KR102645823B1 - Top-down and bottom-up parallel decommissioning of existing building - Google Patents

Abstract

The present invention relates to a top-down and bottom-up parallel dismantling method of an existing building. More specifically, in the case of the first floor above ground and the first basement floor, the slab and retaining wall are demolished, then struts and earth plates are installed, and from the second basement floor to the basement. After demolishing the slab up to the structure, performing a top-down dismantling process to install struts, demolishing the foundation structure, and performing soil backfilling, demolition of retaining walls, dismantling of struts, and soil for each floor from the foundation structure to the second basement floor. By performing a bottom-up dismantling process that performs backfilling, dismantling work can be carried out while preventing sagging when demolishing the bottom of a retaining wall without the need to drill and install H beams to the foundation structure, allowing dismantling work to be performed simply, robustly, and safely. It concerns top-down and bottom-up parallel dismantling methods of existing buildings.

Description

Top-down and bottom-up parallel decommissioning of existing building}

The present invention relates to a top-down and bottom-up parallel dismantling method of an existing building. More specifically, in the case of the first floor above ground and the first basement floor, the slab and retaining wall are demolished, then struts and earth plates are installed, and from the second basement floor to the basement. After demolishing the slab up to the structure, performing a top-down dismantling process to install struts, demolishing the foundation structure, and performing soil backfilling, demolition of retaining walls, dismantling of struts, and soil for each floor from the foundation structure to the second basement floor. By performing a bottom-up dismantling process that performs backfilling, dismantling work can be carried out while preventing sagging when demolishing the bottom of a retaining wall without the need to drill and install H beams to the foundation structure, allowing dismantling work to be performed simply, robustly, and safely. It concerns top-down and bottom-up parallel dismantling methods of existing buildings.

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

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

Most underground retaining walls of buildings older than 30 years old that are subject to demolition are constructed based on earthworks using retaining piles, earth walls, and thumb piles, or using CIP depending on the ground conditions.

Basically, if the depth of the basement to which the dismantling method according to the present invention can be applied is approximately 2 or more underground, it can be applied according to 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 older than 30 years and the depth of the basement is usually less than 3 stories underground or more than 3 stories underground, the demolition method according to the present invention is used to remove the entire building including the basement floor. It can be applied without difficulty to most old buildings in Korea when a new building is to be constructed within the same site boundary after demolition.

If a new building is to be constructed within the same property boundary after demolishing a building with a basement, there is relatively no difficulty in demolishing the above-ground part of the old building, but since the underground part, especially the underground retaining wall, is a part that is subject to significant earth pressure, the underground retaining wall is required. If the retaining wall is destroyed and demolished directly from the inner space surrounded by the basement, that is, the inner space of the basement, the load-bearing wall (retaining wall) that supported the earth pressure will disappear in an instant, and at the same time as the retaining wall is demolished, it will be held by the retaining wall. It is very dangerous because the earth pressure exerted all at once can cause the soil to collapse into the demolition space.

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

In this case, during the next process, the underground excavation of a new building, if the retaining line of the building to be newly constructed overlaps or intersects the line of the remaining underground retaining wall that was subject to demolition, problems arise in the pile drilling work for retaining the retaining wall. This problem is solved. In order to do this, it was necessary to carry out earth retaining work and excavation just for the purpose of removing the remaining underground retaining wall, and then perform secondary backfilling to ensure that there were no obstacles in the ground within the boundary of the new construction site. It is necessary to create a bare land condition and restart earthworks in accordance with the underground retaining wall line of the building to be newly built on a bare land with no obstacles in the ground.

The general upward underground retaining wall removal and reclamation method is used in cases where extremely cumbersome, long-term, and expensive earthworks are required to demolish the problematic underground retaining wall, especially when the underground retaining wall line of the building to be newly constructed is used to replace the underground retaining wall line to be demolished. This is a method that can be used very effectively in cases of overlap.

In other words, after completely removing the remaining underground structures except for the underground retaining wall, raker piles and raker are installed to support the underground retaining wall. In this state, the underground retaining wall is partially incised from the bottom to be removed, and then soil backfill is performed. By performing this sequentially from the bottom, the underground retaining wall is safely demolished while preventing it from collapsing due to earth pressure.

