KR101066198B1 - Underground construction method of top-down with slurry walls - Google Patents

Abstract

The present invention comprises the steps of: excavating the ground while filling the stabilizer along the boundary of the underground structure to form an excavation hole (10); (b) inserting a reinforcing steel bar 20 to which the metal fixing plate 22 is attached at the position where the cheolgolbo is to be connected to the excavation hole and pouring concrete to build a slurry wall 100; (c) vertically installing the steel pillars 110 at the positions where the pillars of the building are to be installed; (d) performing a first blow to a predetermined depth to expose the metal fixing plate 22 of the slurry wall; (e) installing a cheolgolbo (30) between the slurry wall and the steel column, the end of the cheolgolbo 30 is coupled to the exposed metal fixing plate (22); (f) Mounting the first deck plate 40 and the second deck plate 42 on the cheolgolbo, the first deck plate 40 is mounted to the same height as the lower surface of the slab to be built, the second Deck plate 42 is mounted to a height lower than the first deck plate 40 in the vicinity of the connection portion of the slurry wall (100) and cheolgolbo (30); (g) installing a buried sleeve 50 to be connected to the through hole 46 formed in the second deck plate 42; (h) constructing slab by pouring concrete on the deck plates 40 and 42; And (i) repeating the steps (d) to (h) to continuously build the basement slab, wherein the constructed slab is a stepped area formed by the second deck plate 42 ( 60, the lower surface of the stepped area 60 forms a step having a lower height than the slab area formed by the first deck plate 40, and a drainage hole is formed in the stepped area 60. It relates to a method for reverse construction of underground structures to form 62).

Slurry wall, underground structure reverse drilling method

Description

Underground construction method of top-down with slurry walls}

The present invention relates to a method for constructing underground structures (TOP-DOWN), and more particularly, to a slurry wall leak by constructing a slab with a drain hole and a step for a slurry wall used as an underground block wall. The present invention relates to a method for reversing underground structures using an improved slurry wall to solve the problems.

As a method of constructing underground structures, the reverse stroke method is called the TOP-DOWN method, which constructs the outer retaining wall and the underground column, constructs the ground frame and breaks the underground layer at the same time. It is a method to perform the construction of underground structures while proceeding step by step.

Slurry Wall is widely used as a back wall in the reverse drilling method. In this slurry wall method, after digging the excavation hole to a predetermined depth while supplying a stabilizer such as bentonite to prevent the collapse of the excavation surface, Underground continuous wall construction method is to insert a reinforcing bar network of predetermined size and build concrete wall by pouring concrete.

By the way, the slurry wall is divided by a predetermined length due to the limitation of the work to be constructed separately, for example, excavating the excavation hole to be spaced apart from each other, and after the reinforcement network is inserted to build a first panel (Primary panel), Subsequently, the first panel is excavated to construct a second panel in the same manner.

Therefore, since the first panel and the second panel of the slurry wall are walls that are not integrated with each other, a problem arises in that the external groundwater or water is infiltrated or leaked by a gap therebetween. The leaked water penetrates along the slab of the basement layer and causes pollution, such as generating rust.

In addition, it is common to combine the RC beam with respect to the conventional slurry wall, in this case, there is a lot of difficulties in construction, such as the need to install a lower support such as copper bar.

On the other hand, Patent Publication No. 10-2009-20430 is to insert a reinforcing bar network with a filler inside the excavation hole to build a slurry wall, to remove the filler from the wall of the slurry wall and to place the end of the cheolgolbo in place Disclosed is a method of constructing an underground structure including a process.

However, according to the underground structure construction method according to the above document, when the basement slab to be built is formed in a plane with a uniform thickness, when the leak of the underground layer as described above occurs, the leaked water spreads to the center of the slab to corrode or contaminate There is a problem that causes.

In addition, there is a limit in that connectivity or integrity between the slab layer and the slurry wall is not secured. Furthermore, when the deck plate is mounted on a steel frame that spans between the slurry wall and the pillar, the working space between the deck plate and the slurry wall is narrow, so that the reinforcing bars are reinforced by mutual interference between the reinforcing bars embedded in the slurry wall and the bars assembled on the deck plate. Difficulty in doing back work.

