KR101856768B1 - Method for breakup structure - Google Patents

Abstract

An embodiment of the present invention is a process for removing an inner member in which an inner member of a structure in a demolished layer is carried to the outside of a demolished layer; An outer member cutting and removing process in which the outer member of the structure in the removed layer taken out of the inner member is cut into a plurality of cutting members and the cut members are taken out to the outside of the removed layer; And a column reinforcing process in which the columns in the demolished layer where the inner member and the outer member are carried and left are supported by the reinforcing members; The process of removing the inner member, the process of cutting and removing the outer member, and the process of reinforcing the column are repeated for each layer as one disassembly cycle, so that the structure can be disassembled.

Description

Method for breakup structure [

The present invention relates to a structure dismantling method, and more particularly, to a structure dismantling method that allows existing buildings to be used as they are after remodeling.

Generally, various concrete structures used for construction and civil engineering often have to be demolished due to problems such as a short service life, safety problems, or reconstruction and design changes.

Conventional scaffolding and dismantling technology is a technical part that dismantles all or part of a structure. There are a whole demolition method to remove the entire structure and some demolition method to demolish a part.

The whole demolition method includes blasting method, crushing method and so on. Some of the demolition methods include cutting of structures using diamond wire saw, water det, partner, rod cutter, etc., which can be partially demolished, and other structures such as hand breakers and giant breakers. Or a part thereof is crushed and demolished.

In this way, the existing dismantling method is a concept in which a whole structure is dismantled and completely removed, and a new structure is newly constructed or a part of the structure is demolished to remodel a part of the existing structure.

However, there may be cases where restrictions are imposed on strengthened regulations due to the permission issue of the relevant competent authority or the passage of time, and there is a restriction on the expansion or the expansion of the structure after demolition.

For example, in terms of cost, even if it is planned to be built after the whole demolition, the floor space ratio of the newly built apartment is only 200% compared to the hotel floor space ratio of 500%, or the high limit regulation There is a problem in that it can not be ensured only in a lower layer at the time of stretching after the whole demolition. Also, when remodeling is done by the existing demolition method, existing hotel floors and planned apartment floors can be different from each other.

Therefore, there is a need for a new type of demolition method that is not affected by altitude limitation while maintaining the existing volume ratio.

Korean Patent No. 10-0618604

SUMMARY OF THE INVENTION The present invention provides a method of dismantling a structure that allows an existing building to be used as it is after remodeling.

An embodiment of the present invention is a process for removing an inner member in which an inner member of a structure in a demolished layer is carried to the outside of a demolished layer; An outer member cutting and removing process in which the outer member of the structure in the removed layer taken out of the inner member is cut into a plurality of cutting members and the cut members are taken out to the outside of the removed layer; And a column reinforcing process in which the columns in the demolished layer where the inner member and the outer member are carried and left are supported by the reinforcing members; The process of removing the inner member, the process of cutting and removing the outer member, and the process of reinforcing the column are repeated for each layer as one disassembly cycle, so that the structure can be disassembled.

The dismantling work cycle is repeated from top to bottom in the order of top-down, so that the structure can be disassembled.

Cutting the slab member forming the ceiling of the demolished layer into a plurality of slab cutting members and carrying it out; And cutting the outer wall beams constituting the wall of the demolished layer with a plurality of outer wall beam cutting members and carrying them out.

The slab cutting member and the outer wall beam cutting member are cut in the same shape as the lattice structure of the cutting line so that the shape of the slab cutting member and the shape of the outer wall beam cutting member are the same .

The stiffener may be an H-beam reinforcement connecting the adjacent columns to each other.

The columns in the demolition layer are supported by the stiffener by supporting the stiffener horizontally and connecting one end to the first column and connecting the other end of the stiffener to the second column adjacent to the first column, A second support having a horizontal support structure for supporting the second column as a horizontally disposed reinforcement member, or an end of the reinforcement member is inclined so that one end thereof is coupled to the first column and the other end of the reinforcement member is coupled to the second column adjacent to the first column And a slant support structure for supporting the first and second columns together as a stiffener positioned at an inclined position.

The columns in the demolition layer are supported by the stiffener. The stiffener having the horizontal support structure and the sloped support structure may be alternately arranged alternately between the columns and the columns.

The columns in the demolition layer are mutually supported by the reinforcing member when a column reinforcing operation is performed between the first column and the second column in the upper demolishing layer, the lower end of the first column and one end of the upper demolished- And the upper end of the second column and the other end of the upper reinforcing layer reinforcement are combined as the upper reinforcing layer second pillar combined body and supported in an inclined manner after the upper end of the second pillar, which is higher than the lower end of the first pillar, , One end of the lower reinforcing layer reinforcing material is joined to the upper reinforcing layer first column connecting body when a column reinforcing operation is performed between the first and second columns in the lower reinforcing layer immediately below the upper reinforcing layer, And the lower end of the second column and the other end of the lower reinforcing steel layer reinforcement are combined as a lower reinforcing layer second pillar combined body and supported in an inclined manner.

