KR102068129B1 - Demolition method of basement of building using underground structure as support - Google Patents

Abstract

The present invention relates to a demolition method for a basement of a building using an underground structure as a support and, more specifically, to a demolition method for a basement of a building in a downtown area, capable of demolishing a basement of a building by using an underground structure as a support without using an additional device or an additional structure by using the underground structure of the building to be demolished in a downtown area as a structure supporting earth pressure. According to the present invention, the demolition method for a basement of a building using an underground structure as a support can reduce demolition costs and demolition periods by supporting the earth pressure using a part of the basement to be demolished without using the additional structure or the additional device when demolishing the basement unlike a conventional art. The demolition method for a basement of a building using an underground structure as a support can prevent earth and soil in a periphery or underground water from flowing into the basement when demolishing an outer wall of the basement by demolishing the basement after constructing grouting for demolishing a basement on the outside of the outer wall of the basement. Moreover, the demolition method for a basement of a building using an underground structure as a support can require low costs using a kind of fly ash generated in a thermoelectric power plant.

Description

Demolition method of basement of building using underground structure as support

The present invention relates to a building basement demolition method using an underground structure as a support, and more particularly, by using the underground structure of a building to be demolished as a structure supporting earth pressure, the underground structure without using a separate device or structure. It is related to the underground floor demolition method of urban buildings that can be used to directly remove the basement of the building.

Domestic buildings that are to be demolished for over 30 years are buildings with a considerable floor area, and even if they have a basement floor, most of them are about three floors or less and the depth is about 7 to 20m.

In order to construct a new building on such an existing building site, it is necessary to demolish the existing building. The removal of the ground part of the existing building is relatively difficult, but the underground part is not easy to be removed due to the surrounding earth pressure. In particular, in the case of demolishing the underground part in the downtown area, it is necessary to perform the demolition work so that sinking of the next building or sink hole does not occur in the adjacent road.

To this end, as a method for dismantling the basement of an existing building, a separate soil barrier is first installed and the steel is used to support the soil barrier, and then a method of demolishing an existing building while descending from the top to the lower floor is generally applied.

For example, during the demolition of a building with a basement floor, even if most of the floor slabs including the internal columns of the basement floor are demolished, the base retaining wall, which is the outer wall of the building under pressure, cannot be demolished. In some cases, the entire underground interior space can be quickly refilled with external soils with retaining walls intact.

In this case, when the underground process wall construction of a new building underground trench construction overlaps with the remaining underground retaining wall line of the existing building which was to be demolished, a problem occurs in the file drilling work for the construction of the earthquake. In order to solve this problem, in the past, the earthquake construction and the excavation for the purpose of removing the underground retaining wall were inevitably removed, and the remaining underground retaining wall was removed, and then the second backfill was carried out again. I am making a bare land without any obstacles. After that, there is a problem in that the foundation work must be restarted in line with the underground retaining wall of the building to be constructed for the bare land without any obstacles in the ground.

Various techniques have been proposed and used to solve this problem.

As an example, Patent No. 10-736241 discloses a method of removing a basement layer by installing a raker pile and a raker as a temporary structure for supporting earth pressure.

This method removes the central part of the inner structure of the underground retaining wall without causing the underground retaining wall to collapse, and installs the raker pile in the ground at the dismantled central part, and removes the rest of the internal structure of the underground retaining wall which is not demolished from the top down. After installing a raker connecting the basement retaining wall and the raker pile, the raker is removed from the bottom up, the basement wall is removed and backfilled. Finally, the raker pile is removed.

This method has a structure in which the raker slopes the earth pressure received by the basement wall while the raker piles vertically support it. This method is advantageous in that a short length raker can be used. However, this method requires a special drilling equipment because the drilling work must be performed to fix the raker pile on the ground, and there is a problem that the drilling noise is generated and the ground can be disturbed.

As another example, Patent No. 10-1140327 discloses a method for dismantling an underground structure using a part of the underground structure as a earth pressure support.

This method relates to the technology to use as a temporary structure for supporting earth pressure to stably support the earth pressure acting on the underground retaining wall during the demolition process by maintaining part of the underground structure without dismantling even in the process of backfilling. In this method, even if the underground structure is multi-layered, all the underground layers are removed with the same span, and if the existing structure cannot support the earth pressure stably, the temporary earth pressure support is additionally installed to support the earth pressure.

