KR101782840B1 - A Top Down Method of deploying Underground Structures - Google Patents

Abstract

The present invention relates to a method for constructing an underground structure using a top-down construction method and, more specifically, relates to a method for constructing an underground structure using a top-down construction method capable of rapidly executing a construction by executing a construction for installing a ground structure on the ground and a construction for installing the underground structure underground at the same time. The method for constructing the underground structure using the top-down construction method includes: (1) a step of flattening the ground; (2) a step of forming a frame structure (100) having columns and beams on the flat ground; (3) a step of connecting a central column (210) of an underground floor to the central column of the frame structure (100); (4) a step of connecting outer columns (220) of the underground floor to the outer columns of the frame structure (100); (5) a step of forming a retaining wall connection unit (300); (6) a step of forming a retaining wall (400); (7) a step of waterproofing an inner surface (inner parts of a building) of the retaining wall (400) by connecting a waterproof fabric; and (8) a step of forming an outer wall of the underground floor.

Description

[0001] The present invention relates to a method of constructing an underground structure of a top down method,

The present invention relates to a method of constructing an underground structure in a tower-down method, and more particularly, to a method of constructing an underground structure in a tower-down method, And the earth retaining wall is formed by drilling the column downward between the column and the column and connecting the plates to each other.

Conventionally, various types of building construction work has been mainly applied to the construction of retention type retention pavement. In the construction work using the retention type retention pavement construction method, a thumb pile is installed in the ground along a planned excavation planning line in the relevant area, And the earth slabs were placed in succession from the excavated foundation floor in the earth retaining wall with the outer wall body in order to construct the present structure.

This is because, when the underground structure of the building is constructed, it is separated from the work of installing the retention type wall structure and the construction of the main structure, so that it does not require any special equipment or technical skill, Has been extensively used in construction sites.

However, there is a problem that construction of such a building using the retention type retaining structure is vulnerable to construction of a large underground structure in which excavation depth and excavation depth are increased due to the earth pressure surrounding the earth pressure applied during the first construction In the urban area where the second building is densely built up, it is impossible to compose perfectly outside of the retaining wall. Therefore, there is a problem of damage to the surrounding buildings due to the deformation and settlement of the stratum. Thirdly, an unnecessary work space is secured between the retaining wall and the under- There is a problem that the volume ratio of the underground structure is reduced and the construction period is extended as the construction of the structure is performed only after the installation of the earth retaining wall is completed.

In order to solve the above problems, various types of TOP DOWN methods have been widely used in the construction site. One of them is a method of installing the composite columns fixed to the ground in the underground building zone, The underground structural part is constructed so as to carry out a construction work on the upper part of the ground with the upper part of the columns as a boundary, And the deck plate was fixed to the exposed rear side of the synthetic column to install the earth retaining wall and the soil slab was put back together with the synthetic wall to the foundation floor so as to be integrated with the retaining wall, Down method is known.

1A and 1B, the synthetic wall 110 and the ground slab 120 are integrally formed as a unit with the earth retaining wall 110 at the time of constructing the underground structure 100, The synthetic wall body 120 and the stratum slab 130 are installed in parallel with the installation work of the earth retaining wall 110 so as to shorten the construction period and the construction wall 110 is integrally formed with the earth retaining wall 110 It is true that the synthetic wall body 120 has an advantage of being able to construct an underground structure as a solid structure corresponding to the surrounding earth pressure.

However, the conventional tower-down method using the earth retaining wall has the following problems.

First, the synthetic column 140, which is subject to unreasonable vertical loads due to the self weight of the composite wall 120 and the stratum slab 130, buckles or sinks, and collapse may occur during the construction of the underground structure.

Second, in order to install the deck plate 150 on the rear surface of the composite column 140, the work is performed so that the composite column 140 itself fixed to the ground is fully received, so that the workload of the work is increased. In the case of the ground formed, the difficulty of excavation work is increased and the work efficiency is lowered.

