KR102568229B1 - Bottom-up dismantling method using existing building slab - Google Patents

Abstract

The present invention relates to a bottom-up dismantling method using an existing building slab, and more specifically, to a bottom-up dismantling method using an existing building slab, wherein a slab reinforcing means (100) is installed on each existing building, slab so that when the bottom of a retaining wall is dismantled, dismantling construction can be carried out easily while preventing sagging, and thus, dismantling work can be carried out firmly and safely, thereby preventing unexpected accidents.

Description

Bottom-up dismantling method using existing building slab {Bottom-up dismantling method using existing building slab}

The present invention relates to a bottom-up disassembly method using slabs of an existing building, and more particularly, by installing slab reinforcing means (100) for each slab of an existing building to prevent sagging when demolishing the lower part of a retaining wall. It is about a bottom-up disassembly method using existing building slabs that can prevent unexpected accidents in advance by carrying out dismantling work firmly and safely.

After the underground retaining wall is built according to the application of the earth retaining method, temporary members (retaining piles, soil plates, CIP, etc.) for earth retaining civil works are pulled out and removed, or some of them are buried in the ground, and most of the underground retaining walls built are directly in contact with the soil support

Domestic buildings over 30 years old are buildings with a significant floor area, and even if they have a basement, most of the basements are about 3 stories or less in depth, and the depth is about 4m to 17m. The reason for having a basement is related to the fact that securing an underground parking space was not an indispensable request because there were not many vehicles in the past.

Most of the underground retaining walls of buildings older than 30 years to be demolished were constructed based on earthworks using earth retaining piles, earth walls and thumb piles, or using CIP depending on the conditions of the ground.

The depth of the basement floor to which the dismantling method according to the present invention can be applied is basically useful in the case of about 1 basement floor to 3 basement floors, but more is possible depending on the retaining wall support method related to the existing building structure.

Therefore, considering that most of the buildings that are generally subject to demolition are over 30 years old and the depth of the basement is usually 3 or less underground, the dismantling method according to the present invention demolishes the entire building, including the basement, It can be applied without difficulty to most of the old buildings in Korea when a new building is to be built within the same site boundary.

If a new building is to be built within the same site boundary after demolishing a building with a basement floor, there is relatively no difficulty in demolishing the above-ground part of the old building. In the case of unauthorized destruction and removal of the retaining wall directly from the inner space enclosed by the basement, that is, the bearing wall (retaining wall) that supported the earth pressure disappears in an instant, and the demolition of the retaining wall and the holding by the retaining wall at the same time It is very dangerous because the soil can collapse into the demolition space at once as the earth pressure that has been under pressure acts all at once.

For this reason, even if most of the floor slabs, including the internal pillars of the basement floor, are removed during the demolition work of the building, there are many cases where the basement retaining wall, which is the outer wall of the building under earth pressure, cannot be demolished. The entire interior space is quickly backfilled with soil brought in from the outside.

In this case, during the next process, underground excavation of a new building, when the retaining line of the building to be newly built overlaps or intersects the remaining underground retaining wall line, which was to be demolished, problems arise such as pile drilling work for earth retaining work. Solve this In order to inevitably remove the remaining underground retaining wall by carrying out earth retaining work and excavation only for the purpose of removing the retained underground retaining wall, and then removing the remaining underground retaining wall and then performing a secondary backfill again, there is no obstacle in the ground within the boundary of the site to be newly built. In this way, earthworks must be restarted according to the underground retaining wall line of the building to be built for the bare site without any obstacles in the ground.

The general bottom-up underground retaining wall removal and reclamation method requires very cumbersome, long-term and costly earthworks to remove the problematic underground retaining wall. It is a technique that can be used very effectively when overlapping.

In other words, after completely removing the remaining underground structures except for the underground retaining wall, raker piles and rakers are installed to support the underground retaining wall, and in this state, the underground retaining wall is partially cut and removed from the lower end, and then soil backfilling is performed. By carrying out sequentially from the lower end, the underground retaining wall is safely demolished while preventing it from collapsing due to earth pressure.