The present invention is to solve the above problems, by constructing a slab to have a stepped area formed with a drain hole at the connection point with the slurry wall, the underground structure to smoothly drain the water leaked between the panels of the slurry wall It aims at providing the reverse construction method.

Another object of the present invention is to ensure the integrity of the slab and slurry wall by removing the interference with the deck plate at the time of slab construction and facilitating rebar reinforcement work because the stepped area is formed at the connection point with the slurry wall It is to provide a method for reversing underground structures to enable the construction.

In order to achieve the above object, the underground structure reverse construction method according to a preferred embodiment of the present invention, (a) filling the stabilizer along the boundary of the underground structure while excavating the ground to form an excavation hole; (b) inserting a reinforcing bar network 20 having a metal fixing plate attached thereto at the position where the cheolgolbo is connected to the excavation hole and pouring concrete to build a slurry wall; (c) installing the steel frame vertically at the position where the pillar of the building is to be installed; (d) performing a first blow to a predetermined depth to expose the metal fixing plate 22 of the slurry wall; (e) installing a cheolgolbo between the slurry wall and the steel column, the end of the cheolgolbo coupled to the exposed metal fixing plate; (f) mounting a first deck plate and a second deck plate on the cheolgolbo, wherein the first deck plate is mounted at the same height as the lower surface of the slab to be constructed, the second deck plate of the slurry wall and cheolgolbo Mounting at a height lower than the first deck plate near a connection; (g) installing a buried sleeve to be connected to a through hole formed in the second deck plate; (h) constructing slab by pouring concrete on the deck plate; And (i) repeating the steps (d) to (h) to continuously build the basement slab, wherein the constructed slab includes a stepped area formed by the second deck plate, The lower surface of the stepped area forms a step having a lower height than the slab area formed by the first deck plate, and a drain hole is formed in the stepped area.

Preferably, in the step (e), the cheolgolbo includes a steel frame and a concrete member integrally formed at both ends of the steel frame, the concrete member, the upper surface is formed at the same height as the lower surface of the slab is the first deck A first concrete member adapted to mount the plate; And a second concrete member having an upper surface formed at a height lower than an upper surface of the first concrete member to form the stepped area so as to mount the second deck plate.

More preferably, the upper surface of the first concrete member 34 is formed at the same height as the upper surface of the upper flange of the steel frame.

According to another embodiment of the present invention, it further comprises a mounting bracket horizontally formed to have an upper surface of the same height as the upper surface of the first concrete member.

According to another embodiment of the present invention, in the step (e), the cheolgolbo, steel frame; A concrete member integrally formed at one end of the steel frame to have the upper surface of the same height as the lower surface of the slab to mount the first deck plate; And a mounting bracket 39 formed horizontally on the web of the steel frame so as to have the upper surface having a lower height than the upper surface of the concrete member 34 to form the stepped area so as to mount the second deck plate. Include.

According to the present invention, in the step (b), the reinforcing bar network further comprises a connecting reinforcing bar and the filling member filled around the connecting reinforcement is maintained at the end of the upper end of the metal fixing plate, the (d) Removing the filling member exposed with the metal fixing plate in a step; And extending the ends of the connecting bars to extend toward the slab layer.

Preferably, the construction method of the present invention further comprises the step of installing a collection guide pipe for guiding the water flowing downward through the drain hole to the collection well.

More preferably, the present invention further includes the step of forming a moisture proof inner wall to be connected to the stepped region of the slab to form a space in which the leaked water flows between the slurry wall and the moisture proof inner wall.

The underground structure reverse construction method using the slurry wall according to the present invention has the following effects.

First, a metal fixing plate is attached to the reinforcing bar network for constructing the slurry wall, and the end of the cheolgolbo is welded and attached directly to the metal fixing plate after the slurry wall is made, so the operation is very simple and structurally stable.

Secondly, in the present invention, by using a steel plate that can be mounted to the deck plate at different heights to secure the work space because the deck plate does not interfere in the vicinity of the slurry wall to extend the reinforcing bars of the reinforcing bar or extend the slab reinforcement It is very easy to work out.

