KR20210088850A - Top-down construction method - Google Patents

Abstract

The present invention relates to a top-down construction method of an underground structure, which can minimize the depth of excavation, comprising the steps of: (a) inserting a column member into the ground; (b) installing a stop plate and a bracket; (c) continuously installing a strut; (d) installing a transverse connection beam; (e) forming a slab (S); (f) performing lower excavation of the slab; (g) lowering and installing the stop plate and the bracket; (h) repeating the steps (c) to (g) a predetermined number of times; and (i) constructing an underground outer wall.

Description

Top-down construction method of underground structures

The present invention relates to a reverse construction method of an underground structure, and more particularly, to construct a pair of braces in parallel to the upper part of the column and connect the braces and beams on both sides of the column with continuous beams so that it is easy to manufacture and advantageous for deflection When constructing an external underground wall, part of the cross-sectional heights of the supporting beam bracket, supporting beam, and supporting beam are overlapped so that the supporting beam is mounted on the upper part, thereby reducing the height of the lower member on which the supporting beam is mounted, thereby minimizing the excavation depth. It relates to the reverse construction method of the underground structure that can

In general, the method of constructing an underground structure such as the underground part of a building can be largely divided into a forward perforation method and a reverse perforation method according to the construction direction. After constructing the retaining wall, it is a method of constructing the structure sequentially by excavating to the lowest level of the basement while supporting the retaining wall with temporary supports (horizontal braces, rakers, earth anchor rock bolts, etc.) . The reverse perforation method is a method of constructing excavated soil and structures in the reverse order, going down one layer after the retaining wall is constructed. It is also called the top-down method. The reverse drilling method can shorten the construction period in parallel with excavation and ground construction, can secure structural stability by using a permanent structure as a retaining wall support, and has low noise and vibration, so it is advantageously applied to urban construction at present.

In the prior art, after the retaining wall was constructed and the column member was installed in the middle, a separate bracket was coupled to the column member and then the braces were mounted on the brackets, respectively, so there was a problem in that it could not cope with the deflection.

As the technology that is the background of the present invention, there is Patent Registration No. 1198286 "Non-wale strut system for reverse rudder support method for continuous construction of underground outer walls and reverse pounding construction method of underground structures by this" (Patent Document 1).

In the background art, while constructing the thumb piles (RW1) using flanged steel (RW11) spaced apart at a predetermined interval while constructing the earth wall (RW2) to connect between the thumb piles (RW1), the retaining wall (RW) is constructed, A first step of constructing an internal pillar (C) in the internal space of the retaining wall (RW); A second step of excavating the ground inside the retaining wall (RW); The third step of attaching and installing the mounting bracket (B1) to the flange of the flange-shaped steel (RW11) of the thumb pile, and installing the supporting beam (B2) along the retaining wall (RW) while mounting it across the neighboring mounting bracket (B1) ; Install the cheolgolbo (G), but connect both ends of the cheolgolbo (G) to the inner column (C) to connect the inner column (C) to each other, while connecting the supporting beam (B2) and the inner column (C) A fourth step of mounting one end of the cheolgolbo (G) on the support beam (B2) and attaching the other end of the cheolgolbo (G) to the inner column (C); While installing the deck plate (S1) and the slab reinforcing bar (S2) on the cheolgol beam (G) while locating it spaced apart from the retaining wall (RW), the stud bolt 140 is positioned on the deck plate (S1) while the non-wale strut system ( 100) a fifth step of installing; A sixth step of completing the slab (S) integrated with the non-wale strut system 100 by pouring the slab concrete (S3) on the deck plate (S1) with the acupressure plate members (120, 130) of the non-wale strut system as a boundary; a seventh step of repeating the second to sixth steps; Between the retaining wall (RW) and the slab (S), reinforce the wall reinforcement through the empty space between the main strut 110 and the sub-strut 150. 160 of the non-wale strut system, and pour wall concrete to ) in the eighth step of completing the bottom-up; We propose a 'reverse construction method of an underground structure by a non-wale strut system, characterized in that it consists of

However, in the background art, after attaching the mounting bracket (B1) to the flange of the flange-shaped steel (RW11) of the thumb pile and installing the supporting beam (B2) on the upper part of the mounting bracket (B1), back to the upper part of the supporting beam (B2) By allowing the cheolgolbo (G) to be mounted, the height of the members of the mounting bracket (B1), the support beam (B2) and the cheolgolbo (G) does not increase, so the excavation depth is deepened and the earth pressure is increased accordingly.