Third, when the synthetic columns 140 fixed in the ground have poor verticality, there is a problem that the inside space of the synthetic wall 120 is invaded into a predetermined designed area to maintain the verticality of the synthetic wall 120 itself.

Fourth, excavation for installing the earth retaining walls is performed at a time, so that equipment capable of deep excavation must be mobilized, and there is a problem of equipment mobilization such as injection of bentonite to prevent collapse of the excavated portion, and the cost thereof is excessive.

Korean Patent Registration No. 0157086 (Jul. 28, 1998)

A problem to be solved by the method of constructing an underground structure of the tower-down method of the present invention is as follows.

First, we try to solve the problem that the synthetic column which is subjected to unreasonable vertical load due to the composite walls and the stratum slab self-weight buckles or sinks and collapses during the construction of the underground structure.

Second, the workload of the deck plate for the deck plate is increased, and the work efficiency is lowered due to the difficulty in excavation work in the case where the rock layer is formed near the ground.

Third, to solve the problem of narrowing the underground space by penetrating into the planned design area to maintain the verticality of the composite wall itself.

Fourth, we want to solve the problem of mobilization of equipment for installation of earth wall and its excessive cost.

In order to achieve the above object, the method of constructing an underground structure of a top down method of the present invention is a method of constructing an underground structure on the ground with the ground of the site as a boundary, A method of constructing an underground structure of a top-down construction method for rapidly advancing a construction work, the method comprising the steps of: (1) planarizing a surface of the site; (2) forming a frame structure having a column and a beam on the ground of the planarized sheet in the step (1); (3) connecting the center underground pillar to the pillar of the frame structure by excavating the lower ground of the pillar center pillar formed in step (2) downward; (4) sequentially excavating the lower ground of each of the outer pillars of the frame structure formed in step (2) downward to connect the outer basement pillar to the outer pillars of the frame structure; (5) forming an earth retaining wall connection portion by connecting the plate outer side of the outer basement pillar formed in the step (4) with the plate; (6) forming an earth retaining wall by connecting the earth retaining wall connection portion formed in the step (5) to an outer side plate; (7) waterproofing the inner surface of the earth retaining wall formed in step (6) by connecting a tarpaulin thereto; And (8) a reinforcing bar is placed on the inner surface of the retaining wall and the basement pillar side where the waterproofing step of the step (7) is finished, and the inner side plate covering the reinforced steel rope is connected to the inside of the building of the underground pillar And forming an outer wall of the underground layer by pouring concrete into a space in which the reinforcing bars between the earth retaining wall and the inner side plate are laid.
In addition, the frame structure forms a beam and a beam with an H-shaped beam, and the column and the beam are connected by welding after being bolted, and the frame structure is composed of two or three layers to suppress deformation of the frame structure.
Further, the outer excavating ground and connection for connecting the outer poles of the lower ground floor beams and the framework structure comprises: (4-1) digging a pole outside the basement after the bottom ground of the pole to be formed at one vertex of the framework structure in the downward direction To a column formed at one vertex of the frame structure; (4-2) Excavating the lower ground of the other pillar formed at the vertex opposed diagonally to one vertex of the frame structure of the step (4-1) in the downward direction, ) To another column formed at a vertex opposed diagonally to one vertex of the frame structure of the frame structure; (4-3) After excavating the lower ground of the column formed at one vertex adjacent to one vertex of the frame structure of the step (4-1) downward, Connecting a vertex adjacent to a vertex of the frame structure to a vertex formed at a vertex adjacent to the vertex; (4-4) After lowering the lower ground of the column formed at the vertex opposed diagonally to one vertex adjacent to one vertex of the frame structure of the step (4-1) Connecting a vertex adjacent to one vertex of the frame structure of step (4-1) to a vertex opposed to a vertex diagonally opposite the vertex; (4-5) After lowering the lower ground of the column formed between one vertex of the frame structure and adjacent vertexes of the step (4-1) in the downward direction, Connecting one vertex of the frame structure and one vertex adjacent to the vertex of the frame structure; (4-6) After lowering the lower ground of the column facing the column formed between one vertex of the frame structure and adjacent vertexes in the step (4-1), the outer ground floor column A step of joining a vertex of the frame structure of the step (4-1) and a column formed so as to face a column formed between adjacent vertexes; (4-7) After excavating the lower ground of the column formed between one vertex of the frame structure and adjacent vertexes of the frame structure of the step (4-1) in the downward direction, ) With a vertex adjacent to another vertex of the frame structure; And (4-8) a lower ground of a column formed to face a column formed between one vertex of the frame structure and adjacent vertexes in the step (4-1), and then, To a column formed to face a column formed between one vertex of the frame structure and adjacent vertexes of the step (4-1).
In addition, the connection between the pillars of the frame structure and the basement column may be sequentially performed for each layer, and the basement column of the lowest layer may be formed so as to form a foundation for each basement column.
In addition, the earth retaining wall connection portion has a shape or a C shape, and the inner surface of the wall connecting portion having the a shape is connected to the column formed at the vertex of the frame structure, and the inner surface of the earth retaining wall connection portion are each other between and connected to the pillar formed between il vertex and another vertex of the framework structure, the outer side plate is vertically and horizontally, and the flat plate shape of 1~1.5m, the retaining wall connecting to the outer plate To form an earth retaining wall. The earth retaining wall is formed on the excavated part after excavating 1 ~ 2m of the ground in the downward direction, and 1 ~ 2m ground is excavated in the lower direction and then a retaining wall is formed on the excavated part , The earth retaining wall can be completed.