Third, by forming a space between the slurry wall and the inner wall and draining the water leaked downward through the drain hole, it is possible to solve the problem caused by the leakage of the underground structure and to prevent the condensation of the inner wall.

Fourth, since the stepped region is formed at the end of the slab adjacent to the slurry wall, it is possible to prevent the leaked water flows to the center of the slab and cause corrosion or contamination.

By the construction method of the present invention, the conventional slurry wall is

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

According to the present invention, a slurry wall is constructed as a retaining wall along a boundary where an underground structure is to be constructed by designing a building to be constructed first. This slurry wall serves as a temporary barrier wall that prevents the surrounding soil from collapsing during the underground excavation stage, and functions as an underground outer wall of the building after completion of the building.

In order to build the slurry wall as described above, as shown in Figure 1, to excavate the ground to a predetermined depth along the boundary of the underground structure to form an excavation hole (10). At this time, by filling a stabilizing liquid, such as bentonite (bentonite) in the excavation hole (10) inside and excavated to prevent the collapse of the soil.

Subsequently, the excavation hole 10 excavated as described above is inserted into the rebar network 20 according to the present invention. The reinforcing bar network 20 is a structure in which rebars are arranged horizontally and vertically, and the metal fixing plate 22 is attached to a predetermined position to which the cheolgolbo pillar is connected as described below.

The metal fixing plate 22 has a size enough to be coupled to the end of the cheolgolbo, and the side of the reinforcing bar 20 so as not to interfere with the insertion of the reinforcing bar 20 into the excavation hole 10 For example, it can be firmly attached by making, inserting and welding a predetermined storage space.

In addition, the reinforcing bar network 20 according to the present invention includes a plurality of connecting reinforcing bar 24 to be embedded to extend into the slab, the connecting reinforcing bar 24 is a slab on top of the metal fixing plate 22 It is provided according to the position to be constructed.

The end 25 of the connecting reinforcing bar 24 is bent and maintained inside the reinforcing bar 20 so as not to interfere when the reinforcing bar 20 is inserted into the excavation hole 10. Further, around the end 25 of the connecting reinforcing bar 24, the filling member 26 made of, for example, styrofoam, synthetic resin, or the like is filled to prevent it from being embedded in concrete. This filling member 26 should be able to be removed after the slurry wall construction as described below.

In addition, the side of the metal fixing plate 22 may be provided so that the filler 23 extends horizontally to form a receiving space for inserting the end of the deck plate as described later. However, the present invention is not necessarily limited by this configuration.

The slurry wall 100 is constructed by inserting the reinforcing bar network 20 having the above configuration into the excavation hole 10 and placing concrete.

Next, as shown in FIG. 2, the steel frame 110 is vertically inserted from the ground at a position where the pillar of the building is to be installed. In addition, a base (not shown) may be formed at the lower end of the steel pillar 110 so as to transfer the load of the upper structure to the ground.

After the slurry wall 100 and the steel pillars 110 are installed as described above, the primary trench is performed to a predetermined depth as shown in FIG. 3 to construct the underground structure. At this time, the depth of the primary trench is made to a suitable degree to build the first floor slab underground.

The inner surface of the slurry wall 100 is exposed by the first bursting process, and thus the metal fixing plate 22, the filling member 26, and the filler 23 are exposed.

Then, between the slurry wall 100 and the steel frame pillar 110 is installed cheolgolbo 30 as a permanent structural member. A detailed coupling configuration between the slurry wall 100 and cheolgolbo 30 is shown in FIG.

Preferably, according to the present invention, the cheolgolbo 30 may be composed of a concrete composite beam as shown in FIG. The concrete composite beam is composed of a steel frame 32, such as H-shaped steel, and concrete members 34, 35 provided only at both ends except for the center of the steel frame (32).

Here, the concrete members 34 and 35 include a first concrete member 34 for forming a slab and a second concrete member 35 for forming a step area of the slab.

