 100, and the lakers 400 are installed as described above (FIG. 10).

10 may be formed on the upper sloped surface 2 between the first row of thumb piles 100 and the second row of thumb piles 200. In this case, Another second heat retaining structure is formed.

The second heat retaining structure serves to stabilize the inclined surface 2 formed between the first heat thumb pile 100 and the second heat thumb pile 200 so that the upper region S of the inclined surface 2 is formed, As shown in Fig.

Therefore, since the structure in which the mass of the region S is removed more than in the embodiment of FIG. 7 can be obtained, a greater earth pressure reduction effect can be obtained. Therefore, when the same strength material is used, It is possible to obtain a retaining structure of the same depth, and in the case of constructing the retaining structure of the same depth, the effect of saving the material can be further increased.

Hereinafter, referring to FIGS. 4 and 5, an embodiment of the connecting member 300 applied to the connecting step will be described.

The connecting member 300 connects the first row thumb pile 100 and the second row thumb pile 200 so that the first row thumb pile 100 and the second row thumb pile 200 are integrated with each other. In order to minimize the occurrence of the displacement, it is preferable that the front and rear connecting members 310 interconnect the first heat thumb pile 100 and the second heat thumb pile 200 with each other.

The front-and-back connecting member 310 may connect the thumb piles 100 and 200 of the plurality of first heat thumb piles 100 and the second heat thumb piles 200 to each other, In order to increase the structural stability, it is more preferable to take the whole integrated structure as follows.

That is, the first row of thumb piles 100 are interconnected by a first row lateral linking member 321 and the second row of thumb-piles 200 are interconnected by a second row lateral linking member 322 The first row left-right direction connecting member 321 and the second row left-right direction connecting member 322 are interconnected by the front-rear direction connecting member 310.

In order to solve the problem of the above-mentioned top head displacement, the first row left-right direction connecting member 321 and the second row left-right direction connecting member 322 may be formed of the first row thumb pile 100 And the front-rear direction connecting member 310 is installed on the upper part of the first row left-right direction connecting member 321 and the second row left-right direction connecting member 322 It is preferable to adopt a configuration.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

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

2 to 10 are views for explaining a two-row thumb pile retention method according to the present invention,

2 to 4 are process drawings of the first embodiment.

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

6 and 7 are process drawings of the second embodiment.

8 to 10 are process drawings of the third embodiment.

DESCRIPTION OF REFERENCE NUMERALS

1: excavation area 2: slope

10: earth retaining member 100: first row thumb pile

200: second row thumb pile 300: connecting member

310: front-rear direction connecting member 321: first-row left-right direction connecting member

322: second row left-right direction connecting member 400:

410: lacquer supporting part 411: support pile

412: support file 413: concrete block

420: Welt L: Limit depth

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

Claims (11)

A first row of thumb pegs adjacent to the first row of thumb piles 100 along a boundary line of the excavation region 1; A second row of thumb thumb piles adjacent to the second row of thumb thumb piles 200 spaced apart from the first row of thumb thumb piles 100; A connecting step of interconnecting the first heat thumb pile 100 and the second heat thumb pile 200 by the connecting member 300 so that the first heat thumb pile 100 and the second heat thumb pile 200 integrally move; Forming an earth retaining structure by excavating the excavation region (1) and installing a securing member (10) between the first heat thumb piles (100) to form a securing structure; And a lacquer installing step of installing a lacquer (400) on the retaining structure, The retaining structure forming step The method of claim 1, further comprising: forming an inclined surface (2) between the first heat thumb pile (100) and the second heat thumb pile (200) The slope forming step The area between the first heat thumb pile 100 and the second heat thumb pile 200 and the area between the first heat thumb pile 200 and the second heat thumb pile 200 while excavating the excavation area 1 to the first design depth H1. Forming a second thermal retention structure by providing a second thermal retention member 20 between the first and second thermal retention members; Below the primary design depth H1, the area between the first row of thumb piles 100 and the second row of thumb piles 200 is sloped inward to the second design depth H2 forming a stable slope And excavating the excavation area (1) to the secondary design depth (H2). The method according to claim 1, The laker installation step A rake top fixing step of fixing the upper end of the lacquer 400 to the securing structure; Forming a laker support part (410) on a bottom surface of the excavation area (1); And fixing the lower end of the lacquer (400) to the lacquer supporting part (410); A two-row thumb pile retention method using a lacquer characterized by comprising 3. The method of claim 2, The rake top settlement step Installing a wale 420 in front of the first row thumb pile 100; Fixing the upper end of the laker (400) to the wristband (420); A two-row thumb pile retention method using a lacquer characterized by comprising 3. The method of claim 2, The lacquer support forming step Supporting the pile 411 vertically; Installing a support pile (412) in a lateral direction on the upper end of the support pile (411) to support the lower end of the laker (400); Forming a concrete block 413 by placing concrete around the support pile 411 and the support pile 412; A two-row thumb pile retention method using a lacquer characterized by comprising 5. The method of claim 4, The lacquer support forming step Further comprising the step of injecting a reinforcing agent into the surrounding ground of the support pile (411). delete delete delete 6. The method according to any one of claims 1 to 5, The connecting step And the upper part of the first heat thumb pile 100 and the upper part of the second heat thumb pile 200 are connected to each other by the front and rear direction connecting member 310. [ 10. The method of claim 9, The connecting step Interconnecting the first row thumb piles 100 by a first row lateral linking member 321; Interconnecting said second row thumb piles (200) by a second row lateral linking member (322); Connecting the first row left-right direction connecting member 321 and the second row left-right direction connecting member 322 by the front-rear direction connecting member 310; A two-row thumb pile retention method using a lacquer characterized by comprising 11. The method of claim 10, The first row left-right direction connecting member 321 and the second row left-right direction connecting member 322 are installed at the upper ends of the first row thumb pile 100 and the second row thumb pile 200, The front-and-rear direction connecting member 310 is installed on the first row left-right direction connecting member 321 and the second row left-right direction connecting member 322.

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