Patent Registration No. 1198286 "Non-wale strut system for reverse pounding support method for continuous construction of underground outer walls and reverse pounding construction method for underground structures"

The present invention is to solve the above problems, and it is possible to construct a pair of braces parallel to the upper part of the column, and connect the braces and the beams on both sides of the column with continuous beams so that it is easy to manufacture and advantageous to sagging, As a whole, it has the effect of making small members continuous and additionally installing reinforcing members on the lower part if necessary. In particular, when constructing an underground outer wall, part of the cross-sectional height of the support beam bracket, support beam and support beam overlaps. The purpose of this is to provide a reverse construction method of an underground structure that can effectively cope with the back earth pressure by reducing the height of the lower member on which the brace is mounted by allowing the brace to be mounted on the upper part, thereby minimizing the excavation depth.

The present invention comprises the steps of (a) rooting the pillar member in the ground after the retaining wall construction; (b) installing the support beam on the retaining wall and the support beam bracket on the retaining wall after excavating the ground, and installing the stop plate and the bracket on the column member; (c) installing a pair of braces spaced apart from each other by a predetermined distance on the upper part of the bracket, and connecting the ends of the braces on both sides of the column member so that the braces are continuous; (d) installing a transverse connecting beam to connect a pair of parallel bracing beams; (E) forming a slab by installing a beam formwork and a deck on the upper part of the brace, and pouring concrete after reinforcing the reinforcement; (f) performing the lower excavation of the slab; (g) dismantling the stop plate and the bracket and sequentially lowering the stop plate and the bracket to the lower layer to install; (h) repeating steps (c) to (g) a predetermined number of times; and (i) reinforcing wall reinforcement between the retaining wall and the slab and constructing the underground outer wall by pouring wall concrete.

In addition, in step (b), the bracket is formed by configuring H-beams in the transverse direction from both sides of the column member, and connecting them with separate joint members to connect a pair of H-beams, and separately mounted on the top of the stop plate. An object of the present invention is to provide a reverse construction method of an underground structure, characterized in that the member is installed and a bracket is installed on the upper part of the mounting member.

In addition, in step (c), it is intended to provide a reverse construction method of an underground structure, characterized in that a reinforcing member is additionally configured in the lower portion of the beotimbo.

In addition, in step (c), the joint of the brace and the beam is to provide a reverse construction method of an underground structure, characterized in that the beam is joined to both ends of the connection member using a separate connection member.

In addition, in step (c), it is intended to provide a reverse construction method of an underground structure, characterized in that the joint of the brace and the beam is formed in a position displaced from the joint of the adjacent beam and the beam in parallel.

In addition, in step (a), a support beam bracket consisting of a horizontal lower plate and a vertical plate formed in a vertical direction at the center of the width direction of the lower plate, respectively, is welded to the H-shaped steel flange of the steel composite pile embedded in the retaining wall at a predetermined interval. After installing the supporting beam on the upper part of the supporting beam bracket so that it is located between the supporting beam bracket and the supporting beam bracket and each end is mounted on the lower plate, in step (c), the upper part of the supporting beam is perpendicular to the retaining wall. An object of the present invention is to provide a reverse construction method of an underground structure, characterized in that the support beam is installed on the upper part of the support beam so as to be positioned as

In addition, in step (a), the lower end of the supporting beam is formed with a mounting portion that is cut in the shape of a, and it is intended to provide a reverse construction method of an underground structure, characterized in that the supporting unit is mounted and installed on the supporting beam.

In addition, in step (a), a support beam bracket made of an H-shaped cross section is welded and joined to the H-shaped steel flange of the steel composite pile embedded in the retaining wall at a predetermined interval, and an upper flange and a lower flange are installed on the upper part of the supporting beam bracket. And after installing the support beam of the H-section made of a web, a separate connecting plate is attached to the support beam at the position where the brace is to be installed, and in step (c), the H-section of the H-section consisting of an upper flange, a lower flange and a web An object of the present invention is to provide a reverse striking construction method of an underground structure, characterized in that the beotim beam is installed so that the upper flange and the upper flange of the supporting beam are aligned, and the upper part is connected to the connecting plate using a joint plate.