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The method of constructing the underground structure of the tower-down method according to the present invention has the following effects.

First, there is a problem that a composite column subjected to unreasonable vertical load due to the weight of the conventional composite wall and stratum slab buckles or sinks to cause collapse during construction of the underground structure. However, So that it is possible to prevent the collapse accident of the synthetic column due to an unreasonable load in the past.

Second, because the workload of the excavation can be reduced through the installation of the earth retaining wall by connecting the excavated plate to the downward direction of the ground, the construction cost and construction time can be saved, which is efficient.

Third, it is possible to determine the verticality of each connection operation of the column, thereby eliminating the narrow problem of the underground space caused by the penetration into the designed area.

Fourth, because it is possible to excavate pillar connection and installation of earth retaining wall by using conventional excavator (forklane), separate equipment for deep excavation is not necessary and it is efficient in terms of cost and equipment mobilization.

Fifth, it is possible to integrate the basement pillar and the retaining wall, and to make the outer wall of the retaining wall as the outer surface, and the outer wall and the basement pillar can be integrated with the reinforcement and concrete curing in the inside.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a longitudinal sectional view schematically showing the essential part of the background art. Fig.
Fig. 2 is a cross-sectional view schematically showing the essential part of the background art. Fig.
3 is a flowchart schematically illustrating a method of constructing an underground structure of a tower-down method according to an embodiment of the present invention.
4 is a flowchart schematically showing a connection between a pillar of a basement pillar and a pillar structure and an order of excavation thereof in a method of constructing an underground structure of a tower-down method according to an embodiment of the present invention.
5 is a cross-sectional view schematically showing a connection between a pillar of a frame structure and a pillar of a basement floor in the center of a tower-down construction method according to an embodiment of the present invention and its excavation.
FIG. 6 is a cross-sectional view schematically illustrating a method of constructing an underground structure of a tower-down method according to an embodiment of the present invention, connecting a column of a frame structure with a basement column, and excavating and installing the earth retaining wall.
FIG. 7 is a plan view schematically illustrating a connection between a column of a frame structure and a column of a basement layer in the method of constructing an underground structure of a tower-down method according to an embodiment of the present invention.
8 is a plan view schematically illustrating an earth retaining wall in a method of constructing an underground structure in a tower down method according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order that those skilled in the art can easily carry out the present invention. In the following detailed description of the preferred embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In the drawings, like reference numerals are used throughout the drawings.

Incidentally, in the entire specification, when a part is connected to another part, it includes not only a direct connection but also a case where the other part is indirectly connected with another part in between. Also, to include an element means that it may include other elements, not excluding other elements unless specifically stated otherwise.