However, when this method requires two or more spans to be supported to support the earth pressure, slabs are present in a plurality of floors, which makes it difficult to remove the bottom surface and the retaining wall of the basement layer at the bottom. . On the other hand, in the case of installing an additional temporary earth pressure support leaving only one span, there is a problem in that work time and cost increase in that it is necessary to manufacture and install a separate temporary earth pressure support.

The present invention was devised in view of the above problems, and an object of the present invention is to provide a method for demolishing a basement floor of a building that can support earth pressure by using a basement of an existing building as a support without using an additional structure.

In addition, an object of the present invention is to provide a method for demolishing the basement of the building that can prevent the groundwater outflow and ground subsidence occurs during the removal of the basement.

The present invention to achieve the above object,

In the basement demolition method of a building having 3 to 5 basement floors,

A first step of constructing a ground floor demolition grouting on the outer circumference of the outer wall of the basement floor of the building;

To prevent the outer wall of the basement layer from collapsing by earth pressure, the inner portion of the basement layer and the slab between the basement layer and the slab between them are to be removed, but the depth of the inner layer and the slab increases as the basement layer deepens. A second step of removing ~ 5 basement layers;

Cut the outer wall except the bottom of the basement floor and the outer wall pillar, and cut the outer portion of the base portion of the lower portion of the outer wall pillar and the outer portion of the base portion of the inner pillar A third step of dismantling and refilling the earth and sand on the basement floor;

A fourth step of removing the slab between the inner pillar of the basement lower layer and the inner pillar of the basement lower layer and the inner pillar of the basement lower layer that are not connected to the inner pillar of the basement lower layer;

The basement of the basement vehicle layer, which is connected to the inner column of the basement floor of the basement floor, is left, and the slab that forms the bottom surface of the basement vehicle layer is cut and removed by cutting the outer layer of the basement vehicle layer except for the outer wall column of the basement vehicle layer. A fifth step of filling the earth and sand to the second floor;

Slabs forming the bottom surface of the underground car upper layer and inner columns of the underground car upper layer not connected to the inner columns of the underground car upper layer, leaving the inner pillars of the underground car upper layer connected to the inner columns of the underground car upper layer. A sixth step of removing and dismantling the outer wall of the lower car layer except for the outer wall pillars of the upper car layer and removing the soil from the upper car layer;

A seventh step of proceeding to the sixth step until the bottom slab of the first floor above the ground remains to the first floor below the ground;

An eighth step of dismantling the ground first floor slab; And

And a ninth step of drawing and removing the outer wall pillar of the first basement floor and the inner pillar of the first basement layer adjacent to the outer wall pillar.
Underground structure, characterized in that for removing the inner pillar of the basement car layer that is not connected to the inner column of the underground car layer is exposed to the earth and sand backfilled to the underground car layer in the sixth step as a support Provide a basement demolition method for the used building.

In one embodiment of the present invention, in the case where a mudguard is constructed on the outer side of the outer wall of the basement of the building, the grouting for the basement demolition is constructed on the outer side of the mud, and when the outer wall of the basement is cut and dismantled. , The earth can also be removed by cutting.

In addition, in one embodiment of the present invention, in the process of dismantling the inner pillar of the basement 2 floors or less that are not connected to the inner pillar of the basement 1 floor, the inner pillar of the basement 2 floors or less can be removed and removed. have.

In addition, in one embodiment of the present invention, the ground layer demolition grouting may be formed of a grouting material mixed with the SEM ash and micro cement.

In this case, the SEM ash is a fly ash produced in a supercritical fluidized bed boiler using pulverized coal, SiO ₂ , CaSO ₄ , f-CaO, Fe ₂ O ₃ , CaCO ₃ , unburned carbon, f-CaO is 3-10wt%, CaSO ₄ may be 10 ~ 20wt%, unburned carbon may be 1.0wt% or less.

According to the basement demolition method of the building using the underground structure as a support according to an embodiment of the present invention as described above, a part of the basement to be removed without using a separate structure or device when dismantling the basement, unlike the prior art By supporting the earth pressure using the can reduce the demolition period and there is an advantage that can reduce the demolition cost.