In addition, in step (a), a support beam bracket made of an H-section is welded to the H-shaped steel flange of the steel composite pile embedded in the retaining wall at a predetermined interval and installed, and in step (c), the upper flange and lower flange And on both sides of the web at the longitudinal end of the H-shaped cross-section made of the web, the supporting beam of the H-shaped cross-section consisting of the upper flange, the lower flange and the web is positioned in the direction at right angles to the upper flange and the supporting beam of the supporting beam. An object of the present invention is to provide a reverse construction method of an underground structure characterized in that the upper flange is matched and joined using a separate joint plate, and then the support beam is mounted on the upper part of the support beam bracket and installed.

The reverse construction method of the underground structure of the present invention constitutes a pair of braces parallel to the upper part of the column and connects the braces and braces on both sides of the column with continuous beams so that it is easy to manufacture and advantageous in deflection, and the overall small member It has the effect of making it continuous and additionally installing reinforcing members on the lower part if necessary. In particular, when constructing an external underground wall, part of the cross-sectional height of the support beam bracket, support beam, and support beam overlaps so that the support beam is placed on the upper part. There is a very useful effect of reducing the height of the lower member on which the brace is mounted, thereby minimizing the excavation depth and thus effectively responding to the back earth pressure.

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical spirit of the present invention together with the detailed description of the present invention, so the present invention is limited to the matters described in the accompanying drawings It should not be construed as being limited.
1 is a view showing the reverse construction method of the underground structure of the present invention in the order of construction.
Figure 2 is a perspective view and an enlarged view showing an embodiment of the beam construction in the reverse construction method of the underground structure of the present invention.
3 is a perspective view and an enlarged view of the simplified embodiment of FIG. 2 .
4 is a perspective view and an enlarged view of another embodiment of FIG. 2 .
Figure 5 is a perspective view and a side view showing the configuration of the earthen wall portion in the reverse construction method of the underground structure of the present invention.
6 is a perspective view and a side view of another embodiment of FIG. 5 .
7 and 8 are a perspective view and a side view of another embodiment of FIG. 5 .

Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the presented embodiments are illustrative for a clear understanding of the present invention, and the present invention is not limited thereto.

Hereinafter, the technical configuration of the present invention will be described in detail according to a preferred embodiment.

1 is a view showing the reverse construction method of the underground structure of the present invention in the order of construction, Figure 2 is a perspective view and an enlarged view showing an embodiment of the beam construction in the reverse construction method of the underground structure of the present invention, Figure 3 is a perspective view and an enlarged view of the simplified embodiment of FIG. 2 , and FIG. 4 is a perspective view and an enlarged view of another embodiment of FIG. 2 .

In the reverse construction method of the underground structure of the present invention, first, as shown in Fig. 1a, after the retaining wall 1 is constructed, as in Fig. 1b, the column member 2 is inserted into the ground at the position where the column will be constructed. (a).

The retaining wall (1) can be formed by various known methods such as slurry wall, CIP, SCW method, etc., and to support vertical load along with earth pressure and water pressure, and the retaining wall (1) is made of rigid composite at predetermined intervals. The H-shaped steel 110 of the pile is embedded and configured.

The column members 2 rooted in the ground are sequentially exposed according to the excavation of the ground, and support the structure's own weight, work load, wind load, etc., and are supported on the lower foundation.

Thereafter, as in FIG. 1c , the stop plate 3 and the bracket 4 are installed on the column member 2 after the excavation of the ground (b).

At this time, after digging the ground in the retaining wall (1), the retaining wall (1) and the retaining wall (1) and the retaining wall (1) are spaced apart from the upper part of the retaining beam bracket 120 and the retaining beam bracket 120 in the retaining wall (1). The support beam 130 is installed in parallel.

The stop plate 3 may be formed in various shapes such as a plate, an angle, a channel, etc. capable of supporting the bracket 4, and is coupled to the side of the column member 2 by welding and bolts to be detachably coupled.

The bracket 4 is installed to be supported on the stop plate 3 from both sides of each pillar member 2 and is fastened with welding and bolts to be detachably coupled to the pillar member 2, so that construction from the upper layer to the lower layer is performed. As it progresses, the coupling and disassembly to the side of the column member 2 are repeated.

In particular, the bracket 4 is formed by connecting the H-shaped steel 41 in the transverse direction from both sides of the column member 2 and connecting the pair of H-shaped steel 41 with a separate joint member 42 to connect them. Thus, it is possible to stably support the beotimbo (5) mounted on the upper part.

At this time, it is possible to install a separate mounting member 46 on the top of the stop plate 3 and install the bracket 4 on the top of the mounting member 46, and the mounting member 46 has an H-shaped cross-section. Various well-known members, such as a member with which it has, can be used.