However, in the above bottom-up underground retaining wall removal method, the earth pressure applied to the underground retaining wall is supported through raker and raker piles, so the size of the raker pile is excessively large, the number of rakers is large, or the rakers must be installed in a long longitudinal direction. There is a tendency to do so, not only a large load acts on the raker, but also the part of the underground retaining wall that is not supported by the raker is pushed by earth pressure, and the shear force is concentrated on the interface between the raker pile and the gusset plate for reinforcement of the joint, and the gusset plate part A problem that could cause the phenomenon of breaking through the underground retaining wall was discovered.

In addition, since the bottom-up underground retaining wall removal method requires raker piles to be driven and rakers to be installed while the remaining underground structures except for the underground retaining wall are completely removed, the underground retaining wall can be collapsed by earth pressure before installing the raker piles and rakers.

Therefore, when removing underground structures other than the underground retaining wall, after removing the floor slab and part of the inner load-bearing wall of the retaining wall, raker piles and rakers are installed. This may increase work time and cost.

In addition, in the above-mentioned bottom-up underground retaining wall removal method, since the retaining wall support method is based on the raker, it is virtually impossible to construct the raker when the depth of the retaining wall is about GL-12m or more in terms of structural review, and despite the narrow area of the basement floor plan In the case of installing the raker, construction problems such as the work flow of the equipment not coming out were also found.

Therefore, in the present invention, in order to improve the above problems, the size and area of the underground structure at a single site, and in the case of several underground structures, the retaining wall support method for each section or the required section of the structure is applied to the slab, not the raker. A support method using a reinforcing means was provided.

Japanese Patent Laid-Open No. 1995-150564

Therefore, the present invention has been made to solve the above conventional problems,

An object of the present invention is to install a slab reinforcing means (100) for each slab of an existing building, which is not a raker method, so that when demolishing the bottom of a retaining wall, the dismantling work can be carried out while preventing sagging. is to make

In order to achieve the problem to be solved by the present invention, a bottom-up disassembly method using an existing building slab according to an embodiment of the present invention,

A top-down slab reinforcement means installation step (S100) in which the process for supporting the existing slab is sequentially repeated for each underground floor by installing the slab reinforcement means 100 on the lower side of the existing slab;

After completing the above process, a foundation demolition and first soil cover process (S200) for performing a first soil cover in which the foundation structure is demolished and soil backfill is performed at a height equal to or higher than the height from which the foundation structure is removed;

A retaining wall cutting step (S300) of cutting or crushing the retaining wall located on the upper side of the foundation structure into a predetermined shape and size;

a retaining wall demolition and secondary covering process (S400) for carrying out secondary soil backfilling at a height higher than the height from which the retaining wall was removed;

After the retaining wall is removed, the slab reinforcing means 100 formed on the upper side is removed, and the existing slab located on the upper side of the slab reinforcing means 100 is removed, and then the retaining wall is cut or crushed into a predetermined shape and size, A slab and retaining wall demolition and tertiary covering process (S500) in which the retaining wall is removed upward from the bottom side upward by repeatedly performing the tertiary covering process of soil backfilling at or above the height from which the retaining wall was removed; By configuring it, it is possible to solve the problem of the present invention.

The bottom-up disassembly method using the existing building slab according to the present invention,

By installing a slab reinforcing means (100) for each slab of the existing building, which is not a raker method, when demolishing the lower part of the retaining wall, the dismantling work can be carried out while preventing sagging, so that the dismantling work can be carried out simply, firmly and safely. It provides an effect that can prevent an accident in advance.

1 is an overall process diagram of a bottom-up disassembly method using an existing building slab according to an embodiment of the present invention.
2 is an exemplary diagram briefly showing the entire process of a bottom-up disassembly method using a slab of an existing building according to an embodiment of the present invention.
3 to 4 are exemplary views showing a slab reinforcing means 100 of a bottom-up disassembly method using a slab of an existing building according to an embodiment of the present invention.
5 to 6 are process charts showing in detail the retaining wall demolition and the secondary covering process (S400) of the bottom-up disassembly method using the slab of an existing building according to an embodiment of the present invention.