However, in the above-mentioned bottom-up underground retaining wall removal method, the earth pressure applied to the underground retaining wall is supported through the raker and raker pile, so the size of the raker pile must be excessively large, the number of rakers must be increased, or the raker must be installed long in the longitudinal direction. Not only does a large load apply to the raker, but the part of the underground retaining wall that is not supported by the raker is pushed in by earth pressure, and the shear force is concentrated on the interface between the raker pile and the gusset plate for reinforcing the joint, thereby concentrating the gusset plate portion. A problem was discovered that could cause the underground retaining wall to break through.

In addition, the bottom-up underground retaining wall removal method involves driving raker piles and installing the raker while completely removing all underground structures except the underground retaining wall, so the underground retaining wall may collapse due to earth pressure before installing the raker piles and rakers.

Therefore, when removing underground structures other than the underground retaining wall, the floor slab and part of the load-bearing wall inside the retaining wall are removed and then raker piles and rakers are installed. These remaining underground structures can become obstacles to raker installation, and work to remove them is required. This may increase work time and costs.

In addition, in the above-mentioned upward underground retaining wall removal method, the retaining wall support method is based on a raker, so when the depth of the retaining wall is more than about GL-12m according to the structural review, raker construction is virtually impossible, and even though the planar area of the basement is narrow, When the raker was installed, construction problems were also discovered, such as the equipment's work movement line not being visible.

Therefore, in order to improve the above-mentioned problems, the present invention proposes a method that can simultaneously provide a top-down dismantling method and a bottom-up dismantling method.

Japanese Patent Publication No. 1995-150564

Therefore, the present invention was devised to solve the above conventional problems,

The purpose of the present invention is to install struts and earthen plates after demolishing the slabs and retaining walls in the case of the first floor above ground and the first floor underground, and to install struts after demolishing the slabs from the second basement floor to the underground structure. After performing the demolition of the basic structure, performing soil backfilling, and performing a bottom-up dismantling process of demolishing retaining walls, dismantling struts, and performing soil backfilling for each floor from the basic structure to the second basement floor, the H beam was laid as a foundation. The purpose is to allow dismantling work to be carried out while preventing sagging when demolishing the bottom of a retaining wall without the need to drill into the structure or install it very deeply, making it simple, sturdy, and safe.

In order to achieve the problem that the present invention seeks to solve, the top-down and bottom-up parallel dismantling method of an existing building according to an embodiment of the present invention is,

A pile installation step (S1000) in which center piles and side piles are installed in the center and side areas of the existing building,

After performing the above pile installation step, in the case of the first floor above ground and the first basement floor, the slabs and retaining walls are demolished, then struts and earth plates are installed, and the slabs are demolished from the second basement floor to the underground structure, and then the struts are installed. A top-down disassembly step (S2000),

After performing the top-down dismantling step, the basic structure is demolished, soil backfilling is performed, and then a bottom-up dismantling step (S3000) is performed in which retaining wall demolition, strut dismantling, and soil backfilling are performed for each floor from the basic structure to the second basement floor. By including and configuring, the problem of the present invention is solved.

The top-down and bottom-up parallel dismantling method of an existing building according to the present invention,

In the case of the first floor above ground and the first basement floor, the slabs and retaining walls are demolished, then struts and earth plates are installed. After the slabs are demolished from the second basement floor to the underground structure, and the struts are installed, a top-down dismantling process is performed. After demolishing the foundation structure and performing soil backfilling, a bottom-up dismantling process is performed to demolish retaining walls, dismantle struts, and perform soil backfilling for each floor from the foundation structure to the second basement level, thereby drilling the H beam to the foundation structure, or When dismantling the bottom of a retaining wall without having to install it very deeply, dismantling work can be carried out while preventing sagging, allowing dismantling work to be performed simply, robustly and safely, providing the effect of preventing unexpected accidents in advance. .

Figure 1 is an overall process diagram of a top-down and bottom-up parallel dismantling method of an existing building according to an embodiment of the present invention.
Figure 2 is an exemplary diagram briefly showing the entire process of the top-down and bottom-up parallel dismantling method of an existing building according to an embodiment of the present invention.
Figure 3 is an example diagram schematically showing a conventional top-down dismantling method of an existing building.
Figure 4 is an exemplary diagram briefly showing the entire process of the top-down and bottom-up parallel dismantling method of an existing building according to an embodiment of the present invention.
Figures 5 and 6 are exemplary diagrams showing the top-down and bottom-up parallel dismantling methods of an existing building by process, according to an embodiment of the present invention.