In addition, according to the basement demolition method of a building using the underground structure as a support according to an embodiment of the present invention, since the basement is demolished after the underground floor demolition grouting on the outside of the outer wall of the basement, when the basement outer wall is dismantled There is an advantage that can prevent the sediment or groundwater of the inflow into the basement.

In addition, the ground floor demolition grouting used in the underground floor demolition method of the building using the underground structure as a support according to an embodiment of the present invention has an advantage of low cost because it uses a kind of fly ash generated from a thermal power plant.

Figure 1a is a plan view showing the basement floor of the existing building remaining after the ground portion is removed in the basement demolition method of the building using the underground structure as a support according to an embodiment of the present invention, Figure 1b is a line I- of FIG. Section cut along I;
2A and 2B are a plan view and a cross-sectional view showing a state in which the underground floor demolition grouting is constructed around the basement floor of an existing building in the underground floor demolition method of a building using the underground structure as a support according to an embodiment of the present invention;
3A and 3B are a plan view and a cross-sectional view showing a state in which a basement of a basement of a building is demolished to a basement 3 floor in a method of dismantling a basement of a building using an underground structure as a support according to an embodiment of the present invention;
4A and 4B are plan views illustrating a state in which the basement and the outer walls of the basement 3 floors of the basement floor of the existing building are demolished in the basement demolition method of the building using the underground structure as a support according to an embodiment of the present invention; Cross-section;
4C is a line II-II of FIG. 4B to show a state in which the outer wall of the basement 3 floor to be removed is removed by cutting in the basement demolition method of the building using the underground structure as a support according to an embodiment of the present invention. Section cut along;
5A and 5B are a plan view and a cross-sectional view showing a state in which earth and sand refill of the basement 3 floors of the basement floor of an existing building is performed in a method of dismantling the basement of a building using an underground structure as a support according to an embodiment of the present invention;
6a and 6b is a basement floor demolition method of a building using an underground structure as a support according to an embodiment of the present invention, the inner column of the basement three floors not connected to the inner column of the basement two floors of the basement floor of the existing building And a plan view and a cross-sectional view showing a state in which the slab between them is removed and the soil refilling is completed;
7a and 7b is a state in which the basement floor demolition method of the building using the underground structure as a support according to an embodiment of the present invention, the bottom and outer walls of the basement 2 floor of the basement floor of the existing building is removed and the soil refilling Plan and cross-sectional view showing;
8A and 8B illustrate a method of dismantling the basement floor of a building using an underground structure as a support according to an embodiment of the present invention. A plan view and a cross-sectional view showing a state in which the internal pillars of the basement 2 floor which are not connected to the pillars are removed;
9A and 9B are a plan view and a cross-sectional view showing a state in which the soil refilling is completed in the basement 1 floor of the basement floor of an existing building in the method of dismantling the basement of a building using an underground structure as a support according to an embodiment of the present invention;
10A and 10B are a plan view and a cross-sectional view showing a state in which the outer wall pillars and inner pillars of a basement floor of an existing building are removed by removing them in a method of dismantling a basement of a building using an underground structure as a support according to an embodiment of the present invention; to be.

Hereinafter, with reference to the accompanying drawings will be described in detail the embodiments of the basement demolition method of a building using the underground structure according to the present invention as a support.

Embodiments described below are shown by way of example in order to help understanding of the present invention, it should be understood that the present invention may be modified in various ways different from the embodiments described herein. However, in the following description of the present invention, if it is determined that the detailed description of the related known functions or components may unnecessarily obscure the subject matter of the present invention, the detailed description and specific illustration thereof will be omitted. In addition, the accompanying drawings may be exaggerated in some dimensions of the components rather than being drawn to scale to facilitate understanding of the invention.

In the following description and drawings will be described mainly with respect to the three-story underground structure, but this is only for convenience of description, the scope of the present invention is not limited to the dismantling, dismantling of the three-story underground structure, preferably 3-5 It can be used for the demolition of underground structures with a floor scale (approximately 7-20m in height below ground level).

When the ground portion of the existing building to be demolished is removed, only the basement layer 100 or the underground structure remains as shown in FIGS. 1A and 1B. At this time, the outer wall 40 of the basement floor 100 and the bottom surface 1 of the ground floor 1, that is, the ceiling 1 of the basement 1 floor are maintained as they are. The basement floor 100 includes a basement 1 floor 10, a basement 2 floor 20, and a basement 3 floor 30. In FIG. 1A and FIG. 1B, reference numeral 200 denotes existing ground around the basement layer 100.