According to the embodiment of the present invention, the operation of reinforcing a column by using a reinforcing material after cutting and unloading the outer material proceeds in a downward direction in the downward direction, thereby preventing a collapse risk at the time of dismantling the building.

1 is a flowchart illustrating a structure disassembly process according to an embodiment of the present invention.
Figure 2 is an illustration of a multi-layered structure.
FIG. 3 is a view showing a state in which a ceiling is cut and taken out according to an embodiment of the present invention. FIG.
4 is a view showing a state in which an outer wall member is cut and taken out according to an embodiment of the present invention.
FIG. 5 is a diagram illustrating columns that are exposed and left in a layer according to an embodiment of the present invention. FIG.
FIG. 6 is a view showing a state in which a column is supported by a reinforcing member, in which the outer material is taken out and left on the floor according to an embodiment of the present invention.
FIG. 7 is a view showing a state in which pillars of the entire structure are supported by a reinforcing member according to an embodiment of the present invention. FIG.
8 is a view showing a state in which a stiffener is supported horizontally according to an embodiment of the present invention.
9 is a view showing a state in which a stiffener is supported in an inclined manner according to an embodiment of the present invention.
FIG. 10 is a view showing a reinforcing material alternately horizontally and obliquely according to an embodiment of the present invention. FIG.
11 and 12 are views showing a state where two stiffeners are coupled to a column as one assembly according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to achieve them, will be apparent from the following detailed description of embodiments thereof taken in conjunction with the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as being limited to the exemplary embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete and will fully convey the concept of the invention to those skilled in the art. And the present invention is only defined by the scope of the claims. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

FIG. 1 is a flow chart showing a structure disassembly process according to an embodiment of the present invention, FIG. 2 is an illustration of a structure including a plurality of layers, FIG. 3 is a view FIG. 4 is a view illustrating a state in which an outer wall member is cut and taken out according to an embodiment of the present invention. FIG. 5 is a cross-sectional view illustrating an example in which the outer member is taken out and the columns FIG. 6 is a view showing a state in which columns supported by external materials and left on a layer are supported by a reinforcing member according to an embodiment of the present invention. FIG. 7 is a cross- The figure shows the columns being supported by the reinforcement.

The method of dismantling the structure of the present invention is an efficient dismantling method which can maintain the existing volume ratio of the structure but is not affected by the altitude restriction and can accommodate the change of the stratification caused by the difference between the existing use and the new use.

Hereinafter, the four-layer structure will be described as an example, but it will be understood that more or fewer layers may be included.

To this end, the method of disassembling a structure of the present invention may include an inner member removal process (S100), an outer member cutting and removal process (S200), and a column reinforcement process (S300), as shown in FIG.

As used herein, the term " structure " refers to a structure having two or more layers (e.g., two or more layers) as shown in FIG. 2, and the present invention is to disassemble a plurality of layers .

In the present invention, when the structure is dismantled, the lower layer may be disassembled, but it is preferable that the structure is dismounted from top to bottom in a top-down manner. This is a top-down dismantling from the roof of the structure to remove the danger of conduction due to the center of gravity.

In order to disassemble the structure of the present invention, an inner member removal process (S100) is first performed. This inner member removal process (S100) is a process of removing a layer to be removed from the structure shown in FIG. 2 ) Is the process in which the inner ash of the structure in the concrete structure is taken out of the removed layer. Such an interior material may include a finishing material of a structure in a demolished layer to be dismantled, an inner material such as a wall, and the like. Therefore, the inner material in the demolished layer can be taken out to the outside of the demolished layer by a transportation means such as a crane.

When the inner member removal process S100 is completed, the outer member of the structure in the demolished removed layer is cut into a plurality of cutting members, and the cut member is taken out to the outside of the demolished layer. S200). This is due to the weight and size of the outer material, which can not be carried out as a whole, so it is cut off to a size that can be taken out and taken out.

As shown in FIG. 3, the external re-cutting and unloading step S200 includes a step S210 of cutting and discharging the slab member forming the ceiling of the demolished layer to a plurality of slab cutting members 10 and carrying it out. When the slabs forming the ceiling are completely removed, the outer wall beams constituting the walls of the demolition layer are cut and cut out by a plurality of outer wall beam cutting members 20 as shown in FIG. 4 (S220). The cutting can be performed by various cutting means such as a welding machine, a concrete cutting machine, and the like. Also, the unloading can be carried out from the demolished layer to the outside by means of various carrying out means such as a crane.