FIG. 3 is a flowchart schematically illustrating a method of constructing an underground structure according to an embodiment of the present invention. FIG. 4 is a flowchart illustrating a method of constructing an underground structure according to an embodiment of the present invention, FIG. 5 is a flowchart illustrating a connection and an excavation procedure of a column of a frame structure according to an embodiment of the present invention. FIG. 5 is a flowchart illustrating a method of constructing an underground structure of a tower- Sectional view schematically showing excavation. 6 is a cross-sectional view briefly showing a connection between a column of a frame structure and a basement column, a method of excavating the same, and a method of installing the earth retaining wall in a method of constructing an underground structure according to an embodiment of the present invention. FIG. 8 is a plan view schematically showing a connection between a column of a frame structure and a basement column and an excavation procedure in the method of constructing an underground structure according to an embodiment of the present invention. The earth retaining wall will be briefly described as a plan view.

The conventional tower-down method has a possibility that a synthetic column 140 subjected to excessive vertical load due to the self-weight of the synthetic wall 120 and the stratum slab 130 buckles or sinks to collapse during the construction of the underground structure, In order to install the deck plate 150 on the rear surface of the synthetic column 140, the work is carried out such that the synthetic column 140 itself fixed to the ground is completely received , in the case of formed ground there was a problem of the difficulty the weight decreases the work efficiency of the drilling operations, when the composite column fixation in the ground are poor the verticality has invaded into the intended design area to maintain the verticality of the composite wall itself And the problem of narrowing the underground space. In addition, since the excavation for installing the earth retaining walls is performed at a time, equipment for deep excavation must be mobilized, and there is a problem of equipment mobilization such as injection of bentonite to prevent collapse of the excavated portion, The present invention is presented to solve this problem. Let's take a closer look at the steps below.

As shown in FIG. 3, in the method of constructing an underground structure of a tower down method according to an embodiment of the present invention, a ground structure is constructed on the ground with the ground of the site as a boundary, A method of constructing an underground structure of a top-down construction method for allowing a construction work to proceed quickly by performing a long underground structure construction, comprising the steps of: (1) planarizing a surface of the site; (2) forming a frame structure 100 having pillars and beams on the ground of the planarized floor in the step (1); (3) connecting the center underground pillar 210 to the center column of the frame structure 100 by drilling the lower ground of the pillar at the center of the pillar structure 100 formed at step (2) downward; (4) sequentially excavating the lower ground of each of the outer pillars of the pillar structure 100 formed in the step (2) downward to connect the outer pillar foundation 220 to the outer pillars of the pillar structure 100 ; (5) forming the earth retaining wall connection portion 300 by connecting the plate outer side of the outer basement pillar 220 formed in the step (4) with the plate; (6) forming the earth retaining wall 400 by connecting the earth retaining wall connection part 300 formed in the step (5) to the outer side plate; 7, the steps of water by connecting the tarpaulin to the inner surface (the surface is facing the building interior side) of the retaining wall 400 is formed in the above step (6); And (8) placing a reinforcing bar on the inner surface side of the earth retaining wall 400 after the waterproofing step of step (7) has been completed, placing the inner side plate covering the reinforced steel rods on the inner side of the building of the underground pillar 220 And forming an outer wall of the underground layer by pouring concrete into a space in which the reinforcing bars between the outer plate and the inner plate are arranged.

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The steps will be described in detail below.

(1) Site planarization step

The step (1) is a step of flattening the ground surface of the site, and flattening the ground surface by compaction if necessary. This planarizing operation is necessary because the upper frame structure 100 is mounted on the ground and therefore needs to be kept horizontal. It can be performed in the same manner as the stop operation of the ground during the construction of a typical building.