The basement demolition method of a building using an underground structure as a support according to an embodiment of the present invention consists of the following eight processes (hereinafter, abbreviated as 'building basement demolition method' for convenience of description).

(1) Process of constructing grouting for the demolition of basement floors

As shown in Figure 2a and 2b, the underground floor demolition grouting 50 is constructed on the outer side of the outer wall 40 of the basement floor 100 of the building to be demolished. At this time, when the mudstone 110 is installed on the outside of the outer wall 40 of the basement floor 100 of the building as in the present embodiment, the basement demolition grouting 50 is constructed outside the mudguard 110. However, as another example, although not shown, when there is no crust on the outer wall 40 of the basement floor 100 of the building, the basement demolition grouting 50 is directly at the outer wall 40 of the basement floor 100 of the building. Construct on the outside.

The basement demolition grouting 50 may be constructed by injecting a grouting material for the basement demolition into the basement after a plurality of perforations at regular intervals along the basement outer wall 40. The grouting layer 50 for the demolition of the basement layer is formed deeper than the bottom surface 33 of the basement layer 100.

The grouting 50 for the basement demolition may prevent the earth and sand from flowing into the basement 100 when the outer wall 40 of the basement 100 is demolished.

The grouting layer 50 for dismantling the basement layer may be formed using a grouting material in which SEM ash and micro cement are mixed.

SEM ash is a fly ash produced in a supercritical fluidized bed boiler using pulverized coal and includes SiO ₂ , CaSO ₄ , f-CaO, Fe ₂ O ₃ , CaCO ₃ , unburned carbon, etc. Is 3-10wt%, CaSO ₄ is 10 ~ 20wt%, unburned carbon contains less than 1.0wt%. Such an SEM ash can be obtained from Samcheok Power Plant of Southern Power as an example.

SEM ash has a higher degree of powder than conventional fly ash. That is, the conventional fly ash has a powder degree of 2,500 to 3,500 cm 2 / g, while the SEM ash has a powder degree of 7,500 to 9,000 cm 2 / g. Thus, the SEM ash may be composed of particles of 5 μm or less. In addition, the SEM ash contains Fe ₂ O ₃ , exhibits yellowish brown color, and has a small color variation. In addition, the SEM ash is environmentally stable because it meets the first-grade soil pollution standards.

Therefore, the grout 50 for the basement demolition including the SEM ash does not contaminate the underground soil and thus may remain in the ground even after the basement demolition is completed. In addition, the grouting 50 for the basement demolition has a property that can be easily destroyed when performing a perforation, etc. to construct a new building.

(2) Process of removing center part of basement floor

In order to prevent the outer wall 40 of the basement layer 100 from collapsing due to earth pressure, the center portion of the basement layer 100 is demolished while leaving the inner pillars close to the outer wall 40 of the basement layer 100 and slabs and beams therebetween. At this time, as the basement layer deepens, the center portions of the three basement layers are demolished so that the number of remaining columns, slabs, and beams increases.

Specifically, as shown in FIGS. 3A and 3B, the ceiling 1 of the first basement 10, that is, the bottom surface 1 of the first floor above the ground, is the interior closest to the outer wall 40 of the basement 100. The bottom 11 of the remaining area is dismantled, leaving only a part from the pillar 11, ie, the inner pillar 11 spaced one span from the outer wall 40 of the basement floor.

Subsequently, only the inner pillar 11-1 spaced apart from the outer wall 40 of the basement floor by one span from the inner pillar 11 of the basement first floor 10, and all the inner pillars 11 of the remaining area are removed. When the bottom surface 13 of the first basement 10, that is, the ceiling of the second basement 20, the slab (integral beams) from the outer wall 40 of the basement to the inner column 21-2 spaced two spans apart. 2) and the slab 23 of the remaining area is removed. Although not shown, as another example, when the beam is formed separately from the slab, the sidewalk is removed together.

Next, the inner column 21 of the second basement 20 is also removed from the outer wall 40 of the basement floor by only two inner spans 21-2 spaced apart from the outer wall 40. That is, the inner column 21-1 spaced apart from the outer wall 40 of the basement floor and the inner column 21-2 spaced apart from the 2 span are left, and all the remaining inner columns 21 of the basement 2 floor 20 are demolished. do. Then, the inner column 21-1 near the outer wall 40 of the basement 2 floor 20 is connected to the inner column 11-1 of the basement 1 floor 10 at the top and is located near the center part. 21-2 is a state in which the inner column 11 of the first basement 10 is not present in the upper portion.