The top-down and bottom-up parallel dismantling method of an existing building to solve the problem of the present invention is,

A pile installation step (S1000) in which center piles and side piles are installed in the center and side areas of the existing building,

After performing the above pile installation step, in the case of the first floor above ground and the first basement floor, the slabs and retaining walls are demolished, then struts and earth plates are installed, and the slabs are demolished from the second basement floor to the underground structure, and then the struts are installed. A top-down disassembly step (S2000),

After performing the top-down dismantling step, the basic structure is demolished, soil backfilling is performed, and then a bottom-up dismantling step (S3000) is performed in which retaining wall demolition, strut dismantling, and soil backfilling are performed for each floor from the basic structure to the second basement floor. It is characterized by including.

Specifically, the top-down and bottom-up parallel dismantling method of an existing building according to the present invention is,

After demolition of the ground, drilling is performed to install the side piles, and a side pile installation step (S100) to install the side piles at the perforated location;

After installing the side piles, drilling holes for installing center piles, and installing center piles at the perforated positions (S200);

After installing the center pile, the slab and retaining wall on the first floor above ground are demolished, the first strut and the first earth plate are installed on the lower side of the demolished location, and the second strut and the second earth plate are installed on the upper side of the first strut and the first earth plate. Ground strut and earth plate installation step for installing the earth plate (S300); and

After completing the above process, the slab and retaining wall of the first basement floor are demolished, the first strut and the first earth plate are installed on the lower side of the demolished location, and the second strut and the second earth plate are installed on the upper side of the first strut and the first earth plate. Basement first floor strut and earth plate installation step (S400) to install; and

After completing the above process, the slabs are demolished on each floor starting from the 2nd basement floor downward, the first strut is installed on the lower side of the demolished position, and the second strut is installed on the upper side of the first strut. Strut installation step for each basement floor (S500), which is performed sequentially and repeatedly for each floor starting downwards;

After completing the above process, the foundation structure and retaining wall at the lowest level of the basement are demolished, the first strut installed at the lowest level underground is dismantled, and then the first covering is performed by backfilling soil above the height at which the first strut was removed. Foundation demolition and first covering stage (S600) for

After carrying out the first covering process, the retaining wall is demolished while dismantling the struts from the lower part of the basement to the upper side, and the second covering process of performing soil backfilling at the corresponding location is repeatedly performed for each floor. Strut dismantling and 2 It is characterized in that it includes a subsoil step (S700).

At this time, by removing the slab and retaining wall by performing the top-down dismantling and bottom-up dismantling in parallel, there is no need to drill and install the H beam to the foundation structure.

At this time, as top-down dismantling and bottom-up dismantling are performed in parallel, sagging is prevented when the lower part of the retaining wall is demolished.

Hereinafter, the top-down and bottom-up parallel dismantling method of an existing building according to the present invention will be described in detail through examples.

Figure 1 is an overall process diagram of a top-down and bottom-up parallel dismantling method of an existing building according to an embodiment of the present invention.

Figure 2 is an exemplary diagram briefly showing the entire process of the top-down and bottom-up parallel dismantling method of an existing building according to an embodiment of the present invention.

As shown in Figure 1, the present invention includes a pile installation step (S1000) of installing center piles and side piles in the center and side areas of an existing building,

After performing the above pile installation step, in the case of the first floor above ground and the first basement floor, the slabs and retaining walls are demolished, then struts and earth plates are installed, and the slabs are demolished from the second basement floor to the underground structure, and then the struts are installed. A top-down disassembly step (S2000),

After performing the top-down dismantling step, the basic structure is demolished, soil backfilling is performed, and then a bottom-up dismantling step (S3000) is performed in which retaining wall demolition, strut dismantling, and soil backfilling are performed for each floor from the basic structure to the second basement floor. It is characterized by including.

In general, as shown in FIG. 3, the conventional top-down dismantling method requires drilling to install the H beam deeply into the foundation structure and driving it deep into the foundation structure, which causes the problem of delayed construction costs and construction period. did.

In addition, when the rigidity of the foundation structure is high, drilling is impossible, which causes delays in construction.

However, as shown in Figure 4, when the process is performed as above, the slab and retaining wall are removed through top-down dismantling and bottom-up dismantling in parallel, so there is no need to drill and install the H beam to the basic structure.