(2) Formation of mold structure 100

The step (2) is a step of forming the frame structure 100, and the frame structure 100 having pillars and beams on the ground of the planarized ground in the step (1) is formed. The frame structure 100 serves as a foundation and a skeleton of the ground structure, and serves as a framework for the construction of the underground structure. The ground structure part can be installed on the upper part of the frame structure 100 as an outer shape, and the underground structure part gradually goes to the lower part of the frame structure 100. The reason why the frame structure 100 is formed is that the vertical and horizontal portions are maintained as a frame so that the vertical and horizontal portions do not slip or slip out in the process of sequentially excavating from the center portion to the outer diagonal portion in the method of constructing an underground structure of the present invention.

The frame structure 100 forms a beam and a beam with an H-shaped beam, and the beam and the beam are connected by welding after the bolt is bolted to the frame structure 100. The frame structure 100 includes two or three layers to suppress the deformation of the frame structure 100 . The frame structure 100 should be able to maintain the outer shape when digging the basement , so that the central underground pillar 210 and the outer basement pillar 220 can be connected in a vertical state after the pillar is excavated. Therefore, a frame which does not cause such structural deformation must be formed, and it may be composed of two to three layers, preferably two layers. It should not only provide structural stability but also be stable against vertical loads. Therefore, in the case of four or more layers, structural instability may occur because the vertical load becomes excessive as compared with the structural stability of the frame structure 100.

(3) Excavation and connection of the center underground pillar 210

In the step (3) , the lower ground of the central underground pillar 210 of the pillar structure 100 formed in the step (2) is downwardly excavated so that the pillar 210 of the center underground is pierced on the pillar of the pillar 100 It is a connecting step. This is to support the frame structure 100 by first joining the center portion to the excavated ground and the center underground pillar 210 first. Subsequently, by connecting the sub-basement pillars 220 located at the outskirts, the underground structure can be formed while the foundation structure 100 is structurally stabilized while the basement layer is being excavated.

(4) Excavation and connection of the central underground pillar 220

It said step (4) is outside the basement group round 220, the frame structure (100 a central portion basement pillar 210 by drilling each of the lower ground in the downward direction in order of the frame structure 100 formed in the above step (2) ) Of the outer column. This is done in the following procedure as a method for installing the subterranean basement pillar 220 located at each outskirt after the center basement pillar 210 is formed in the step (3). This is to ensure the structural stability of the frame structure 100.

The ground excavation and connection for connecting the outer basement pillar 220 to the columns of the frame structure 100,

(4-1) A lower ground of a column formed at a vertex of the frame structure 100 is downwardly excavated and an outer ground floor column 220 is connected to a column formed at a vertex of the frame structure 100 ; 4-2, the frame structure 100, one vertex and then excavate the lower ground of the other poles formed on the vertex facing diagonally downward outside the basement pillar 220 of the step (4-1) Connecting to another column formed at a vertex opposed diagonally to one vertex of the frame structure 100 of the step (4-1); (4-3) After the excavation of the ground of the bottom of the column to be formed to an apex adjacent to one vertex of the framework structure 100 in the downward direction, outside the basement pillar 220 of the step (4-1) Connecting a vertex adjacent to one vertex of the framework structure 100 of step (4-1) to a vertex formed at one vertex; (4-4) After lowering the lower ground of the column formed at the vertex opposed diagonally to one vertex adjacent to one vertex of the frame structure 100 in the step (4-1), the upper ground floor Connecting the column 220 to one vertex adjacent to one vertex of the framework structure 100 of the step (4-1) and a column formed at a vertex opposed diagonally; (4-5) After lowering the lower ground of the column formed between one vertex and adjacent vertex of the frame structure 100 in the step (4-1), the outer ground floor column 220 is cut Connecting a vertex of the frame structure 100 of the step (4-1) to a vertex adjacent to one vertex of the frame structure 100; (4-6) After the excavation of the ground of the bottom pillar is formed so as to face the pillar formed between one vertex and one neighbor vertex of the framework structure 100 of the step (4-1) in the downward direction, the outer Connecting the basement pillar 220 to a vertex of the framework structure 100 of the step 4-1 and a column formed to face a vertex formed between adjacent apexes of the framework structure 100; (4-7) After excavating the lower ground of the column formed between one vertex of the framework structure 100 and the other vertexes of the step (4-1) in the downward direction, the outer basement pillar 220 Connecting a vertex of the mold structure 100 of the step (4-1) to a vertex adjacent to one vertex of the mold structure 100; And (4-8) the lower ground of the column formed to face the column formed between one vertex of the frame structure 100 and adjacent vertexes of the step (4-1) in the downward direction, And a step of connecting the subterranean pillar 220 on the outer side with the vertex of the mold structure 100 of the step (4-1) and the column formed to face the pillar formed between adjacent vertexes of the mold structure 100 have.
That is, as shown in FIG. 5, starting with the installation of the center underground pillar 210, steps 1, 2, 3, 4, 5, 6, 7, At this time, 2 and 3 can be performed in the reverse order, and 4 and 5 can be performed in the reverse order. This is the same for 6 and 7, 8 and 9. 2 and 3 as a pair and 4 and 5 as a pair, a pair of 2 and 3 and a pair of 4 and 5 can be performed in the reverse order. A pair of 4 and 5 may be performed first and a pair of 2 and 3 may be performed later. If 6 and 7, 8 and 9 are also a pair, each pair can be performed in reverse order as well. That is, diagonally opposed or opposed columns may be paired and the order of the paired columns may be changed, or the order may be reversed between the pairs of diagonally opposed or opposed columns. However, it is not possible to change the order in which the center underground column 210 is first performed, then the diagonally opposite column pairs are performed, and finally, the column pair between the vertexes is performed. This is to allow the frame structure 100 to have structural stability while the underground layer is being squeezed.