The bottom surface 23 of the basement 2 floor 20, that is, the ceiling of the basement 3 floor 30, leaves the slab 23 from the outer wall 40 of the basement floor to the inner column 31-3 spaced apart 3 spans. The slab 23 of the area is removed. Subsequently, the inner pillar 31 of the third basement 30 is also removed from the outer wall 40 of the basement floor only by three spans of the inner pillar 31-3, and all the inner pillars 31 of the remaining area are removed. That is, the inner column 31-1 spaced one span from the outer wall 40 of the basement layer, the inner column 31-2 spaced two spans, and the inner column 31-3 spaced three spans, leaving the remaining inner column. All 31 are to be demolished. Then, as shown in FIG. 3B, the inner pillars 11, 21, 31 and the slabs 13, 23, and 33 of the three basement layers 10, 20, and 30 remain in a staircase shape. Therefore, the inner pillar 31-1 near the outer wall 40 of the third underground floor 30 and the inner pillar 31-2 adjacent thereto are upper inner pillars 21-1, 21 of the second underground floor 20. -2) is connected to the inner pillar 31-3 is located near the central portion is a state that the inner pillar 21 of the basement 2 floor 20 does not exist at the top.

As such, when the center portion of the basement layer 100 is demolished to increase the number and area of the internal pillars, slabs, and beams remaining as the basement layer 100 descends, the remaining basement layer portion may support a larger earth pressure as it goes down. It becomes possible. Therefore, by increasing the number and area of the inner pillars, slabs and beams left as the basement down as in the present invention, it is possible to appropriately support the earth pressure increasing with depth without installing additional structures.

In the above, only the inner pillar 11-1 spaced one span apart from the outer wall in the first basement 10, and the inner pillar 21 increased by one span in each of the second and second basement layers 20 and 30. -2,31-3), but this is only an example, and the position of the inner pillar may be changed depending on the magnitude of the earth pressure. As another example, when the earth pressure is large, the first basement may be located up to two inner spaces spaced apart from the outer wall, and the second basement and three basement floors may have up to one inner span increased by one span.

(3) The process of removing the bottom and outer walls of the 3rd basement level and refilling the soil.

As shown in FIGS. 4A and 4B, after dismantling the bottom surface 33 of the third basement 30, the outer wall portion 42 is removed between the outer wall pillars 41 of the third basement 30. Dismantle). At this time, the base part of the lower part of the column, more specifically, the outer part of the base part larger than the outer diameter of the column is cut for future drawing. In addition, although the drawing is shown as cutting the outer portion of the outer portion of the base portion of the base portion, it is not necessary to do this, it is also possible to cut the portion connecting the base and the pillar. The outer wall 40 of the basement 3 floor 30 cuts and removes the outer wall portion 42 between the plurality of outer pillars 41 with cutting equipment such as a wheel saw cutting machine. When there is an earthquake 110 on the outer side of the outer wall 40 of the basement floor 100, the earthquake 110 is also removed by cutting a portion corresponding to the basement 3 floor with cutting equipment. Then, as illustrated in FIG. 4C, the grouting layer 50 for removing the underground floor is exposed between the outer wall pillars 41. The dashed-dotted line 44 in FIG. 4C represents a cutting line cut by a cutting machine. The grouting layer 50 for dismantling the ground layer provided on the outer side of the soil barrier 110 may temporarily block the inflow of the earth and ground water through the cut outer wall portion 42.

As another example, when there is no earth barrier 110 on the outside of the basement layer 100, when the outer wall 40 of the basement layer 100 is cut, the basement demolition grouting 50 is exposed between the outer wall pillars 41.

When the outer wall 42 and the soil barrier 110 of the basement 3 floor 30 is removed, the soil wall is backfilled to the portion where the outer wall 42 and the soil barrier are removed to support the earth pressure. The outer wall is sequentially removed and the soil backfill is repeated until the outer wall 42 of the entire circumference of the basement 3 floor 30 is removed. At this time, the earth and sand backfill proceeds to the innermost pillar 31-3, that is, the innermost pillar 31-3 located closest to the center of the basement 3 floor 30.

