KR20200011037A - Method for reinforcing seismic resistant of building - Google Patents

Abstract

The present invention relates to a seismic reinforcement method of a building, which reinforces seismic performance of a conventional building by a high molecular elastic body, a vertical steel material and a reinforcing frame on the conventional building so as to reinforce the seismic performance with respect to the conventional building of a school and a general middle-to-low rise building, to which seismic design is not applied. A seismic reinforcement method of a building of the present invention includes: a first elastic body applying step of applying a high molecular elastic body onto a floor, a ceiling and a wall portion in the building; a vertical steel material installing step of vertically installing steel materials on four corner portions in the building; and a second elastic body applying step of applying the high molecular elastic body onto the floor, the ceiling and the wall portion in the building after installing the vertical steel materials.

Description

Method for reinforcing seismic resistant of building}

The present invention relates to a seismic reinforcement method for buildings, in order to reinforce seismic performance for existing buildings, such as schools and general low-rise buildings, where seismic design is not reflected, by means of polymer elastomers, vertical steel, and reinforcement frames. It is to reinforce the seismic performance of existing buildings.

Recently, there has been an increasing demand for seismic reinforcement of structures due to aging and strengthening seismic regulations, as well as structural repair and reinforcement due to high strength of structures (buildings) and deterioration of durability due to environmental problems.

As a method for improving the seismic performance of the existing hypothetical structure or the structure to be built, the cross-sectional increase method or the steel plate reinforcement method is used a lot, but the above-described method is not only inconvenient to proceed the process due to the complicated process, In addition to the drawback of requiring too much time, there was a problem that it is difficult to expect sufficient seismic performance.

Therefore, there is an urgent need for the development of construction methods that can effectively reinforce the seismic performance of buildings quickly and easily.

As a conventional technique for improving this, Korean Patent No. 10-0471509 has been proposed 'reinforcing method of structure, reinforcing structure and high ductility material', as shown in Figure 1, the wall dividing the space of the building (building) Different from one side 15a of 17

The high ductility material 21 is separately arrange | positioned at both sides of the side surface 15b, and the through-hole 18 provided with the aperture which can penetrate the connection string material which is needed for connecting the high ductility material 21 with each other is provided with one side and the other. It is provided separately so that it may progress in a horizontal direction at predetermined intervals between the other side surfaces.

For this reason, the high ductility material 21 can be reliably connected through the connection braid material which penetrated and penetrated the through-hole 18 mutually, and the connection brazing material connects the high ductility material 21 to each through hole 18 separately from each other. It is also possible to connect by connecting the high ductility material 21 to each other, while passing through each through hole 18 one by one.

In this case, if a high ductile coating material is installed in the gap between the column and the cosmetic upper wall material, the high ductile coating material is not burdened without exceeding the toughness limit of the column. Although it is only a burden on high-combustibility cladding, the load can be supported while securing the space between the ceiling and the floor or the floor above and after the collapse of the structure, so that it can effectively contribute to lifesaving. It is still exposed to fatal injuries and dangers of life due to concrete fragments or debris suspended solids.

In addition, the seismic reinforcement method, which is one of the seismic reinforcement methods, reinforces only a certain part, and thus, there is a lack of overall balance and force distribution, and it is inefficient in consideration of visual and psychological problems.

Meanwhile, as a prior document, Korean Patent No. 10-1737557 attaches a composite member combining a soft seismic fiber and a non-toxic inorganic flame retardant to a concrete surface, and applies a flame retardant composite material to a seismic and flame retardant composite reinforcement. The method is disclosed.

Korean Patent No. 10-1746933 discloses a method for seismic reinforcement construction of a structure in which cement concrete, a multi-layer epoxy putty and super fiber, and a polya resin are sequentially applied.

Korean Patent Laid-Open Publication No. 10-2013-0117204 discloses a structure for reinforcing seismic resistance by installing a "X" shaped bracing 5 'on a plane wall between a first pillar and a second pillar as shown in FIG. Doing.

Japanese Utility Model Registration No. 3104679 discloses reinforcing the H-beam support 4 'to an existing RC column 5', as shown in FIG.

However, these prior documents do not disclose an earthquake-resistant reinforcing method that can effectively perform a seismic function in the horizontal and vertical directions with respect to the entire building having a multi-layered space. In addition, since the bracing 5 'of Korean Patent No. 10-2013-0117204 is installed only on the horizontal wall between the windows and is spaced apart from each other, the seismic effect on the horizontal wall can be expected, but the overall seismic effect on the whole building is expected. It is difficult to exercise. Japanese Utility Model Registration No. 3104679 can install a H-beam strut 4 'to provide a certain seismic effect.However, additional seismic materials may be added to the H-beam strut 4' to increase the seismic effect. It is not disclosed, and it is difficult to expect effective seismic function for the whole building by this structure alone.