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The connection between the column of the frame structure 100 and the central underground pillar 210 and the underground pillar 220 is sequentially carried out for each layer and the connection between the lower basement pillar 210 and the lower basement pillar 210 220 may be respectively formed to form a foundation. 5, 6, 7, 8, and 9 in the above-described FIG. 5, in which the excavation of one layer and the excavation of the center underground pillar 210 and the outer underground pillar 220 When the connection is completed, the next layer is performed. In the bottom layer, the base is formed at the bottom of the column so that each column can transmit the load to the ground, so that the structural stability is achieved.

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(5) Formation of the earth retaining wall connection portion 300

The step (5) is a step of forming the earth retaining wall connection part 300 by connecting the plate with the basement pillar 220 formed in the step (4). The earth retaining wall connection part 300 is connected to the outer side of the outer basement pillar 220 and the earth retaining wall connection part 300 is connected to the outer side plate to form the earth retaining wall 400. The outer basement pole 220 and the retaining wall connecting portion (300) and a a shape to c-shaped, the inner surface of the retaining wall connecting to a a shape (building interior side) is formed at the vertex of the framework structure 100 And the inner surface of the earth retaining wall connection portion having a C shape may be connected to a column formed between one vertex and the other vertex of the framework structure 100. The a-shaped earth retaining wall connection portion can be formed as a corner of the outer wall of the building naturally when it is connected to the column formed at the vertex of the frame structure 100. The U-shaped earth retaining wall connection part is connected to the column formed on the line connecting the vertexes of the frame structure 100, and it is formed so as to surround the column so as to be formed into a natural column shape. When the retaining wall 400 is completed, the outer wall is formed by pouring the concrete. The pillar and the outer wall can be formed by the reinforcement and the concrete pouring without a separate form, which is effective in the shortening of the air and the construction cost.

(6) Formation step of the earth retaining wall 400
In the step (6), the earth retaining wall 400 is formed by connecting the earth retaining wall connecting part 300 formed in the step (5) to the outer side plate. The outer side plate has a shape of a flat plate having a width of 1 to 1.5 m and a length of 1 to 1.5 m, and the earth retaining wall 400 is formed by connecting the earth retaining wall connecting portion and the outer side plate to each other. The earth retaining wall 400 is formed on the excavated part and the ground 1 ~ 2m is excavated in the lower direction and then the earth retaining wall 400 is formed on the excavated part, ) Can be completed. In other words, it is possible to install the earth retaining wall 400 while gradually moving from the ground to the downward direction. In this method, equipment for excavating deep and narrow passages is not separately required, and in addition , So that the safety and efficiency of the earth retaining work can be achieved.
That is , the upper and lower basement pillar 220 and the outer basement pillar 220 are slid downward for 1 to 2 m, and the outer side plate is connected to the excavation wall 400, (400) is installed in a manner as described above.