5A and 5B show a state in which the bottom surface 33 and the outer wall 42 of the basement 3 floor 30 are cut and the backfill of the earth and sand 210 is completed in the basement 3 floor.

(4) Process of removing some internal pillars and slabs on the 3rd basement level

As shown in FIG. 5B, when the soil refilling of the basement 3 floor 30 is completed, the internal pillar 31 of the basement 3 floor 30 that is not connected to the internal column 21 of the basement 2 floor 20, namely, The inner pillar 31-3 located at the innermost side is removed near the center of the remaining inner pillars of the basement 3 floor 30. In addition, a part of the slab 23 that forms the ceiling of the basement 3 floor 30, that is, the inner pillar 21-2 of the basement 2 floor 20 located near the center and the basement 3 floor 30 located near the center. Remove the slab 23 between the inner pillars 31-3 of the.

After removing the internal pillars 31-3 of the basement 3 floor 30 and the slab 23 supported by the base 3 located near the center part, the earth and sand 210 is filled in the center part to backfill the soil 3 of the basement 3 floor 30. To complete. The state of earth and sand refilling of the basement 3 floor 30 is shown in FIGS. 6A and 6B.

(5) The process of removing the bottom and outer walls of the second basement and refilling the soil.

In the state shown in FIG. 6B, after removing the slab 23 forming the bottom surface of the basement 2 floor 20, that is, the ceiling of the basement 3 floor 30, the outer wall pillar 41 of the basement 2 floor 20. The outer wall portion 42 of the basement 2 floor 20 except for) is removed. At this time, the internal pillars 21-1 and 21-2 of the basement 2 floor 20 are not demolished. The outer wall 40 of the second basement 20 is partially cut between the plurality of outer wall pillars 41 by cutting equipment such as a wheel saw cutting machine. If there is an earthquake 110 on the outer side of the outer wall 40 of the basement floor 100, the portion of the earthquake 110 corresponding to the second basement floor is also cut and removed by cutting equipment. Then, the grouting 50 for the basement demolition is exposed between the outer wall pillars 41. The ground floor demolition grouting 110 provided on the outer side of the soil barrier 110 may temporarily block the earth and ground water from flowing through the cut outer wall.

In another example, when there is no earth barrier outside the basement layer 100, when the outer wall 40 of the basement layer 100 is cut, the basement demolition grouting 50 is exposed between the outer wall pillars 41.

When the outer wall 40 and the soil barrier 110 of the basement 2 floor 20 is removed, the earth and sand backfilled on the cut portion of the outer wall portion 42 may support the earth pressure. The outer wall is sequentially removed and the soil backfill is repeated until the outer wall 40 of the front circumference of the second basement 20 is removed. At this time, the soil backfill proceeds to the inner pillar 21-2 located at the innermost side of the second basement 20.

7A and 7B show a state in which the bottom surface 23 and the outer wall 40 of the basement 2 floor 20 are cut and the soil refilling is completed.

(6) The process of removing the bottom and outer walls of the first basement and refilling the soil.

The slab 13 which forms the floor of the basement 1 floor 10, ie, the ceiling of the basement 2 floor 20, is demolished. At this time, as shown in FIG. 7B, the inner pillars 21-2 located at the innermost side of the second underground floor 20 buried in the earth and sand are also removed. Since the inner pillar 21-2 of the basement 2 floor 20 is connected to the inner pillar 31-2 of the basement 3 floor 30, when the inner pillar 21-2 of the basement 2 floor 20 is drawn out, The remaining internal pillars 31-2 of the basement 3 floor 30 may also be removed by pulling out. For example, the inner pillar 21-2 of the basement 2 floor 20 may be drawn out using a crane. At this time, the internal pillars 11-1 of the first underground floor 10 connected to the internal pillars 21-1 of the second underground floor 20 are left without demolition. 8A and 8B illustrate a state in which the bottom surface of the first basement 10 and the inner pillars 21-2 of the second basement 20 are removed.