Thereafter, as in FIG. 1d, a pair of braces 5 are installed at a certain distance on the upper part of the bracket 4, and the ends of the braces 5 on both sides of the column member 2 are joined to the braces 5 ) to be installed so that they are continuous (c), and to install a transverse connecting beam (5a) to connect a pair of parallel braces (5) (d).

As in FIGS. 2a and 2b, the brace 5 is made continuous in the longitudinal direction, and a separate harness plate 56 is formed at the end of the brace 5 and joined by a variety of known methods such as bolts, welding, etc. can be made continuous.

As in FIGS. 2a and 2b, at the time of bonding of the brace 5 and the brace 5, the joint may be formed at the position of the column member 2, and as in FIG. 2c, the brace 5 and the brace The joint portion of (5) may be formed at a position shifted from the joint portion of the parallel adjacent braces 5 and 5, and as shown in FIG. 2d, a separate connecting member 9 is attached to the upper portion of the bracket 4 It is also possible to be continuous by attaching the braces 5 to both ends of the connecting member 9 and respectively.

In particular, as shown in Figure 3, in the case of connecting the beotimbo (5) with the connecting member (9) to make it continuous, the dance of the beotimbo (5) configured on both sides of the connecting member (9) is different from the connecting member (9). Can be configured, as shown in Figure 4, the overall beotimbo (5) to continuously configure the small member and, if necessary, it may be possible to additionally install a reinforcing member (5b) in the lower part of the beotimbo (5) .

After installing a pair of braces (5) spaced apart a certain distance on the upper part of the bracket (4) in this way. A pair of spaced beams (5) are connected to a separate transverse connecting beam (5a). The transverse connecting beam (5a) may be made in various shapes, and both ends are configured to be joined to the beotimbo (5) at regular intervals in the longitudinal direction of the beotimbo (5).

As described above, since the brace 5 is installed on the top of the stop plate 3 and the bracket 4, it is not located on the same plane between the members, so the joint construction of these members is easy, and the member can be easily installed even on an irregular plane. can

Thereafter, as in FIGS. 1e and 1f, the beam form 61 and the deck 6 are installed on the top of the brace 5, and the concrete is poured after reinforcing the reinforcement to form the slab (S) (e) .

A variety of known beam formwork 61 is installed on the upper part of the beam 5, and the deck 6 is mounted on the upper end of the side plate of the beam formwork 61 to be installed.

Then, as in Figure 1f, to carry out the lower excavation of the slab (S) (f).

That is, after completing the construction of the slab (S) of the corresponding layer in the above-described step, the lower ground is excavated to construct the lower layer of the slab (s) on which the construction is completed.

Then, as in FIG. 1g, the stop plate 3, the bracket 4, and the brace 5 are disassembled to sequentially lower the stop plate 3 and the bracket 4 to the lower layer to install it (g) .

Thereafter, as in FIGS. 1h and 1i, the steps (c) to (g) are repeated a certain number of times (h), and finally, wall reinforcement is reinforced between the retaining wall (1) and the slab (S), and the wall concrete to construct the underground outer wall (8) by pouring (i).

5 is a perspective view and a side view showing the configuration of an earthen wall part in the reverse hitting construction method of an underground structure of the present invention, and FIG. 6 is a perspective view and a side view of another embodiment of FIG. 5 .

In particular, in the present invention, when the underground outer wall 8 is constructed, the cross-sectional height of the support beam bracket 120 and the support beam 130 is overlapped so that the beam beam 5 is mounted on the upper part, so that the bottom beam 5 is mounted. By reducing the height of the member, it is possible to minimize the excavation depth according to it, so that it can effectively cope with the back earth pressure.

5a and 5b, the support beam bracket 120 is installed on the flange 111 of the H-beam 110 of the steel composite pile embedded at a predetermined interval in the retaining wall 1, and the support beam bracket 120 to mount the support beam 130 on the upper part of the

At this time, in order to reduce the height of the lower member on which the beotimbo 5 is mounted, the support beam bracket 120 is formed in a vertical direction in the center of the width direction of the horizontal lower plate 121 and the lower plate 121 ( 122) to have an inverted T-shaped cross section, and to install the support beam 130 between the support beam bracket 120 and the support beam bracket 120 so that the ends are mounted on the lower plate 121, respectively. Thus, by making the cross section of the support beam 130 overlap within the cross section of the support beam bracket 120, the height of the member is greatly reduced, and the excavation depth can be reduced by this height.