The bottom-up disassembly method using the existing building slab to solve the problem of the present invention,

A top-down slab reinforcement means installation step (S100) in which the process for supporting the existing slab is sequentially repeated for each underground floor by installing the slab reinforcement means 100 on the lower side of the existing slab;

After completing the above process, a foundation demolition and first soil cover process (S200) for performing a first soil cover in which the foundation structure is demolished and soil backfill is performed at a height equal to or higher than the height from which the foundation structure is removed;

A retaining wall cutting step (S300) of cutting or crushing the retaining wall located on the upper side of the foundation structure into a predetermined shape and size;

a retaining wall demolition and secondary covering process (S400) for carrying out secondary soil backfilling at a height higher than the height from which the retaining wall was removed;

After the retaining wall is removed, the slab reinforcing means 100 formed on the upper side is removed, and the existing slab located on the upper side of the slab reinforcing means 100 is removed, and then the retaining wall is cut or crushed into a predetermined shape and size, A slab and retaining wall demolition and tertiary covering process (S500) in which the retaining wall is removed upward from the bottom side upward by repeatedly performing the tertiary covering process of soil backfilling at or above the height from which the retaining wall was removed; It is characterized by doing.

At this time, the slab reinforcement means 100,

A retaining wall steel plate reinforcement part 110 installed on the retaining wall to reinforce the retaining wall; and

A slab support steel member 120 installed on the lower side of the existing slab and having one side coupled to the retaining wall steel plate reinforcement part 110; and

A first reinforcing member 130 for reinforcing the slab supporting steel member 120 by having one side coupled to the H pile and the other side coupled to the slab supporting steel member 120; and

It is characterized in that it is configured to include; one side is coupled to the slab support steel member 120, and the other side is coupled to the H-file to reinforce the slab support steel member 120. .

At this time, the slab reinforcement means 100,

When demolishing the bottom of the retaining wall, it is characterized in that it includes preventing sagging.

At this time, the retaining wall removal and secondary soil cover process (S400),

A first part demolition step (S410) of cutting or crushing the lowermost retaining wall of the underground retaining wall into a predetermined shape and size, but cutting or crushing it at regular intervals;

A retaining wall sagging prevention bracket installation step (S420) of installing a retaining wall sagging prevention bracket for preventing sagging of the retaining wall at each of the incised or crushed locations;

A second part demolition step (S430) of cutting or crushing the underground retaining wall existing between the cut or crushed positions at a predetermined interval into a predetermined shape and size, and cutting or crushing the retaining wall at a predetermined interval;

A backfilling process (S440) for dismantling the struts supporting the underground retaining wall and performing soil backfilling;

The retaining wall formed on the upper side of the soil backfill position is cut or crushed in a predetermined shape and size, but cut or crushed at regular intervals, and a retaining wall sagging prevention bracket is installed at each cut or crushed position to prevent sagging of the retaining wall Demolition of the third part of the retaining wall / bracket installation process for preventing sagging of the retaining wall (S450);

Partial excavation/retaining wall sagging prevention bracket disassembly process (S460) of partially excavating the surrounding area where the retaining wall sagging prevention bracket installed in the retaining wall sagging prevention bracket installation process (S420) is located and dismantling the retaining wall sagging prevention bracket;

Cutting or crushing the underground retaining wall existing between the cut or broken positions formed in the third part demolition of the retaining wall / retaining wall sagging prevention bracket installation process (S450) in a predetermined shape and size, but cutting or crushing at regular intervals Retaining wall It is characterized in that it includes; a fourth partial removal process (S470).

At this time, it is characterized in that the first partial retaining wall demolition process (S410) to the fourth partial retaining wall demolition process (S470) are sequentially and repeatedly performed for each basement floor.

Hereinafter, a bottom-up disassembly method using an existing building slab according to the present invention will be described in detail through an embodiment.