After dismantling the bottom surface 13 of the first basement 10 and the inner columns 21-2 of the second basement 20, the first basement except for the outer wall pillar 41 of the first basement 10 was opened ( The outer wall portion 42 of 10 is removed. As described above, the outer wall 40 of the basement first floor 10 is partially cut and removed between the plurality of outer wall pillars 41 by cutting equipment such as a wheel saw cutting machine. If there is an earthquake 110 on the outer side of the outer wall 40 of the basement layer 100, the remaining earthquake 110 is also removed by cutting equipment. Then, the grouting 50 for the basement demolition is exposed between the outer wall pillars 41. The grouting layer 50 for dismantling the ground layer provided on the outer side of the soil barrier 110 may temporarily block the inflow of the earth and ground water through the cut outer wall portion 42.

As another example, when there is no earth barrier 110 on the outside of the basement layer 100, when the outer wall 40 of the basement layer 100 is cut, the basement demolition grouting 50 is exposed between the outer wall pillars 41.

When the outer wall 40 and the soil barrier 110 of the first basement 10 is removed, the soil to be backfilled to the portion where the outer wall 40 is cut so that the soil to be backfilled 210 can support the earth pressure. The outer wall is sequentially removed and the soil backfill is repeated until the outer wall 40 of the front circumference of the first basement 10 is removed. Thereafter, the soil refilling process proceeds to the center portion of the first underground floor 10 so that the upper surface of the earth and sand 210 filled in the first underground floor 10 is the same as the ground surface.

(7) Process of removing the bottom surface of the ground floor

After the soil refilling of the first basement 10 is completed, the slab 1 forming the ceiling of the first floor of the first floor 10, that is, the ceiling of the first basement 10, is removed. Then, as illustrated in FIGS. 9A and 9B, only the plurality of outer wall pillars 41 and the plurality of inner pillars 11 ′ adjacent to the outer wall pillars 41 remain in the soil. That is, the inner pillar 11 ′ is an inner pillar 11-1 of the first underground floor 10, the inner pillar 21-1 of the second underground floor 20, and an interior of the third underground floor 30. The pillar 31-1 is connected.

(8) process of drawing and removing outer wall columns and inner columns

Since the remaining plurality of outer wall pillars 41 and the plurality of inner pillars 11 'are connected from the first basement 10 to the third basement 30 below, the plurality of outer wall pillars 41 and the plurality of inner columns The pillar 11 'can be removed by drawing. As a device for drawing the outer wall pillar 41 and the inner pillar 11 ', a crane can be used.

In the case of drawing the outer wall pillar 41 and the inner pillar 11 ', the upper end of the outer wall pillar 41 and the inner pillar 11' so that the outer wall pillar 41 and the inner pillar 11 'is not cut during drawing. Can be drawn by installing a fixture to hang the wires of the crane in the appropriate position.

A fastener for fixing the wire is not necessarily required, and in some cases, it is also possible to directly draw a wire insertion hole in a pillar without the fastener.

In addition, when the lowermost tofu is not suitable for drawing, it is preferable to proceed with drawing after arranging the periphery of the head using cutting equipment.

As such, when the plurality of outer wall pillars 41 and the plurality of inner pillars 11 'are drawn out and removed, all the structures constituting the basement floor 100 of the existing building are removed from the earth and sand. Therefore, it becomes a bare land state without any obstacle in the ground within the land boundary.

The state in which the plurality of outer wall pillars 41 and the plurality of inner pillars 11 'are removed is shown in FIGS. 10A and 10B. At this time, the ground floor demolition grouting 50 is left around the basement floor 100 of the existing building. However, the grouting 50 for the basement demolition is composed of a component that does not contaminate the soil, it is easily destroyed when the ground work for the construction of new buildings in the future does not interfere with the construction.

As described above, according to the method of dismantling the underground floor of a downtown building according to an embodiment of the present invention, the earth pressure of the surroundings can be supported by using the structure of the basement of the existing building. There is no need. Therefore, the construction period can be shortened, there is an advantage that can reduce the construction cost.

In the above, the basement floor of an existing building has been described as an example of the basement 3 floor, but the underground floor demolition method of the urban building according to the present invention can be applied even when the basement floor is 3 to 5 floors (about 10 to 20m in height). Of course.

In addition, if there are structurally weak parts, it is natural that the demolition method can be applied after reinforcement using a separate temporary facility.

The present disclosure has been described above by way of example. The terminology used herein is for the purpose of description and should not be regarded as limiting. Many modifications and variations of the present disclosure are possible in light of the above teachings. Accordingly, unless otherwise indicated, the present disclosure may be embodied freely within the scope of the claims.