Then, to install the support beam (5) on the upper part of the support beam (130) so as to be positioned at right angles to the retaining wall (10) on the upper part of the support beam (130), as shown in FIG. 6, the cross section of the support beam (5) The cross-section of the support beam bracket 120 and the support beam 130 may overlap to reduce the height.

To this end, the support beam (5) has the lower end of the end portion to be cut in a shape of a (59) is formed, and by allowing the support beam (130) to be mounted on the support beam (59), the support portion (59) is As much as the formed height overlaps the cross-sectional height of the support beam 130, it is possible to reduce the excavation depth by that much.

At this time, a separate reinforcing maguri plate may be formed at the end where the mounting portion 59 is formed.

7 and 8 are a perspective view and a side view of another embodiment of FIG. 5 .

In particular, as in FIG. 7 , in step (a), the support beam bracket 120 made of an H-shaped section in the H-shaped steel 110 flange 111 of the steel composite pile embedded in the retaining wall 1 at a predetermined interval. is welded and installed, and after installing the support beam 130 on the upper part of the support beam bracket 120 , the support beam 5 may be installed so that the cross section overlaps the support beam 130 .

To this end, the supporting beam 130 is made of an H-shaped cross section consisting of an upper flange 131, a lower flange 132, and a web 133, and the supporting beam 130 at a position where the supporting beam 5 is to be installed. to connect the connecting plate 139 of the

As shown, the connecting plate 139 is joined by a method such as welding to be positioned at a right angle to the web 133, and in step (c), a joint plate (5) is attached to the connecting plate 139 ( 59) to join them.

At this time, the upper flange (51) of the upper flange (51) and the supporting beam (130) of the H-shaped section beam (5) consisting of the upper flange (51), the lower flange (52) and the web (53) so that the cross-sections can overlap 131) to match, and the upper part is installed to be joined to the connecting plate 139 using the joint plate 59.

In addition, as in FIG. 8 , in step (a), the support beam bracket 120 made of an H-shaped cross section on the H-shaped steel 110 flange 111 of the steel composite pile embedded in the retaining wall 1 at a predetermined interval. is welded and installed, and in step (c), after installing the support beam 130 on the support beam 5 in advance, the support beam 130 may be installed on the support beam bracket 120 .

At this time, the longitudinal end web of the beotimbo 5 of the H-shaped cross section consisting of the upper flange 51, the lower flange 52 and the web 53 so that the cross section of the beotimbo 5 and the supporting beam 130 can overlap. On both sides of (53), respectively, to install the support beam (130).

At this time, the supporting beam 130 is composed of an upper flange 131, a lower flange 132 and a web 133, and positioned at a right angle to the beotimbo 5, the upper flange 51 of the beotimbo 5 and After matching the upper flange 131 of the support beam 130 and joining using a separate joint plate 59, the support beam 130 is mounted on the upper part of the support beam bracket 120 to be installed. .

The reverse construction method of the underground structure of the present invention as described above comprises a pair of braces parallel to the upper part of the column and connects the braces and beams on both sides of the column with continuous beams so that it is easy to manufacture and advantageous to sagging. As a whole, it has the effect of making small members continuous and additionally installing reinforcing members on the lower part if necessary. In particular, when constructing an underground outer wall, part of the cross-sectional height of the support beam bracket, support beam and support beam overlaps. By allowing the brace to be mounted on the upper part, it is possible to reduce the height of the lower member on which the brace is mounted, thereby minimizing the excavation depth, which has a very useful effect to effectively cope with the back earth pressure.

So far, the present invention has been described in detail with reference to the presented embodiments, but those skilled in the art can make various modifications and modified inventions without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The present invention is not limited by such variations and modifications, but only by the claims appended hereto.