1 is an overall process diagram of a bottom-up disassembly method using an existing building slab according to an embodiment of the present invention.

2 is an exemplary diagram briefly showing the entire process of a bottom-up disassembly method using a slab of an existing building according to an embodiment of the present invention.

As shown in FIGS. 1 and 2, the bottom-up disassembly method using the existing building slab,

A top-down slab reinforcement means installation step (S100) in which the process for supporting the existing slab is sequentially repeated for each underground floor by installing the slab reinforcement means 100 on the lower side of the existing slab;

After completing the above process, a foundation demolition and first soil cover process (S200) for performing a first soil cover in which the foundation structure is demolished and soil backfill is performed at a height equal to or higher than the height from which the foundation structure is removed;

A retaining wall cutting step (S300) of cutting or crushing the retaining wall located on the upper side of the foundation structure into a predetermined shape and size;

a retaining wall demolition and secondary covering process (S400) for carrying out secondary soil backfilling at a height higher than the height from which the retaining wall was removed;

After the retaining wall is removed, the slab reinforcing means 100 formed on the upper side is removed, and the existing slab located on the upper side of the slab reinforcing means 100 is removed, and then the retaining wall is cut or crushed into a predetermined shape and size, A slab and retaining wall demolition and tertiary covering process (S500) in which the retaining wall is removed upward from the bottom side upward by repeatedly performing the tertiary covering process of soil backfilling at or above the height from which the retaining wall was removed; It is characterized by doing.

Specifically, the top-down slab reinforcement means installation process (S100) is a process of sequentially repeating the process for supporting the existing slab by installing the slab reinforcement means 100 on the lower side of the existing slab for each basement floor. However, as shown in FIG. 2, in the case of the third basement floor, the slab reinforcing means 100 is installed on the lower side of the existing slab to reinforce the existing slab.

Thereafter, the slab reinforcing means 100 is installed on the lower side of the existing slab in the second and third stages of the slab to reinforce the existing slab.

In addition, the foundation demolition and first soil cover process (S200) is a process for performing the first soil cover after completing the above process, removing the foundation structure and performing earth and sand backfilling at a height equal to or higher than the height from which the foundation structure was removed.

Through this, the occurrence of sagging is prevented, thereby preventing the inflow of soil into the space where the foundation structure is removed.

And, the retaining wall cutting process (S300) is a process of cutting or crushing the retaining wall located on the upper side of the foundation structure into a predetermined shape and size.

And, the retaining wall demolition and secondary covering process (S400) is a process of performing the secondary soil backfilling to a height equal to or higher than the height from which the retaining wall was removed.

Through this, the occurrence of sagging is prevented, thereby preventing the inflow of soil into the space where the foundation structure is removed.

In the slab and retaining wall removal and tertiary cover process (S500), after the retaining wall is removed, the slab reinforcing means 100 formed on the upper side is removed, and the existing slab located on the upper side of the slab reinforcing means 100 is removed. do.

Thereafter, the tertiary covering process is performed in which the retaining wall is cut or crushed into a predetermined shape and size, and soil backfilling is performed at a height equal to or higher than the height from which the retaining wall was removed.

At this time, the slab and retaining wall removal and the tertiary covering process (S500) are repeatedly performed to remove the retaining wall upward from the lower end side in a bottom-up manner.

For example, after removing the 3rd stage of the slab, remove the slab reinforcing means 100 of the 2nd stage of the slab located on the upper side again, remove the existing slab located on the upper side of the slab reinforcing means 100, and then remove the retaining wall It will be.

Thereafter, after removing the second stage of the slab, the slab reinforcing means 100 of the first stage of the slab located on the upper side is removed, and the existing slab located on the upper side of the slab reinforcing means 100 is removed, and then the retaining wall is removed. .

After that, demolition and covering are completed.