The present invention devised to solve the problems of the prior art as described above, the polymer elastic body, vertical steel in the existing building in order to reinforce the seismic performance for existing buildings, such as schools and general low-rise buildings that do not reflect the seismic design And it has an object to reinforce the seismic performance of the existing building by the reinforcement frame.

In addition, the present invention has another object to prevent the spread of the fire by additionally applying a flame retardant even when a fire occurs during a disaster such as an earthquake.

In addition, the present invention has another object to further enhance the seismic performance by reinforcing the reinforcing frame in the "X" shape on the floor, ceiling and wall portions.

In addition, the present invention is connected to a multi-layer by means of interlayer connection means, not just one space in one floor, the safety of human life to evacuate the structure reinforced by the earthquake-resistant performance when collapsed due to the concrete load of the upper floor when building collapse There is another purpose to promote this.

According to an aspect of the present invention, there is provided a method for reinforcing a building earthquake, comprising: applying a first elastic body to a polymer elastomer on a floor, a ceiling, and a wall of the building; Vertical steel installation step of installing the steel vertically to the four corners of the inside of the building; After the installation of the vertical steel is achieved by the earthquake-resistant reinforcement method comprising a secondary elastic body applying step of applying the polymer elastic body to the floor, ceiling and wall portion in the building.

The above object of the present invention is a building earthquake-resistant reinforcement method in which the unit space is stacked, (A) (a) applying a first elastic body to the polymer elastomer to the floor, ceiling and wall portion in the unit space forming the building; (b) vertical steel installation step of installing the steel vertically to the four corners in the interior of the space; (c) a secondary elastic body coating step of applying the polymer elastic body to the bottom, ceiling and wall portions in the space after the vertical steel is installed, and (d) the polymer elastic body is a paint containing polyurethane or polyurea (E) by providing a flame retardant coating step of applying a flame retardant paint on the polymer elastic body after the first elastic body coating step, the four corner portions of the interior of the space in order from the first elastic body, flame retardant paint, vertical Laminated and reinforced in the order of the steel and the secondary elastic body, and (f) tension the two ends so that the ceiling forms an "X" shape by connecting each of the upper ends of the vertical steel facing diagonally after the vertical steel installation step Frame reinforcement step connected to the reinforcing steel wire or reinforcing steel having a bar; further comprising a horizontal and vertical inside the unit space Completing the directional seismic reinforcement; (B) By repeating the steps of (a), the completed unit spaces are constructed in multiple layers vertically and vertically, and the vertical steels of each unit space are joined together by interlayer connecting means. Comprising the frame reinforcement member is structurally integrally connected with each of the vertical steel and the frame reinforcement member of the other unit space, thereby completing the building earthquake-resistant reinforcement in the height direction; And (c) repeating the steps of (b) to construct a plurality of floors in succession of the building in the height direction to complete the earthquake-proof reinforcement in the longitudinal direction. .

Therefore, the seismic reinforcement method of the building according to the present invention has an effect of enabling seismic reinforcement that is easy to construct for a building that is not designed to be earthquake-resistant by primary elastic body coating, vertical steel installation, and secondary elastic body coating.

In addition, the present invention has another effect of preventing the fire from spreading by additionally applying a flame retardant even when a fire occurs during a disaster such as an earthquake.

In addition, the present invention has another effect of further strengthening the seismic performance by reinforcing the floor, ceiling, and wall portions in a "X" shape as frame reinforcement.

In addition, the present invention is connected to a multi-layer by means of interlayer connection means, not just one space in one floor, the safety of human life to evacuate the structure reinforced by the earthquake-resistant performance when collapsed due to the concrete load of the upper floor when building collapse There is another effect that can be secured.

1 is a structural diagram of a method for reinforcing a structure according to the related art;
2 is a flow chart of a building earthquake-resistant reinforcement method according to the invention.
3 is a cross-sectional view of the building earthquake-resistant reinforcing structure according to the present invention.
4 is an exemplary view showing a frame reinforcement structure according to the present invention.
5 is an exemplary view illustrating a building earthquake-proof reinforcement structure of a vertical multilayer structure according to the present invention.
FIG. 6 is an exemplary view illustrating a building seismic reinforcing structure completed by horizontally installing the building seismic reinforcing structure of FIG.
7 is a view showing a seismic reinforcement structure of the prior art.
Figure 8 is a view showing a four-in the reinforcement structure of the prior art.