1: retaining wall
2: column member
3: stop plate
4: Bracket
5: Brace
5a: transverse connecting beam
5b: reinforcing member
6: deck
8: basement outer wall
10: H-beam
120: support beam bracket
130: support beam

Claims (9)

(a) the retaining wall (1) after the construction of the pillar member (2) in the ground;
(b) After excavating the ground, install the support beam 130 on the upper part of the support beam bracket 120 and the support beam bracket 120 on the retaining wall 1, and the stop plate 3 on the column member 2 and Installing the bracket (4);
(c) Install a pair of braces 5 spaced apart by a certain distance on the upper part of the bracket 4, and connect the ends of the braces 5 on both sides of the column member 2 so that the braces 5 are continuous to do;
(d) installing a transverse connecting beam (5a) to connect a pair of parallel braces (5);
(e) forming a slab (S) by installing a beam formwork (61) and a deck (6) on top of the beam (5) and pouring concrete after reinforcing the reinforcement;
(f) performing the lower excavation of the slab (S);
(g) dismantling the stop plate (3) and the bracket (4) and sequentially lowering the stop plate (3) and the bracket (4) to the lower layer to install;
(h) repeating steps (c) to (g) a predetermined number of times; and
(i) Reinforcing wall reinforcement between the retaining wall (1) and the slab (S) and constructing the basement outer wall (8) by pouring wall concrete; The method according to claim 1,
(b) in step,
The bracket 4 is formed by connecting the H-beams 41 in the transverse direction from both sides of the column member 2, and connecting a pair of H-beams 41 with a separate joint member 42,
Reverse construction method of an underground structure, characterized in that a separate mounting member (46) is installed on the upper part of the stop plate (3), and a bracket (4) is installed on the upper part of the holding member (46). The method according to claim 1,
(c) in step,
The reverse construction method of the underground structure, characterized in that the lower portion of the beotimbo (5), the reinforcement member (5b) is additionally configured. The method according to claim 1,
(c) in step,
The joint of the beotimbo (5) and the beotimbo (5) is a reverse construction method of an underground structure, characterized in that the beotimbo (5) is joined to both ends of the connecting member (9) using a separate connecting member (9). The method according to claim 1,
(c) in step,
Reverse construction method of an underground structure, characterized in that the joint of the beotimbo (5) and the beotimbo (5) is formed in a position displaced from the joint of the beotimbo (5) and the beotimbo (5) adjacent in parallel. The method according to claim 1,
In step (a),
A vertical plate formed in a vertical direction at the center of the horizontal lower plate 121 and the lower plate 121 in the width direction of the H-shaped steel 110 flange 111 of the steel composite pile embedded in the retaining wall 1 at a predetermined interval ( 122), the support beam bracket 120 is welded and installed,
After installing the support beam 130 on the upper part of the support beam bracket 120 to be positioned between the support beam bracket 120 and the support beam bracket 120 so that the ends are respectively mounted on the lower plate 121,
(c) in step,
Reverse construction method of an underground structure, characterized in that the support beam (5) is installed in the upper part of the support beam (130) so as to be positioned at right angles to the retaining wall (10) on the upper part of the support beam (130). 7. The method of claim 6,
In step (a),
The support brace (5) is formed with a mounting part (59) in which the lower end of the end is cut in a shape of a,
Reverse construction method of an underground structure, characterized in that the mounting portion (59) is mounted on the support beam (130) and installed. The method according to claim 1,
In step (a),
A support beam bracket 120 made of an H-shaped cross section is welded to the H-shaped steel 110 flange 111 of the steel composite pile embedded at a predetermined interval in the retaining wall 1 and installed,
After installing the support beam 130 of the H-shaped cross section consisting of the upper flange 131, the lower flange 132 and the web 133 on the upper part of the support beam bracket 120,
A separate connecting plate 139 is bonded to the supporting beam 130 at the position where the beotim beam 5 is to be installed,
(c) in step,
By matching the upper flange 131 of the upper flange 51 and the supporting beam 130 with the H-shaped rib beam 5 of the H-shaped cross section consisting of the upper flange 51, the lower flange 52 and the web 53, Reverse construction method of an underground structure, characterized in that the upper part is installed to be joined to the connecting plate (139) using a joint plate (59). The method according to claim 1,
In step (a),
The support beam bracket 120 made of an H-shaped cross section is welded and installed to the H-shaped steel 110 flange 111 of the steel composite pile embedded in the retaining wall 1 at a predetermined interval,
(c) in step,
On both sides of the longitudinal end web 53 of the brace 5 of H-shaped cross section consisting of the upper flange 51, the lower flange 52 and the web 53, respectively,
The support beam 130 of the H-shaped cross-section consisting of the upper flange 131, the lower flange 132 and the web 133 is positioned at a right angle to the support beam 5, and the upper flange 51 of the support beam 5 and After matching the upper flange 131 of the support beam 130 and joining using a separate joint plate 59,
Reverse construction method of an underground structure, characterized in that the support beam 130 is mounted and installed on the upper part of the support beam bracket 120 .

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