In cutting the outer member, the slab cutting member 10 in which the slab constituting the ceiling is cut and the outer wall beam cutting member 20 in which the outer wall beam constituting the wall are cut off are cut into the same shape in a lattice structure, It is preferable that the slab cutting member 10 and the outer wall beam cutting member 20 have the same shape. This is to use the carry-out means for carrying out the slab cutting member 10 and the carry-out means for carrying out the outer-wall beam cutting member 20 as one carry-out means. 3, the size and shape of the slab cutting member 10 that cuts the slab forming the ceiling are substantially the same as the size and shape of the outer wall beam cutting member that cuts the outer wall forming the wall as shown in FIG. There is a problem in that the work efficiency is lowered because the lifting hooks of the crane, which is the carry-out means, and the allowable tonnage of the crane are different from each other and must be taken out using separate cranes.

On the other hand, when the external re-cutting and unloading process (S200) is completed, as shown in Fig. 5, only the columns 100 remain in the demolished layer. As a result, only the column 100 is left in the demolished layer, thereby causing a risk of collapse. In order to prevent such a risk, the present invention is characterized in that columns 100 in a demolished layer, in which an inner member and an outer member are carried and left, are supported by a stiffener 200 as shown in Fig. 6 S300). The risk of collapse of the structure can be prevented by supporting the column 100 between the column 100 and the column 100 by acting as a temporary support. The stiffener 200 may be embodied as an H-beam stiffener 200 connecting the adjacent pillars 100 with each other.

The inner member removing process S100, the outer member cutting and unloading process S200, and the column supporting process S300 are repeated for each layer as one disassembling operation cycle to disassemble the structure. It is preferable that the dismantling work cycle is repeated for each layer in the order of top-down from the upper layer to the lower layer so that the structure is disassembled. Due to the weight of the structure, top down to top down and down to top down. Therefore, the inner member removal process (S100), the outer member cutting and unloading process (S200), and the column strengthening process (S300) are repeated for each layer as one cycle until the last layer is demolished (S400).

For example, in the case of a 20-story building, first, when the inner member removal process S100, the outer member cutting and removal process S200, and the column strengthening process S300 are completed at the 20th floor, A process S100, an external material cutting and unloading process S200, and a column stiffening process S300 are performed. Similarly, when the inner member removal process S100, the outer member cutting and removal process S200, and the column strengthening process S300 are completed in the 19th layer, the inner member removal process S100 in the 18th layer, (S200), and a column reinforcing process (S300) are performed. When the disassembling operation cycle is performed in this manner, the columns 100 remain in the entire layer of the structure as shown in FIG. 7, and the columns 100 are supported as the stiffeners 200 to prevent collapse.

On the other hand, when the columns 100 in the demolished layer are supported by the reinforcing member 200, they can be supported in the following two ways.

8, one end of the stiffener 200 is horizontally connected to the first column 100a, the other end of the stiffener 200 is connected to the second column 100a adjacent to the first column 100a, The first column 100a and the second column 100b may have a horizontal support structure that supports the first column 100a and the second column 100b as horizontally positioned stiffeners 200. [

9, the stiffener 200 is inclined so that one end thereof is coupled to the first column 100a and the other end of the stiffener 200 is connected to the second column 100a adjacent to the first column 100a, The first column 100a and the second column 100b may have an inclined support structure for supporting the first column 100a and the second column 100b together as a stiffener 200 disposed at an inclined position.

However, when the pillars 100 are supported as a single support structure 200 as a horizontal support structure or a slant support structure, the reinforcing effect of the reinforcement 200 may be reduced. Generally, in the case of the stiffener 200 such as the H-beam stiffener 200, the stiffener 200 is made of a material having a higher compressive stress than the tensile stress. Therefore, when the stiffener 200 between the first column 100a and the second column 100b is positioned only in a horizontal support structure, all the stiffeners 200 can be struck down, while the first columns 100a and 100b When the stiffener 200 between the second columns 100b is positioned only in the inclined supporting structure, the force is received only in the inclined direction, and the uniform supporting force can not be exerted.

Therefore, in the embodiment of the present invention, the columns 100 in the demolished layer are supported by the stiffener 200 because the stiffener 200 is positioned horizontally between the first column 100a and the second column 100b When reinforced by a horizontal support structure and an inclined support structure in which a plurality of stiffeners 200 are disposed between the first column 100a and the second column 100b as inclined slopes, A plurality of stiffeners 200 having a horizontal support structure and an inclined support structure are alternately arranged alternately for each layer between the first column 100a and the second column 100b. Therefore, by having the composite structure alternating between the horizontal support structure and the inclined support structure, the supporting force for supporting the first column 100a and the second column 100b can be improved.