The terms or words used in this specification and claims are not to be construed as limiting in their usual or dictionary meanings, and the inventors may appropriately define the concept of terms in order to best describe their invention. Based on the principle that the present invention should be interpreted as meanings and concepts corresponding to the technical spirit of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a flow chart of the building earthquake-resistant reinforcement method according to the present invention. As shown in FIG. 2, when the seismic design is not reflected or the design is reflected, it is for the seismic reinforcement of a building that does not reach the required level of seismic design performance, and it is possible to construct the whole building. More preferably, when it is difficult to evacuate to the outside of the building in case of an earthquake, it is necessary to construct the evacuation space of the double-layered central part of the building so that the route for evacuation is shortened to form a temporary evacuation space. I can reduce the burden.

To this end, the earthquake-resistant reinforcement method of the present invention first applies a polymer elastic body to the floor, ceiling, and wall parts in the building (S100).

After applying the polymer elastomer first (S100), the vertical steel installation (S200) to install the steel vertically to the four corners of the interior of the building, the vertical steel is coupled to the corner structure of the building by means such as anchors.

After installing the vertical steel, the polymer elastic body is secondarily applied to the polymer elastic body on the floor, ceiling, and wall portion of the building (S300).

Here, the application of the secondary polymer elastomer to prevent the frame reinforcing member 300, such as the reinforcing steel wire or the reinforcing steel having a tension bar to be described later when the impact caused by the earthquake to be separated from the seismic reinforcement structure. It is for.

Here, the reinforcing steel wire means a wire material capable of changing the shape of a certain level, such as a general steel wire or a wire rope, the reinforcing steel means a fixed steel of the shape of H-shaped steel, T-shaped steel, etc. used as the vertical steel in the present invention In addition, it is more preferable to use a reinforcing steel wire that can be lighter in order to prevent secondary damage due to its own load of the frame reinforcing material 300 during an external impact or earthquake.

In addition, the frame reinforcement 300 is primarily supported by a hardened polymer elastomer when applied to the lower portion of the concrete, such as the concrete of the building during the external impact or earthquake, when the load is applied to the lower, but more load It is installed to withstand it.

Here, it is more preferable to use a coating material including polyurethane or polyurea as the material of the polymer elastomer to be cured by applying the first and second coatings, and the polymer elastomer has elasticity after curing.

Here, in order to reinforce the flame retardant performance, it is more preferable to further apply a flame retardant paint on the polymer elastic body after applying the first polymer elastic body (S110).

In addition, the vertical steel is irrelevant as long as the steel having a strong structure, such as T-shaped steel or H-shaped steel, but more preferably use H-shaped steel.

3 is a cross-sectional view of the building earthquake-resistant reinforcing structure according to the present invention. As shown in FIG. 3, first, the polymer elastomer is applied to the floor, the ceiling, and the wall of the building to cure, and then the first polymer elastomer layer 100 and the flame retardant paint 110 for reinforcing the flame retardant performance are cured. To form a flame retardant layer 200, and then install a vertical steel material 200, and then apply a polymer elastomer to cure to form a second polymer elastomer layer 120 to form a building seismic reinforcement structure.

4 is an exemplary view showing a frame reinforcement structure according to the present invention. In FIG. 4, the illustration related to the applied elastic body and the flame retardant is omitted, and only the frame reinforcing structure is clearly shown.

* In Figure 4, after installing the vertical steel in the corner portion of the building reinforce the frame by using any one or more of the reinforcing steel wire or reinforcing steel having a tension bar at both ends so that the floor, ceiling and wall parts each form an "X" shape. To combine the frame reinforcement 300 to.

In general, when the frame reinforcement member 300 uses T-shaped steel or H-shaped steel as the steel for frame reinforcement, it is possible to use it as it is because there is little deformation, but in the case of using the reinforcing steel wire by adjusting the length of the reinforcing steel wire In order to secure rigidity, tension bars are provided at both ends of the reinforcing steel wire to secure rigidity.

Further, after the frame reinforcement, the vertical steel 200 is coupled to the interlayer connecting means (not shown) for connecting the lower floor and the upper floor of the building up and down, and the interlayer connecting means is for connecting the vertical steel of the lower floor and the upper floor. Means are sufficient, but connection by bolts and nuts or by connection pins is more preferred.