The first concrete member 34 is integrally formed at one end of the steel frame 32 so that the upper surface thereof is flush with the lower surface of the slab on which the upper surface is constructed. As will be described later, the first deck plate (40 in FIG. 11) is mounted on the upper surface of the first concrete member 23, and sets the height of the lower surface of the slab to be constructed.

According to this embodiment, the upper surface of the first concrete member 34 is set at the same height as the upper surface of the upper flange 32c of the steel frame 32. In this case, the deck plate may be mounted to simultaneously cover the upper flange 32c of the steel frame 32 and the upper surface of the first concrete member 34.

The second concrete member 35 is formed to bury only a portion of the lower flange 32a and the web 32b at the end of the steel frame 32 coupled to the slurry wall 100. The upper surface of the second concrete member 35 is formed to be located at a height lower than the upper surface of the first concrete member 34. That is, the second deck plate (42 in FIG. 11) is mounted on the upper surface of the second concrete member 35, and as described later, the stepped area of the slab (see 60 in FIG. 13) is formed by concrete pouring. .

A connecting iron plate 31 is joined to the end of the steel frame 32 on which the second concrete member 35 is formed by welding, which is to be coupled to the metal fixing plate 22 of the slurry wall 100. The size of the connecting iron plate 31 may be appropriately set according to the working conditions.

As another alternative, the cheolgolbo 30 is not necessarily provided with a connecting steel plate 31, in some cases, the end of the steel frame 32 may be attached directly to the metal fixing plate 22.

7 and 8 illustrate a configuration of cheolgolbo 30 'according to another embodiment of the present invention. Here, the same reference numerals as in the above-described drawings indicate the same members.

As shown, the upper surface height of the first concrete member 34 'provided in the cheolgolbo 30' according to the present embodiment is formed to a height lower than the upper flange 32c of the steel frame (32). In this case, the first deck plate 40 is mounted on the upper surface of the first concrete member 34 'so that this height corresponds to the lower surface of the slab.

Also in this embodiment, the top surface of the second concrete member 35 that forms the stepped region 60 of the slab is still located below the top surface of the first concrete member 34 '.

Preferably, the cheolgolbo 30 'according to the present embodiment may further include a mounting bracket 37 having an upper surface of the same height as the upper surface of the first concrete member 34'. The mounting bracket 37 is attached to the side of the web 32b of the steel frame 32 by welding or the like, and the first deck plate 40 is mounted together with the first concrete member 34 '.

9 and 10 show the construction of a cheolgolbo 30 "according to another embodiment of the present invention. Here, the same reference numerals as in the above-described drawing indicate the same members.

The cheolgolbo 30 "according to this embodiment includes a mounting bracket 39 formed horizontally on the web 32b of the steel frame 32 instead of the above-described second concrete member 35. The mounting bracket The upper surface of the 39 is configured to be formed at a position lower than the upper flange 32c of the first concrete member 34 or the steel frame 32.

5 to 10 described the configuration of the cheolgolbo according to a preferred embodiment of the present invention, but the present invention is not necessarily to be construed as being limited to this embodiment, it should be understood that it can be modified by various combinations of these configurations. .

For example, although not shown in the drawings, a mounting bracket may be formed instead of the first concrete member 34.

As another alternative, the deck plate may be mounted directly to the upper flange of the steel frame without the first concrete member 34 or a mounting bracket to replace it. In this case, the concrete member 35 is provided only on one side of the steel frame 32, the other end of the steel frame is convenient because it can be cut in accordance with the appropriate length and joined to the steel column.

In the present invention, if the deck plate can be mounted at a height lower than the lower surface of the slab in order to build the stepped region 60 of the slab, various configurations can be applied.

Referring to Figure 4 again showing the combination of the cheolgolbo 30 and the slurry wall 100, the cheolgolbo 30 is a metal fixing plate of the slurry wall 100 exposed to the basement layer of the iron plate 31 provided at the end It is fixed by welding to (22) or by using a separate connection bracket (not shown) and bolts. In addition, the other end of the cheolgolbo 30 is also coupled to the steel frame pillar 110 in the same manner.