One; Bottom 10 of the ground floor; B1
11; Internal column 13 on the first basement floor; Slab of the first basement
20; Second basement 21; Internal columns on the second basement
23; Slab 30 of second basement; 3 underground levels
31; Internal columns 33 of the third basement level; Slab of 3rd Basement Floor
40; Outer wall 41; Curtain wall
42; Outer wall portion 50; Grouting for Basement Demolition
100; Basement floor 110; Crust
200; Ground 210; Tosa

Claims (5)

In the basement demolition method of a building having five basements,
A first step of constructing a ground floor demolition grouting on the outer circumference of the outer wall of the basement floor of the building;
To prevent the outer wall of the basement layer from collapsing by earth pressure, the inner portion of the basement layer and the slab between the basement layer and the slab therebetween are removed, and the center portion of the basement layer is demolished. A second step of removing the two basement layers;
Cutting the outer wall except the bottom of the basement floor and the outer wall column, cutting and removing the outer part of the base part of the lower part of the outer wall column and the outer part of the base part of the inner column, and refilling the earth and sand to the basement floor. Step 3;
A fourth step of removing the slab between the inner pillar of the basement lower layer and the inner pillar of the basement lower layer and the inner pillar of the basement lower layer that are not connected to the inner pillar of the basement lower layer;
The basement of the basement vehicle layer, which is connected to the inner column of the basement floor of the basement floor, is left, and the slab that forms the bottom surface of the basement vehicle layer is cut and removed by cutting the outer layer of the basement vehicle layer except for the outer wall column of the basement vehicle layer. A fifth step of filling the earth and sand to the second floor;
Demolish the slab that forms the bottom surface of the underground car upper layer and the inner column of the underground car lower layer that is not connected to the inner column of the underground car upper layer, leaving the inner column of the underground car upper layer connected to the inner column of the underground car upper layer. Then, a sixth step of cutting and removing the outer chacha upper layer outer wall except for the outer wall pillar of the underground chacha upper floor, and filling the earth and sand to the underground chacha upper layer;
A seventh step of proceeding with the sixth step until the bottom slab of the first floor above the ground remains up to the first floor underground;
An eighth step of dismantling the ground first floor slab; And
And a ninth step of drawing and removing the outer wall pillar of the first basement floor and the inner pillar of the first basement layer adjacent to the outer wall pillar.
The second step,
The first basement floor is to remove the remaining inner pillar and the bottom surface leaving only the bottom surface and the inner column spaced one span from the outer wall to the inner space spaced one span, and the second basement floor two span from the outer wall Demolishing the remaining inner pillar and the bottom surface, leaving only the bottom surface to the spaced inner pillar and the two span spaced inner pillar, and the third basement floor being the bottom surface to the inner pillar spaced three spans from the outer wall. Demolishing the remaining inner pillars and the bottom surface leaving only three span-spaced inner columns, and the basement fourth floor leaving only the bottom surface from the outer wall to the four-span spaced inner pillars and the four-span spaced inner pillars. Dismantling the column and the bottom surface, and the basement fifth floor is a bottom surface and the five spans up to an inner column spaced five spans from the outer wall. Demolishing the remaining interior columns and floors, leaving only the interior columns spaced apart,
In the sixth step, the inner column of the underground car layer not connected to the inner column of the underground car upper layer exposed to the earth and sand exposed to the underground car layer is drawn out and removed.
When a mudguard is constructed on the outer side of the outer wall of the basement floor of the building, the grouting for the basement demolition is constructed on the outer side of the mudguard,
When the outer wall of the basement layer is cut and dismantled, the trowel is also cut and dismantled,
The basement demolition grouting is formed of a grouting material mixed with SEM ash and micro cement,
The SEM ash is a fly ash produced in a supercritical pressure fluidized bed boiler using pulverized coal, the powder degree is 7,500 ~ 9,000 cm 2 / g,
SiO ₂ , CaSO ₄ , f-CaO, Fe ₂ O ₃ , CaCO ₃ , unburned carbon,
f-CaO is 3-10wt%, CaSO ₄ is 10-20wt%, unburned carbon is 1.0wt% or less,
The grouting for the basement demolition is a basement demolition method of a building using an underground structure as a support, characterized in that the remaining after the demolition of the basement is completed. delete delete delete delete

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