That is, although FIG. 4 has described the earthquake-proof reinforcement method in which the unit spaces are stacked, as shown in FIG. 5, the steps of FIG. 4 are repeated, and specifically, the floor, ceiling, and wall parts in the unit space forming the building. Applying a first elastomer to the polymer elastomer; Vertical steel installation step of installing the steel vertically to the four corners in the space; After the installation of the vertical steel material is composed of a second elastomer coating step of applying the polymer elastic to the bottom, ceiling and wall portion in the space, the polymer elastic is a paint containing polyurethane or polyurea, the first primary After the elastic body applying step, the flame retardant coating step is applied to the upper portion of the polymer elastic body, so that the four corner portions in the space are in order from the first elastic body, the flame retardant paint, the vertical steel material and the second elastic body in order. Stacked and reinforced, the frame is connected to the reinforcing steel wire or reinforcing steel having a tension bar at both ends to form a ceiling "X" by connecting each of the upper ends of the vertical steel facing diagonally after the vertical steel installation step Reinforcing step; further comprising a horizontal and vertical seismic direction inside the unit space Repeating the step; repeat, by building a plurality of layers vertically and vertically the completed unit space and vertically arranged vertical steel and frame of each unit space by combining the vertically arranged vertical steel with the interlayer connection means It is possible to complete the earthquake-proof reinforcement of the building in the height direction by having the reinforcing member be structurally integrally connected with each of the vertical steel and the frame reinforcing member of the other unit space like a single drawing.

In addition, since the building is generally horizontally installed in the length or left and right directions, by repeating the steps of FIG. It is obvious to those skilled in the art.

According to the present invention, not only the four corners of the unit space are reinforced by the vertical steel coated with the composite seismic layer and the flame retardant layer, but the vertical steel and the frame reinforcing member of each unit space are structurally and functionally connected to each other without being short-circuited. Therefore, the seismic effect of the whole building is very good.

Although the present invention has been shown and described with reference to the preferred embodiments as described above, it is not limited to the above embodiments and those skilled in the art without departing from the spirit of the present invention. Various changes and modifications will be possible.

100: first polymer elastomer layer 110: flame retardant layer
120: second polymer elastomer layer 200: vertical steel
300: frame reinforcement

Claims (2)

In the building earthquake-resistant reinforcement method which unit space is laminated | stacked,
(A) (a) a first elastic body coating step of applying a polymer elastic body to the floor, ceiling and wall portion in the unit space forming the building;
(b) vertical steel installation step of installing the steel vertically to the four corners in the interior of the space;
(c) a second elastic body applying step of applying the polymer elastic body to the bottom, ceiling and wall portions of the space after the vertical steel is installed,
(d) the polymer elastomer is a paint containing polyurethane or polyurea,
(e) a flame retardant coating step of applying a flame retardant paint on the polymer elastic body after the first elastic body coating step
The four corners of the interior of the space are laminated and reinforced from the inside in order of the primary elastic body, the flame retardant paint, the vertical steel material and the secondary elastic body,
(f) frame reinforcing step of connecting the upper ends of the vertical steel facing each other after the vertical steel installation step to each other by a reinforcing steel wire or reinforcing steel having a tension bar at both ends to form a ceiling "X"shape; Further comprising; completing horizontal and vertical seismic reinforcement in the unit space;
(B) Repeat the steps of (a) to build up a plurality of layers vertically and vertically, and combine the vertically arranged vertical steels with the interlayer connecting means to connect the vertical steels in each unit space. Building the earthquake-resistant reinforcement in the height direction by allowing the frame reinforcement member to be structurally integrally connected with each of the vertical steel and the frame reinforcement member of the other unit space. In the building earthquake-resistant reinforcement method which unit space is laminated | stacked,
(A) (a) a first elastic body coating step of applying a polymer elastic body to the floor, ceiling and wall portion in the unit space forming the building;
(b) vertical steel installation step of installing the steel vertically to the four corners in the interior of the space;
(c) a second elastic body applying step of applying the polymer elastic body to the bottom, ceiling and wall portions of the space after the vertical steel is installed,
(d) the polymer elastomer is a paint containing polyurethane or polyurea,
(e) a flame retardant coating step of applying a flame retardant paint on the polymer elastic body after the first elastic body coating step
The four corners of the interior of the space are laminated and reinforced from the inside in order of the primary elastic body, the flame retardant paint, the vertical steel material and the secondary elastic body,
(f) frame reinforcing step of connecting the upper ends of the vertical steel facing each other after the vertical steel installation step to each other by a reinforcing steel wire or reinforcing steel having a tension bar at both ends to form a ceiling "X"shape; Further comprising; completing horizontal and vertical seismic reinforcement in the unit space;
(B) Repeat the steps of (a) to build up a plurality of layers vertically and vertically, and combine the vertically arranged vertical steels with the interlayer connecting means to connect the vertical steels in each unit space. Comprising the frame reinforcement member is structurally integrally connected with each of the vertical steel and the frame reinforcement member of the other unit space, thereby completing the building earthquake-resistant reinforcement in the height direction; And
(C) Building earthquake-resistant reinforcement method comprising the steps of repeating the steps (b) to build a plurality of rows in a row in the horizontal direction, and then complete the seismic reinforcement in the longitudinal direction.

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