At this time, the angle bracket 33 supporting the end of the cheolgolbo 30 may be attached to the slurry wall 100 for the stable coupling of the cheolgolbo 30, but is not necessarily an essential element.

As described above, once the cheolgolbo 30 is installed on the slurry wall 100 and the steel column 110, the deck plate 40, 42 on the cheolgolbo 30 as shown in Figure 11 for slab casting ) As is already known, the deck plate 40, 42 is used as a formwork for the construction of the slab as a form in which the steel plate and the reinforcing bar is made in advance, and is used as a permanent member after pouring.

According to the present invention, the first and second deck plates 40 and 42 are mounted at different heights, and the first deck plate 40 is mounted at a position corresponding to the height of the bottom surface of the slab to be constructed. The second deck plate 42 is mounted at a position lower than the first deck plate 40 near the connection portion between the slurry wall 100 and the cheolgolbo 30.

In the embodiment shown in Figure 11 shows the installation state of the deck plate for the case of employing the cheolgolbo 30 shown in Figures 5 and 6 described above.

Specifically, the first deck plate 40 is mounted on the first concrete member 34 that sets the height of the bottom surface of the slab. At this time, since the upper surface of the first concrete member 34 has the same height as the upper surface of the upper flange 32c of the steel frame 32, the first deck plate 40 is the end of the steel plate 30 as shown It is mounted on the upper flange 32c.

On the other hand, the second deck plate 42 is mounted on the second concrete member 35 having an upper surface at a lower level than the upper surface of the first concrete member 34.

In addition, an auxiliary formwork iron plate 44 is installed between the first deck plate 40 and the second deck plate 40 to prevent gaps due to height differences.

If the cheolgolbo 30 'shown in Figures 7 and 8 is employed, the first deck plate 40 is mounted on the upper surface of the first concrete member 34' and the mounting bracket 37, the second The second deck plate 42 is mounted on the upper surface of the concrete 35.

9 and 10, which is another embodiment, the first deck plate 40 is disposed on the first concrete member 34 ″ and the upper flange 32c of the steel frame 32. The second deck plate 42 will be mounted on the upper surface of the mounting bracket 39 in contact with the slurry wall 100 at a lower height.

Preferably, as described above, by removing all of the fillers (23 of FIG. 1) that were exposed to the slurry wall 100, a horizontal storage space is formed, and when the end of the second deck plate 42 is inserted thereinto, More stable coupling is possible, and in this case, a configuration such as an angle bracket (not shown) supporting the lower portion of the deck plate is unnecessary.

According to the present invention, a plurality of through holes 46 are formed in the second deck plate 42, and these through holes 46 function as drain holes when concrete is poured later. The through hole 46 may be formed in advance, but may also be formed when working in the field.

Meanwhile, all of the filling member 26 and the filler 23 exposed through the slurry wall 100 are removed, and the end 25 of the connecting reinforcing rod 24 buried in the filling member 26 is unfolded and the slab is intact. Extend towards the layer.

At this time, since the connecting reinforcing bar 24 is located at the same height as the slab layer being constructed, the end 25 is embedded in the slab during concrete pouring, and thus stable coupling between the slurry wall 100 and the slab is possible.

Subsequently, as shown in FIG. 12, the buried sleeve 50 is installed to be connected to the through hole 46 of the second deck plate 42 before placing the concrete for slab construction. The buried sleeve 50 acts as a drain hole along with the through hole 46 of the second deck plate 42 after the concrete is poured.

In addition, the slab reinforcing bars 52 are properly arranged and structurally connected to the connecting bars 24 as necessary.

According to the present invention, it is necessary to install a structure such as a copper bar for supporting the lower portion in the process of connecting the cheolgolbo 30 between the slurry wall 100 and the steel column 110 and installing the deck plates 40, 42 There is no.

As described above, when the deck plate 40, 42 and the reinforcing reinforcement work is completed, concrete is then poured on the deck plate 40, 42 to build, for example, a basement slab.

A schematic slab configuration after curing the poured concrete is shown in FIG. 13. 13 shows the slab between the cheolgolbo and cheolgolbo (hence the construction of the cheolgolbo and concrete members, etc. are not shown).

