KR100609187B1 - Stalk-Branche Type Precast Concrete Reinforcing Unit and Aseismatic Structure Using the Same - Google Patents

Abstract

Disclosed are a reinforcing unit for constructing a seismic structure for earthquake-proof reinforcement for an existing building which is not designed to be seismic reinforcing structure, and an improved technique for a seismic reinforcing structure using the same. The present invention is to form a reinforcement structure on the outside of an existing building, such as an aging apartment in the seismic reinforcement to construct a column corresponding to the branches and beams corresponding to the branches as a precast concrete member as one unit unit By combining them vertically and horizontally, the seismic reinforcement structure of the three-dimensional solid lattice shape can be assembled and configured to achieve excellent seismic reinforcement by simple construction, and to solve the disadvantages of the conventional wet method and steel structure. As the technical problem to be made, for this purpose, the present invention has a height corresponding to one or more floors of the building to be reinforced, the pillar member made of concrete material; And a cantilevered horizontal beam protruding horizontally on one side or both left and right sides of the pillar member. .

Remodeling, Seismic Reinforcement, Precast Concrete, Joining

Description

Branch type precast concrete reinforcing unit and seismic reinforcing structure using the same for reinforcing seismic performance of remodeled building {Stalk-Branche Type Precast Concrete Reinforcing Unit and Aseismatic Structure Using the Same}             

1 and 2 are diagrams showing embodiments of a branched seismic reinforcement unit according to the present invention.

Figure 3 is a view of a seismic reinforcement structure made by assembling a branched seismic reinforcement unit according to the present invention.

Figure 4 is a partial detailed view showing an example of the horizontal connection of the twig-shaped reinforcement unit according to the present invention. (Section along the line A-A 'of FIG. 2)

5 is a partial cross-sectional view showing an example of the vertical connection of the branch to the reinforcement unit according to the present invention.

Explanation of symbols on the main parts of the drawings

1: Branch type precast concrete reinforcement unit of the present invention

10: pillar member 15: through hole

18: tendon 20: horizontal beam

22: connecting hardware 25: iron plate

30: horizontal connecting beam 50: front and rear connecting beam

100: reinforcement structure 200: existing building

The present invention relates to a reinforcing unit for constructing a seismic structure for earthquake-resistant reinforcement for an existing building that is not designed for seismic reinforcement, and a seismic reinforcing structure using the same. More specifically, an existing structure requiring seismic reinforcement such as a remodeled building. In order to construct the seismic reinforcement structure, additional three-dimensional three-dimensional grid-shaped seismic reinforcement structure is added to the outside side of the seismic reinforcement structure. The present invention relates to a branch-type precast concrete reinforcing unit capable of improving workability, economic efficiency, and structural safety by continuously combining a tree-shaped unit composed of units in up, down, left, and right, and a seismic reinforcing structure using the same.

Recently, as an alternative to the demolition and new construction of existing reinforced concrete buildings, interest in remodeling has been continuously increasing. This is due to the rapid increase in the demand for housing due to the rapid progress of urbanization, and the improvement of the quality level and utilization of aging inventory buildings. This is due to the fact that remodeling is recommended from the standpoint of improving the level of demand, the need for environmentally friendly building management policies, and the prevention of land development due to reckless building.

This remodeling activity has been mainly focused on special buildings such as offices, shopping malls, hospitals, etc., but recently, the remodeling of the housing sector, especially high-rise apartment buildings such as apartments, is active. The housing sector is expected to lead the overall remodeling market. Moreover, with increasing interest in the environment and the government's policy stance to reduce environmental waste and recycle the framing of existing apartments as far as possible from an economical point of view, apartments that choose to remodel in addition to new construction or reconstruction will increase. It is expected.

On the other hand, in relation to the remodeling of apartment buildings, the apartments built before 1988 in Korea were designed without earthquake-resistant design due to the lack of provisions for earthquake-related provisions. Since 1989, the seismic design of buildings As standards were established, seismic designed apartments were built for earthquakes. Therefore, in the case of buildings before the introduction of the seismic design (1998), it is not only required to carry out seismic reinforcement work for existing frames in remodeling, but also the seismic reinforcement of the part which is expanded by remodeling. It must be designed.

Therefore, in the remodeling as described above, the most common method of seismic reinforcement has been made, which is to reinforce the member strength by adding an iron plate to the beam or column of the existing building or by adding site-cast concrete. In addition, the newly expanded part has been constructed by the reinforced concrete ramen structure or by the structure of the steel structure (Steel Structere) by the moment bonding method. However, the wet method using the existing cast-in-place concrete of the above methods is a disadvantage that the construction work using the formwork and copper bar is accompanied with a lot of waste materials and the construction period also takes a relatively long time. In addition, while the reinforcement method by steel (steel) has the advantage of being prefabricated, it was pointed out that the relatively high construction cost and the need to add a fireproof coating process.

An object of the present invention is to provide a new type of seismic reinforcing method that can be suitably applied to remodeling in the field of apartments such as apartments, as a seismic reinforcing method that can overcome the disadvantages of the conventional seismic reinforcing technology. Specifically, in the reinforcement of seismic reinforcement by forming a reinforcement structure on the outside of an existing building such as an aging apartment, a beam corresponding to a branch and a column corresponding to a stem are configured as a precast concrete member as one unit unit. By combining these unit units vertically and horizontally, the seismic reinforcement structure of the three-dimensional solid lattice shape can be assembled and configured to achieve the seismic reinforcement of excellent performance by simple construction. Precast to make up for the shortcomings To provide a concrete reinforcing unit seismic and seismic using the same reinforcement structure as a technical problem.