To be specific, the pile installation step (S1000) is a process of installing center piles and side piles in the center and side areas of the existing building. As shown in Figure 2, after demolition of the ground, drilling is performed to install side piles. And a side pile installation step (S100) to install the side pile at the perforated location; and

After installing the side piles, a center pile installation step (S200) is included to drill a hole for installing the center pile and install the center pile at the perforated location.

That is, as shown in FIG. 5, after the ground is removed, a hole is drilled to install the side pile, and the side pile is installed at the perforated location (S100).

Afterwards, a drilling process is performed to install the center pile, and the center pile is installed at the perforated location to safely dismantle the existing building.

Afterwards, in the top-down dismantling step (S2000), after performing the pile installation step, in the case of the first floor above ground and the first basement floor, the slab and retaining wall are demolished, then struts and earth plates are installed, and the slab is installed from the second basement floor to the underground structure. As a process of installing struts after demolishing, as shown in FIG. 2, after installing the center pile, the first floor slab and retaining wall are demolished, and the first strut and first earth plate are installed on the lower side of the demolished position. Installing a ground strut and earth plate installation step (S300) for installing the second strut and the second earth plate on the upper side of the first strut and the first earth plate; and

After completing the above process, the slab and retaining wall of the first basement floor are demolished, the first strut and the first earth plate are installed on the lower side of the demolished location, and the second strut and the second earth plate are installed on the upper side of the first strut and the first earth plate. Basement first floor strut and earth plate installation step (S400) to install; and

After completing the above process, the slabs are demolished on each floor starting from the 2nd basement floor downward, the first strut is installed on the lower side of the demolished position, and the second strut is installed on the upper side of the first strut. It includes a strut installation step for each basement floor (S500), which is sequentially repeated for each floor downward.

Specifically, as shown in Figure 5, the process of demolishing the slab and retaining wall on the first floor above ground is carried out, and the first strut and first earth plate are installed below the location where the first floor slab and retaining wall were demolished. It will be installed.

Then, the second strut and the second earth plate are installed at a certain distance above the first strut and the first earth plate (S300).

Afterwards, in the case of the first basement floor, the slab and retaining wall were demolished like the first floor above ground, the first strut and the first earth plate were installed on the lower side of the demolished location, and the second strut was installed on the upper side of the first strut and the first earth plate. And the second earthen plate is installed (S400).

After completing the above process, the slabs are demolished on each floor starting from the 2nd basement floor downward, the first strut is installed on the lower side of the demolished position, and the second strut is installed on the upper side of the first strut. The process is repeated sequentially for each floor starting downwards (S500).

In the example of the present invention, the 3rd basement floor is described, so the first and second strut installation processes are performed from the 2nd basement floor to the 3rd basement floor, respectively.

For example, the slab on the second basement floor is demolished, and the first strut (6 stages) and the second strut (5 stages) are installed.

The process for the second basement floor is completed, the slab on the third basement floor is demolished, and the first strut (8 stages) and the second strut (7 stages) are installed.

Afterwards, in the bottom-up dismantling step (S3000), the top-down dismantling step is performed, the basic structure is demolished, soil backfilling is performed, and retaining wall demolition, strut dismantling, and soil backfilling are performed for each floor from the basic structure to the second basement floor. As a process, as shown in FIG. 2, after completing the above process, the foundation structure and retaining wall at the lowest underground level are demolished, and the first strut installed at the lowest underground level is dismantled, and then the height above the height at which the first strut was removed is removed. Foundation demolition and first covering step (S600) to perform the first covering with soil backfilling; and

After carrying out the first covering process, the retaining wall is demolished while dismantling the struts from the lower part of the basement to the upper side, and the second covering process of performing soil backfilling at the corresponding location is repeatedly performed for each floor. Strut dismantling and 2 It includes a sub-covering soil step (S700).

That is, as shown in FIG. 6, the foundation structure and retaining wall at the lowest underground level are demolished, the first strut installed at the lowest underground level is dismantled, and then soil backfilling is performed above the height at which the first strut was removed. Covering soil is performed (S600).

In the example of the present invention, since it exists up to the 3rd basement floor, the foundation structure of the 3rd basement floor is removed, the retaining wall is demolished, and the first strut (8 stages) installed at the lowest basement is dismantled, and then the first strut is Soil backfilling is carried out beyond the removed height.

After carrying out the first covering process, the process of performing a secondary covering process of dismantling the retaining wall by dismantling the struts from the lower part of the basement to the upper side and performing soil backfilling at the corresponding location is repeatedly performed for each floor (S700). will be.