On the other hand, the slab reinforcing means 100, which is a key component of the present invention,

A retaining wall steel plate reinforcement part 110 installed on the retaining wall to reinforce the retaining wall; and

A slab support steel member 120 installed on the lower side of the existing slab and having one side coupled to the retaining wall steel plate reinforcement part 110; and

A first reinforcing member 130 for reinforcing the slab supporting steel member 120 by having one side coupled to the H pile and the other side coupled to the slab supporting steel member 120; and

It is characterized in that it is configured to include; one side is coupled to the slab support steel member 120, and the other side is coupled to the H-file to reinforce the slab support steel member 120. .

To be described in detail with reference to FIGS. 3 and 4, the slab reinforcing means 100 includes a retaining wall steel plate reinforcement part 110, a slab support steel part 120, a first reinforcing part 130, and a second reinforcing frame It is configured to include the unit 140.

Through the above components, it is characterized in that the sagging phenomenon is prevented when the lower retaining wall is demolished.

To be specific, the slab reinforcing means 100,

A retaining wall steel plate reinforcement part 110 installed on the retaining wall to reinforce the retaining wall; and

A slab support steel member 120 installed on the lower side of the existing slab and having one side coupled to the retaining wall steel plate reinforcement part 110; and

A first reinforcing member 130 for reinforcing the slab supporting steel member 120 by having one side coupled to the H pile and the other side coupled to the slab supporting steel member 120; and

It includes a second reinforcing frame part 140 for reinforcing the slab supporting steel member 120 by having one side coupled to the slab supporting steel member 120 and the other side coupled to the H pile.

That is, as shown in FIGS. 3 and 4, the retaining wall iron plate reinforcement part 110 is installed on the retaining wall to reinforce the retaining wall.

At this time, after reinforcement using the retaining wall iron plate, after installing the slab support steel member 120, welding is performed.

The slab support steel member 120 is installed on the lower side of the existing slab, and one side is coupled to the retaining wall steel plate reinforcement part 110.

The coupling may be performed through welding, and may also be coupled through other coupling means.

In addition, the first reinforcing steel part 130 is installed, and at this time, one side is coupled to the H file, and the other side is coupled to the slab supporting steel part 120 so that the slab supporting steel part 120 sags. will be reinforced secondarily.

In addition, the second reinforcing frame part 140 is installed, and at this time, one side is coupled to the slab support steel member 120 and the other side is coupled to the H-file to cause the slab support steel member 120 to sag. will be reinforced three-dimensionally.

As described above, the reason for performing the tertiary reinforcement is that sagging occurs during the demolition of the underground retaining wall. Together, various reinforcing means are formed.

On the other hand, as shown in FIGS. 5 to 6, the retaining wall removal and secondary soil cover process (S400),

A first part demolition step (S410) of cutting or crushing the lowermost retaining wall of the underground retaining wall into a predetermined shape and size, but cutting or crushing it at regular intervals;

A retaining wall sagging prevention bracket installation step (S420) of installing a retaining wall sagging prevention bracket for preventing sagging of the retaining wall at each of the incised or crushed locations;

A second part demolition step (S430) of cutting or crushing the underground retaining wall existing between the cut or crushed positions at a predetermined interval into a predetermined shape and size, and cutting or crushing the retaining wall at a predetermined interval;

A backfilling process (S440) for dismantling the struts supporting the underground retaining wall and performing soil backfilling;

The retaining wall formed on the upper side of the soil backfill position is cut or crushed in a predetermined shape and size, but cut or crushed at regular intervals, and a retaining wall sagging prevention bracket is installed at each cut or crushed position to prevent sagging of the retaining wall Demolition of the third part of the retaining wall / bracket installation process for preventing sagging of the retaining wall (S450);

Partial excavation/retaining wall sagging prevention bracket disassembly process (S460) of partially excavating the surrounding area where the retaining wall sagging prevention bracket installed in the retaining wall sagging prevention bracket installation process (S420) is located and dismantling the retaining wall sagging prevention bracket;

Cutting or crushing the underground retaining wall existing between the cut or broken positions formed in the third part demolition of the retaining wall / retaining wall sagging prevention bracket installation process (S450) in a predetermined shape and size, but cutting or crushing at regular intervals Retaining wall It is characterized in that it includes; a fourth partial removal process (S470).