The H-beam stiffener 200 requires a separate assembly when the stiffener 200 is coupled to the column 100. In order to connect the stiffeners 200 to the column 100, A plurality of assemblies must be provided. In this case, there is a problem that the work time for mounting the stiffener 200 is increased and the cost is increased.

In order to solve this problem, the present invention provides a method for allowing two stiffeners 200 to share one joint when pillars 100 in the demolition layer are supported by the stiffener 200. [

For example, as shown in FIG. 11, when a column reinforcing operation is performed between the first column 100a and the second column 100b in the upper removed layer, the lower end of the first column 100a and the upper The upper end of the second column 100b located at a position higher than the lower end of the first column 100a and the upper end of the uppermost column reinforcing member 200a 200a are coupled as an upper demolition-layer second column assembly 202a and supported in an inclined manner.

12, after the bottom of the upper demolition layer is demolished, a column strengthening operation is performed between the first column 100a and the second column 100b in the lower demolition layer immediately below the upper demolition layer The upper end of the first column 100a of the lower demolition layer and one end of the lower demolition layer reinforcement 200b are coupled as the upper demolition layer first column assembly 201a, The lower end of the second column 100b at the lower position and the other end of the lower demolishing-floor reinforcement 200b are coupled as the lower column-layer second column assemblies 202b to be inclinedly supported.

Therefore, the upper demolition layer first column assembly 201a simultaneously joins the upper demolished reinforcing plate 200a and the lower demolished plate reinforcing plate 200b so that two stiffeners 200a, Thereby reducing the work time and cost of dismantling.

The embodiments of the present invention described above are selected and presented in order to assist those of ordinary skill in the art from among various possible examples. The technical idea of the present invention is not necessarily limited to or limited to these embodiments Various changes, modifications, and other equivalent embodiments are possible without departing from the spirit of the present invention.

S100: The process of removing members
S210: Slab cutting member cutting / unloading process
S220: Cutting / unloading process of external beam cutting member
S300: Column Reinforcement Course

Claims (8)

The inner member of the structure in the demolished layer is taken out of the demolished layer;
An outer member cutting and removing process in which the outer member of the structure in the removed layer taken out of the inner member is cut into a plurality of cutting members and the cut members are taken out to the outside of the removed layer; And
A column reinforcing process in which the columns and columns in the demolished layer are supported by the reinforcing members;
Wherein the inner member removing process, the outer member cutting and removing process, and the column supporting process are repeated for each layer as one disassembling operation cycle to disassemble the structure,
The columns in the demolished layer are supported by the reinforcing members,
A plurality of stiffeners having a horizontal support structure and an inclined support structure are alternately arranged alternately for each layer between the columns and the columns,
The horizontal support structure comprises a reinforcing member horizontally connecting one end to the first column and connecting the other end of the stiffener to the second column adjacent to the first column such that the first column and the second column are positioned horizontally Wherein the inclined support structure comprises a first reinforcing member and a second reinforcing member, the reinforcing member being inclined to connect one end to the first pillar and the other end of the reinforcing member to the second pillar adjacent to the first pillar, Wherein the reinforcing members are supported by each other as a reinforcing member disposed at an inclined position.
The method according to claim 1,
Wherein the dismantling operation cycle is repeated from top to bottom in a top-down order, and the structure is disassembled.
The method as claimed in claim 1,
Cutting the slab member forming the ceiling of the demolished layer with a plurality of slab cutting members and carrying them out; And
Cutting the outer wall beams constituting the wall of the demolished layer with a plurality of outer wall beam cutting members and carrying them out;
≪ / RTI >
4. The method according to claim 3,
Wherein the slab cutting member and the outer wall beam cutting member are cut in the same shape as the cutting lines in a lattice structure so that the shape of the slab cutting member and the shape of the outer wall beam cutting member are the same.
The stator of claim 1,
And an H-beam reinforcement connecting the adjacent columns to each other.
delete delete The column according to claim 1, wherein the columns in the demolished layer are supported by a reinforcing member,
When the column reinforcing operation is performed between the first column and the second column in the upper demolition layer, the lower end of the first column and one end of the upper demolished-layer reinforcement are joined as the upper demolition layer first column combined body, The upper end of the second column and the other end of the upper reinforcing layer reinforcing member are coupled to each other as the upper reinforcing layer second pillar combined body,
One end of the lower reinforcing layer reinforcing member is joined to the upper reinforcing layer first column connecting body when the column reinforcing operation is performed between the first pillar and the second pillar in the lower reinforcing layer immediately below the upper reinforcing layer, And the lower end of the column and the other end of the lower reinforcing steel layer reinforcement are combined as a lower reinforcing layer second pillar combined body and supported in an inclined manner.

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