In other words, while dismantling the second strut (7th stage), the retaining wall is removed and soil backfill is performed at the corresponding location.

In addition, while dismantling the struts on the second basement floor, the retaining wall will be removed, and soil backfill will be performed at the corresponding location.

These processes are performed repeatedly for each layer, and soil backfill is carried out until the final ground level.

Through this, sagging is prevented and the unfortunate event of soil flowing into the space where the structure was demolished is prevented.

Through the above configuration and process, in the case of the first floor above ground and the first basement floor, the slabs and retaining walls are removed, then struts and earth plates are installed, and the slabs are demolished from the second basement floor to the underground structure, and then struts are installed. After performing a top-down dismantling process, demolishing the basic structure, performing soil backfilling, and then performing a bottom-up dismantling process of demolishing retaining walls, dismantling struts, and performing soil backfilling for each floor from the basic structure to the second basement floor, Dismantling work can be carried out while preventing sagging when demolishing the bottom of a retaining wall without the need to drill H beams to the foundation structure or install them very deeply, allowing dismantling work to be performed simply, robustly and safely, preventing unexpected accidents in advance. It provides preventable effects.

Those skilled in the art to which the present invention pertains as described above will understand that the present invention can be implemented in other specific forms without changing its technical idea or essential features. Therefore, the embodiments described above should be understood in all respects as illustrative and not limiting.

S1000: File installation stage
S2000: Top-down disassembly phase
S3000: Bottom-up disassembly stage

Claims (3)

In the top-down and bottom-up parallel dismantling method of an existing building,
A pile installation step (S1000) in which center piles and side piles are installed in the center and side areas of the existing building,
After performing the above pile installation step, in the case of the first floor above ground and the first basement floor, the slabs and retaining walls are demolished, then struts and earth plates are installed, and the slabs are demolished from the second basement floor to the underground structure, and then the struts are installed. A top-down disassembly step (S2000),
After performing the top-down dismantling step, the basic structure is demolished, soil backfilling is performed, and then a bottom-up dismantling step (S3000) is performed in which retaining wall demolition, strut dismantling, and soil backfilling are performed for each floor from the basic structure to the second basement floor. Characterized by including,
The file installation step (S1000) is,
After demolition of the ground, drilling is performed to install the side piles, and a side pile installation step (S100) to install the side piles at the perforated location;
After installing the side piles, drilling holes to install center piles, and a center pile installation step (S200) for installing the center piles at the perforated positions,
In the top-down disassembly step (S2000),
After installing the center pile, the slab and retaining wall on the first floor above ground are demolished, the first strut and first earth plate are installed on the lower side of the demolished location, and the second strut and second earth plate are installed on the upper side of the first strut and first earth plate. Ground strut and earth plate installation step (S300) to install; and
After completing the ground strut and earth plate installation step (S300), the slab and retaining wall on the first basement floor are demolished, the first strut and the first earth plate are installed on the lower side of the demolished location, and the upper side of the first strut and the first earth plate First basement floor strut and earth plate installation step (S400) to install the second strut and second earth plate; and
After completing the first basement floor strut and earth plate installation step (S400), the slabs are demolished for each floor from the second basement floor downward, the first strut is installed below the demolished location, and the first strut is installed on the upper side of the first strut. It is characterized in that it includes a basement-level strut installation step (S500) in which the process of installing two struts is sequentially repeated for each floor from the second basement floor downward,
In the bottom-up disassembly step (S3000),
Foundation demolition and primary covering to perform primary covering, which involves demolishing the foundation structure and retaining wall at the lowest underground level, dismantling the first strut installed at the lowest underground level, and then backfilling with soil above the height where the first strut was removed. Covering stage (S600); and
After carrying out the first covering process, the retaining wall is demolished while dismantling the struts from the lower part of the basement to the upper side, and the second covering process of performing soil backfilling at the corresponding location is repeatedly performed for each floor. Strut dismantling and 2 A top-down and bottom-up parallel dismantling method of an existing building, comprising a sub-soil step (S700).
According to clause 1,
A top-down and bottom-up parallel dismantling method of an existing building, characterized in that there is no need to drill and install an H beam to the foundation structure by removing the slab and retaining wall by performing the top-down and bottom-up dismantling in parallel.
According to clause 1,
A top-down and bottom-up parallel dismantling method of an existing building, characterized in that it prevents sagging when demolishing the lower part of a retaining wall by performing the top-down and bottom-up dismantling in parallel.