Referring to the drawings, the area formed by the first deck plate 40 becomes a region constituting the main slab layer, while the area formed by the second deck plate 42 is lower in height than the main slab layer. It forms a step (hereinafter referred to as step area 60).

The thickness of the stepped region 60 is relatively thicker than the thickness of the slab.

In addition, the stepped area 60 is formed so that the drain hole 62 penetrates. As described above, the drain hole 62 is formed by the through hole 46 and the buried sleeve 50 of the second deck plate 42. The buried sleeve 50 may be removed or left as it is after concrete pouring.

According to another preferred embodiment of the present invention, a through hole (64 in FIG. 14) may be further formed in the second concrete member 35 of the cheolgolbo 30 shown in FIG. 5, such a through hole 64 ) May be connected to the through hole 46 and / or the embedding sleeve 50 of the second deck plate 42 to form the drain hole 62 in the portion where the cheolgolbo 30 is formed. 14 is shown. As another alternative, the through hole may be formed in the mounting bracket 39 when the cheolgolbo 30 "shown in FIG.

As described above, when the basement first floor slab is constructed, the second basement dig is sequentially carried out so that the metal fixing plate 22 and the filling member 26 of the slurry wall 100 corresponding to the basement second floor slab are exposed. Repeat the same process to construct the second basement slab.

Repeating this process, as shown in FIG. 10, the basement structure is finally completed by pouring and curing the basement floor 70 into concrete.

Then, the moisture proof inner wall 72 is constructed to be connected to the step area 60 of the slab to form a space between the slurry wall 100 and the moisture proof inner wall 72. The moisture proof inner wall 72 may be composed of a masonry wall or a dry wall.

Further, in the space between the slurry wall 100 and the moisture proof inner wall 72, the bottom of the underground structure is preferably provided with a collecting guide 74, which is a collecting basin 78 through a collecting guide pipe 76. Connected with

Therefore, the water immersed or leaked from the slurry wall 100 flows downward along the space and collects in the water collecting guide portion 74 through the drain hole 62 and then the water collecting well 78 along the water collecting induction pipe 76. Is discharged.

In particular, the water leaked in the vicinity of the slab is no longer flow or bleed to the center of the slab due to the height difference of the step area 60 of the slab is drained down or flows downward through the drain hole 62. Therefore, condensation can be prevented from occurring on the inner wall of the underground structure.

Although the present invention will be described in detail with reference to the following drawings, these drawings illustrate preferred embodiments of the present invention, and the technical concept of the present invention is not limited to the drawings and should not be interpreted.

1 is a view showing a process of constructing a slurry wall by excavating an excavation hole and inserting a reinforcing bar network according to the reverse structure construction method according to a preferred embodiment of the present invention.

2 is a view showing a process of installing a steel column according to the method for reverse construction of underground structures according to a preferred embodiment of the present invention.

3 is a view showing a state in which the primary tuper and the cheolgolbo connected in accordance with the reverse structure construction method according to a preferred embodiment of the present invention.

Figure 4 is a view showing the coupling configuration of the metal plate and the steel cheolgolbo of the slurry wall in accordance with the method for reverse construction of underground structure according to a preferred embodiment of the present invention.

5 and 6 are a perspective view and a cross-sectional view showing an example of cheolgolbo which is employed in the underground structure reverse construction method according to a preferred embodiment of the present invention.

7 and 8 are a perspective view and a cross-sectional view showing an example of cheolgolbo which is employed in the underground structure reverse construction method according to another preferred embodiment of the present invention.

9 and 10 are a perspective view and a cross-sectional view showing an example of cheolgolbo which is employed in the underground structure reverse construction method according to another preferred embodiment of the present invention.

11 is a view showing a state in which the deck plate is installed in accordance with the reverse structure construction method according to a preferred embodiment of the present invention.

12 is a view showing a state in which the buried sleeves and reinforcing bars in accordance with the method for reversing the underground structure according to a preferred embodiment of the present invention.

13 is a view showing the configuration of the slab constructed in accordance with the method for reverse construction of underground structure according to a preferred embodiment of the present invention.