Through the above process, when demolishing the lower part of the retaining wall, it is possible to proceed with the dismantling work while preventing sagging, providing the advantage of performing the dismantling work simply, firmly and safely.

Specifically, the first partial retaining wall demolition process (S410) is a process of cutting or crushing the lowermost retaining wall of the underground retaining wall in a predetermined shape and size, but at regular intervals.

First of all, the lowermost retaining wall of the underground retaining wall is incised in a predetermined shape and size, and is incised or crushed at regular intervals.

Thereafter, the retaining wall sagging prevention bracket installation process (S420) is a process of installing retaining wall sagging prevention brackets for preventing sagging of the retaining wall at each of the incised or crushed positions.

As described above, the reason for installing the retaining wall sagging prevention bracket is to completely prevent any unexpected sagging.

In the example, six retaining wall sagging prevention brackets were installed at regular intervals.

Thereafter, the second part demolition process of the retaining wall (S430) is a process of cutting or crushing the underground retaining wall existing between the incised or fractured positions at a predetermined interval in a predetermined shape and size, while incising or crushing at a predetermined interval. .

In the first partial retaining wall demolition process (S410), portions of the retaining wall that have not been cut or broken are cut or broken at regular intervals.

Thereafter, the backfilling process (S440) is a process for dismantling the struts supporting the underground retaining wall and performing soil backfilling.

That is, the struts are dismantled and the underground retaining wall is supported through soil backfilling.

Thereafter, in the third part demolition of the retaining wall / bracket installation process for preventing sagging of the retaining wall (S450), the retaining wall formed on the upper side of the soil backfill position is cut or crushed in a predetermined shape and size, but cut or crushed at regular intervals, This is the process of installing retaining wall sagging prevention brackets to prevent sagging of the retaining wall at each incised or fractured location.

That is, the retaining wall formed on the upper side of the soil backfill position is cut or crushed into a predetermined shape and size at regular intervals.

At this time, a retaining wall sagging prevention bracket is installed to prevent sagging of the retaining wall at each incised or crushed position.

Through this, sagging of the retaining wall is prevented at each incised or fractured location.

Thereafter, the partial excavation/retaining wall sagging prevention bracket disassembly process (S460) is a process of partially excavating the surrounding area where the retaining wall sagging prevention bracket installed in the retaining wall sagging prevention bracket installation process (S420) is located, and dismantling the retaining wall sagging prevention bracket am.

That is, as shown in FIG. 6, the surrounding area where the retaining wall sagging prevention bracket is located is partially excavated, and the retaining wall sagging prevention bracket is dismantled.

As described above, if the bracket for preventing sagging of the retaining wall is not dismantled, after the final covering, the process for removing the bracket for preventing sagging of the retaining wall should be performed again, so the above process is performed to remove this unnecessary process.

Thereafter, in the 4th partial retaining wall demolition process (S470), the underground retaining wall existing between the incised or crushed positions formed in the 3rd partial retaining wall demolition/retaining wall deflection prevention bracket installation process (S450) is cut into a predetermined shape and size, or It is a process of cutting or crushing at regular intervals while crushing.

That is, the part of the retaining wall existing between the incised or broken positions formed in the step of removing the retaining wall third part/installing the retaining wall sagging prevention bracket (S450) is cut or broken.

Therefore, in the retaining wall demolition and secondary cover process (S400) of the present invention, the first retaining wall partial demolition process (S410) to the retaining wall fourth partial demolition process (S470) are sequentially and repeatedly performed for each basement floor, through which Ultimately, it is possible to demolish and cover the underground retaining wall.

Those skilled in the art to which the present invention pertains as described above will understand that it can be implemented in other specific forms without changing the technical spirit or essential characteristics of the present invention. Therefore, the embodiments described above are illustrative in all respects and should be understood as non-limiting ones.