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(7) Waterproofing step
The step (7) is a step of connecting the tarpaulin to the inner surface (inside the building ) of the earth retaining wall 400 formed in the step (6) to waterproof it. There are groundwater leaks and ground collapse due to the fact that caulking works. Therefore, waterproofing is connected to waterproofing to prevent leakage of groundwater.

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(8) External wall forming step

The step (8) is an outer wall forming step, in which a reinforcing bar is disposed on the inner side (inside of the building) and the outer basement pillar (220) side of the earth retaining wall (400) The inner side plate covering the reinforced bar is connected to the outer basement pillar 220 and the concrete is installed in the space where the reinforcing bars between the outer side plate and the inner side plate are laid to form the basement outer wall. In the present invention, the outer wall and the column can be integrated with each other by reinforcing the inner wall of the earth retaining wall 400 and the outer wall of the underground pillar 220, and by reinforcing the reinforcing bars and curing the concrete, To be an outer surface. The inner surface of the outer wall can be formed by connecting an inner side plate having the same shape as the outer side plate. By pouring concrete into the space between the inner side plate and the outer side plate, it is possible to form the outer wall by curing.

The method of constructing an underground structure according to an embodiment of the present invention as described above is a method of constructing an underground structure according to an embodiment of the present invention in which a composite column subjected to an excessive vertical load due to the self weight of a conventional composite wall and a stratum slab buckles or sinks, The present invention can prevent the risk of collapse of the synthetic pillars due to an unreasonable load in the past, and it is possible to prevent the collapse of the synthetic pillars due to the excessive load It is possible to reduce construction cost and construction time due to the reduction of the workload of the excavation work through the installation of the earth wall after the excavation, and it is possible to judge the vertical degree for each connection work of the column. It is possible to exclude the narrow problem of the underground space that occurs due to the invasion. In addition, it is possible to excavate pillar connection and installation of earth retaining wall by using conventional excavator (forklraining), so it is efficient in terms of cost and equipment mobilization because separate equipment for deep excavation is not necessary, and the basement pillar and earth retaining wall are integrated And it is possible to integrate the outer wall and the basement column with the reinforcing steel reinforcement and the concrete curing in the inside while making the earth retaining wall to be the outer surface of the outer wall, thereby providing the structural stability.

The present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics of the invention.

100: Frame structure 210: Center basement pillar
220: Suburban basement pillar 300: Earth retaining wall connection part 400: Earth retaining wall

Claims (5)