14 is a view showing another configuration of the slab constructed in accordance with the method for reverse construction of underground structure according to a preferred embodiment of the present invention.

15 is a view showing a part of the structure of the underground structure constructed in accordance with the underground structure reverse construction method according to a preferred embodiment of the present invention.

Claims (9)

(A) excavating the ground while filling the stabilizer along the boundary of the underground structure to form an excavation hole (10); (b) inserting a reinforcing steel bar 20 to which the metal fixing plate 22 is attached at the position where the cheolgolbo is to be connected to the excavation hole and pouring concrete to build a slurry wall 100; (c) vertically installing the steel pillars 110 at the positions where the pillars of the building are to be installed; (d) performing a first blow to a predetermined depth to expose the metal fixing plate 22 of the slurry wall; (e) installing a cheolgolbo (30) between the slurry wall and the steel column, the end of the cheolgolbo 30 is coupled to the exposed metal fixing plate (22); (f) Mounting the first deck plate 40 and the second deck plate 42 on the cheolgolbo, the first deck plate 40 is mounted to the same height as the lower surface of the slab to be built, the second Deck plate 42 is mounted to a height lower than the first deck plate 40 in the vicinity of the connection portion of the slurry wall (100) and cheolgolbo (30); (g) installing a buried sleeve 50 to be connected to the through hole 46 formed in the second deck plate 42; (h) constructing slab by pouring concrete on the deck plates 40 and 42; And (i) repeating the steps (d) to (h) to continuously build the basement slab; and The constructed slab includes a stepped region 60 formed by the second deck plate 42, The lower surface of the stepped area 60 forms a step having a lower height than the slab area formed by the first deck plate 40, Reverse step construction method, characterized in that the stepped area 60, the drain hole 62 is formed. The method of claim 1, In the step (e), the cheolgolbo 30 includes a steel frame 32, and a concrete member integrally formed at both ends of the steel frame 32, The concrete member, A first concrete member 34 having an upper surface formed at the same height as a lower surface of the slab so as to mount the first deck plate 40; And Underground structure, characterized in that the upper surface is formed to a lower height than the upper surface of the first concrete member to form the stepped area to mount the second deck plate 42 to the second concrete member (35) Reverse construction method. The method of claim 2, The upper surface of the first concrete member (34) is the underground structure reverse construction method, characterized in that formed at the same height as the upper surface of the upper flange (32c) of the steel frame (32). The method of claim 2, The base structure reverse construction method further comprises a mounting bracket (37) formed horizontally to have a top surface of the same height as the top surface of the first concrete member (34 '). The method of claim 1, In the step (e), the cheolgolbo 30, Steel frame 32; A concrete member 34 integrally formed at one end of the steel frame 32 so as to have an upper surface having the same height as a lower surface of the slab so as to mount the first deck plate 40; And It is formed horizontally on the web 32b of the steel frame 32 so as to have a top surface of a lower height than the upper surface of the concrete member 34 to form the stepped area to mount the second deck plate 42 Mounting bracket (39); underground structure reverse construction method comprising a. The method of claim 1, In the step (e), the cheolgolbo 30, Steel frame 32; And Underground structure reverse construction method characterized in that it comprises a concrete member formed to have an upper surface of a lower height than the upper flange (32c) on one end of the steel frame (32). The method of claim 1, In the step (b), the reinforcing bar 20 is filled around the connecting reinforcement 24 and the connecting reinforcement 24 and the end 25 is kept bent at the top of the metal fixing plate 22 Further comprising a filling member 26, Removing the filling member 26 exposed with the metal fixing plate in the step (d); And Unfolding the end portion (25) of the connecting reinforcement to extend toward the slab layer; Underground structure reverse construction method further comprising. The method of claim 1, And installing a water collecting induction pipe (76) for guiding water flowing downward through the drain hole to the water collecting well (78). The method of claim 8, And constructing a moisture proof inner wall 72 so as to be connected to the stepped region 60 of the slab to form a space in which the leaked water flows between the slurry wall 100 and the moisture proof inner wall 72. Underground structure reverse construction method, characterized in that.

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