100: slab reinforcement means
110: Retaining wall steel plate reinforcement
120: slab support steel part
130: first reinforcing member
140: second reinforcing frame part

Claims (5)

In the bottom-up disassembly method using the existing building slab,
A top-down slab reinforcement means installation step (S100) in which the process for supporting the existing slab is sequentially repeated for each underground floor by installing the slab reinforcement means 100 on the lower side of the existing slab;
After completing the above process, a foundation demolition and first soil cover process (S200) for performing a first soil cover in which the foundation structure is demolished and soil backfill is performed at a height equal to or higher than the height from which the foundation structure is removed;
A retaining wall cutting step (S300) of cutting or crushing the retaining wall located on the upper side of the foundation structure into a predetermined shape and size;
a retaining wall demolition and secondary covering process (S400) for carrying out secondary soil backfilling at a height higher than the height from which the retaining wall was removed;
After the retaining wall is removed, the slab reinforcing means 100 formed on the upper side is removed, and the existing slab located on the upper side of the slab reinforcing means 100 is removed, and then the retaining wall is cut or crushed into a predetermined shape and size, A slab and retaining wall demolition and tertiary covering process (S500) in which the retaining wall is removed upward from the bottom side upward by repeatedly performing the tertiary covering process of soil backfilling at or above the height from which the retaining wall was removed; It is characterized by
The slab reinforcement means 100,
A retaining wall steel plate reinforcement part 110 installed on the retaining wall to reinforce the retaining wall; and
A slab support steel member 120 installed on the lower side of the existing slab and having one side coupled to the retaining wall steel plate reinforcement part 110; and
A first reinforcing member 130 for reinforcing the slab supporting steel member 120 by having one side coupled to the H pile and the other side coupled to the slab supporting steel member 120; and
A second reinforcing frame part 140 for reinforcing the slab support steel member 120 by having one side coupled to the slab support steel member 120 and the other side coupled to the H-file; characterized in that it includes,
The retaining wall removal and secondary soil cover process (S400),
A first part demolition step (S410) of cutting or crushing the lowermost retaining wall of the underground retaining wall into a predetermined shape and size, but cutting or crushing it at regular intervals;
A retaining wall sagging prevention bracket installation step (S420) of installing a retaining wall sagging prevention bracket for preventing sagging of the retaining wall at each of the incised or crushed locations;
A second part demolition step (S430) of cutting or crushing the underground retaining wall existing between the cut or crushed positions at a predetermined interval into a predetermined shape and size, and cutting or crushing the retaining wall at a predetermined interval;
A backfilling process (S440) for dismantling the struts supporting the underground retaining wall and performing soil backfilling;
The retaining wall formed on the upper side of the soil backfill position is cut or crushed in a predetermined shape and size, but cut or crushed at regular intervals, and a retaining wall sagging prevention bracket is installed at each cut or crushed position to prevent sagging of the retaining wall Demolition of the third part of the retaining wall / bracket installation process for preventing sagging of the retaining wall (S450);
Partial excavation/retaining wall sagging prevention bracket disassembly process of partially excavating the surrounding area where the retaining wall sagging prevention bracket installed in the retaining wall sagging prevention bracket installation process (S420) is located and dismantling the retaining wall sagging prevention bracket (S460);
Cutting or crushing the underground retaining wall existing between the cut or broken positions formed in the third part demolition of the retaining wall / retaining wall sagging prevention bracket installation process (S450) in a predetermined shape and size, but cutting or crushing at regular intervals Retaining wall A bottom-up disassembly method using an existing building slab, characterized in that it comprises a fourth partial demolition process (S470).
delete According to claim 1,
The slab reinforcement means 100,
A bottom-up disassembly method using an existing building slab, comprising preventing sagging when demolishing the bottom of a retaining wall.
delete According to claim 1,
Bottom-up disassembly method using an existing building slab, characterized in that the first part demolition process (S410) to the fourth part demolition process (S470) of the retaining wall are sequentially and repeatedly performed for each underground floor.