delete delete Construction of underground structure of top-down construction method is carried out so that construction of ground structure is proceeded on the ground with the ground of the site as boundary, In this case,
(1) a leveling step of leveling the ground of the site;
(2) forming a frame structure 100 having pillars and beams on the ground of the planarized floor in the step (1);
(3) connecting the center underground pillar 210 to the center column of the frame structure 100 by drilling the lower ground of the pillar at the center of the pillar structure 100 formed at step (2) downward;
(4) sequentially excavating the lower ground of each of the outer pillars of the pillar structure 100 formed in the step (2) downward to connect the outer pillar foundation 220 to the outer pillars of the pillar structure 100 ;
(5) forming the earth retaining wall connection portion 300 by connecting the plate outer side of the outer basement pillar 220 formed in the step (4) with the plate;
(6) forming the earth retaining wall 400 by connecting the earth retaining wall connection part 300 formed in the step (5) to the outer side plate;
(7) connecting the tarpaulin to the inner surface (inside the building) of the earth retaining wall 400 formed in the step (6) to waterproof it; And
(8) A reinforcing bar is disposed on the inner surface (inside of the building) and the outer basement pillar (220) side of the earth retaining wall (400) after the waterproofing step of step (7) And forming an outer wall of the underground layer by pouring concrete into a space in which a reinforcing bar between the earth retaining wall 400 and the inner side plate is laid,
The frame structure 100 forms a beam and a beam with an H-beam, connects the beam and the beam by welding after welding, and suppresses deformation of the frame structure 100 by two or three layers.
Soil drilling and connections for connecting the outer poles of the pole outside the basement 220 and the frame structure 100,
(4-1) A lower ground of a column formed at a vertex of the frame structure 100 is downwardly excavated and an outer ground floor column 220 is connected to a column formed at a vertex of the frame structure 100 ;
4-2, the frame structure 100, one vertex and then excavate the lower ground of the other poles formed on the vertex facing diagonally downward outside the basement pillar 220 of the step (4-1) Connecting to another column formed at a vertex opposed diagonally to one vertex of the frame structure 100 of the step (4-1);
(4-3) After the excavation of the ground of the bottom of the column to be formed to an apex adjacent to one vertex of the framework structure 100 in the downward direction, outside the basement pillar 220 of the step (4-1) Connecting a vertex adjacent to one vertex of the framework structure 100 of step (4-1) to a vertex formed at one vertex;
(4-4) After lowering the lower ground of the column formed at the vertex opposed diagonally to one vertex adjacent to one vertex of the frame structure 100 in the step (4-1), the upper ground floor Connecting the column 220 to one vertex adjacent to one vertex of the framework structure 100 of the step (4-1) and a column formed at a vertex opposed diagonally;
(4-5) After lowering the lower ground of the column formed between one vertex and adjacent vertex of the frame structure 100 in the step (4-1), the outer ground floor column 220 is cut Connecting a vertex of the frame structure 100 of the step (4-1) to a vertex adjacent to one vertex of the frame structure 100;
(4-6) After the excavation of the ground of the bottom pillar is formed so as to face the pillar formed between one vertex and one neighbor vertex of the framework structure 100 of the step (4-1) in the downward direction, the outer Connecting the basement pillar 220 to a vertex of the framework structure 100 of the step 4-1 and a column formed to face a vertex formed between adjacent apexes of the framework structure 100;
(4-7) After excavating the lower ground of the column formed between one vertex of the framework structure 100 and the other vertexes of the step (4-1) in the downward direction, the outer basement pillar 220 Connecting a vertex of the mold structure 100 of the step (4-1) to a vertex adjacent to one vertex of the mold structure 100; And
(4-8) After the excavation of the ground of the lower pillar formed's poles and facing formed between adjacent il vertex and the other vertex to the frame structure 100 of the step (4-1) in the downward direction, the outer And the step of connecting the basement pillar 220 with the column formed to face the column formed between one vertex of the frame structure 100 and adjacent vertexes of the frame structure in the step (4-1) The method of constructing the underground structure of the tower-down method. The method of claim 3,
The connection between the pillar of the framework structure 100 and the central underground pillar 210 and the underground pillar 220 is sequentially performed for each layer and the middle underground pillar 210 and the outer underground pillar 220 of the lowermost pillar Further comprising forming a foundation on each of the plurality of basement structures. 5. The method of claim 4,
The earth retaining wall connection part 300 has a shape or a C shape and an inner surface of the earth retaining wall connection part 300 having a shape is connected to a column formed at a vertex of the frame structure 100, The inner surface of the earth retaining wall connection portion 300 is connected to a column formed between one vertex and another vertex of the framework structure 100,
The outer side plate has a flat plate shape of 1 to 1.5 m in width and a vertical length of 1 to 1.5 m, and the earth retaining wall 400 is formed by connecting the earth retaining wall connecting portion 300 and the outer side plate to each other, The earth retaining wall 400 is formed on the excavated part after excavation of ~ 2m, the ground 1 ~ 2m is excavated in the lower direction again, and the earth retaining wall 400 is formed on the excavated part, And the wall (400) is completed.

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