In order to achieve the above technical problem, the present invention is a precast concrete reinforcing unit for forming a three-dimensional grid-shaped seismic reinforcement structure by continuously joining a plurality of units in up, down, left and right, one or more floors of the building to be reinforced A pillar member having a height corresponding to and made of concrete; And a cantilevered horizontal beam protruding horizontally on one side or both left and right sides of the pillar member. . In this case, the pillar member may be formed in a single or plural number, and in the case of including a plurality of pillar members, an additional horizontal connection beam may be provided to interconnect the pillar members and the outermost pillar of the pillar members. The cantilever-shaped transverse beam is extended outwardly on the side of the member to allow horizontal connection with adjacent units.

In addition, it is preferable that at least one or more vertical through holes penetrating vertically are formed in the pillar member. Such vertical through holes pass through the tendons and apply a prestress by post tensioning so that coupling between the upper and lower units is possible. It is intended to be made, which is also one of the features of the present invention as a preferred configuration.

The present invention also provides a remodeling seismic reinforcing structure for reinforcing and reinforcing additional reinforcing structures in an existing building for reinforcing seismic performance of a remodeling building, including: an existing building requiring reinforcement; Three-dimensional lattice-shaped reinforcement structure that is installed on at least one side of the existing building; including, wherein the reinforcement structure is a remodeling characterized in that the coupling is formed by connecting the branch-type precast concrete reinforcement unit described above in the up, down, left and right To provide a seismic reinforcement structure using a branch type precast concrete reinforcement unit for seismic performance reinforcement of a building as another form of the present invention, wherein the pillar of the branch type precast concrete reinforcement unit constituting the reinforcement structure It is more preferable that the member is formed with a through hole penetrating up and down, and a prestress is applied by passing the tension tendon in the through hole, but the tendon is installed from the foundation to the top of the reinforcing structure.

Hereinafter, with reference to the accompanying drawings will be described in more detail with respect to the branch-shaped precast concrete reinforcement unit of the present invention having the configuration as described above and the seismic reinforcement structure using the reinforcement unit.

1 is a view showing an embodiment of a branched precast concrete reinforcement unit of the present invention, as shown in the figure, the branched precast concrete reinforcement unit 1 of the present invention is a concrete material as a whole Pillar member 10; And a horizontal beam 20 having a cantilever shape protruding from the side of the pillar member 10 in a horizontal direction.

2 is a view showing another embodiment of the branched precast concrete reinforcement unit of the present invention. 2 is also a precast concrete reinforcement unit which can achieve a three-dimensional lattice-shaped reinforcement structure by continuously combining the unit unit in the up, down, left and right, the basic configuration is the embodiment shown in FIG. As described above, the pillar members 10 and the horizontal beams 20 are the same, except that the number of the pillar members 10 is plural (two in the illustrated example). . In addition, in the present embodiment, it can be seen that the plurality of pillar members 10 as described above are configured to further include a horizontal connection beam 30 so as to interconnect these pillar members 10.

Figure 3 is a perspective view showing the frame structure of the seismic reinforcement is made by forming a seismic reinforcement structure 100 on the side of the existing structure 200 using the branch-type precast concrete reinforcement unit of the present invention as described above, According to the present invention, the seismic reinforcement structure 100 having a three-dimensional three-dimensional lattice shape is constructed as shown in FIG. 3 and is integrally expanded on one side (or both front and rear sides) of an existing building to be remodeled. It is to reinforce the seismic performance of general buildings that are not designed for seismic reinforcement.

In addition, the present invention in forming the three-dimensional lattice-shaped seismic reinforcement structure 100 as described above is not formed by a wet construction method or steel structure, such as the existing cast-in-place concrete, as shown in Figures 1 and 2 Branch-shaped reinforcement unit 1 composed of a pillar member 10 having a predetermined height and a cantilever-shaped horizontal beam 20 protruding to the side is previously provided as a precast concrete member at the factory, and this unit is used in the field. By continuously combining the reinforcement unit up, down, left and right, the main technical feature is to achieve a three-dimensional grid-shaped seismic reinforcement 100 as shown in FIG.

That is, in the reinforcing unit according to the present invention, the pillar member 10 corresponds to a stem as a whole, and the horizontal beam 20 and the front and rear beams 30, which are horizontally bonded to the pillar member 10, correspond to branches. When the branch unit unit 1 is combined up, down, left and right, a substantially planar lattice-shaped structure is formed. By connecting the planar lattice structure to the existing structure 200 by means of separate front and rear connecting beams 50, the seismic reinforcement structure 100 having a three-dimensional lattice shape is formed as a whole. By simply joining precast unit units, it is very easy to achieve seismic reinforcement for buildings that do not have existing seismic reinforcement. At this time, the front and rear connecting beams 50 used in connecting the reinforcing units 1 of the present invention as described above to the existing building 200 can also be constructed by wet concrete pouring, but rather of the present invention When the ready-made precast concrete beams are used as in the reinforcement unit 1, almost all the processes in the construction of the reinforcement structure can be performed in a dry manner, thereby further improving the efficiency of the construction.

On the other hand, the branch-shaped reinforcement unit 1 of the present invention is configured to include at least one or more pillar members 10, the structure of the existing structure that requires reinforcement or the convenience of the production, transportation and storage of the reinforcement unit, etc. In consideration of various conditions, the number of the pillar members 10 may be variously applied. Figure 1 shows the minimum configuration of the reinforcing unit of the present invention as shown in Figure 1, which is configured to have a horizontal beam 20 integrally extended to both sides of one pillar member 10 as shown Can be. However, in the case of the embodiment shown in Figure 1 is shown the minimum unit configuration for forming a three-dimensional lattice shape by assembling, in most cases it is composed of a plurality of pillar members 10 rather than this minimum form between the units It would be advantageous to have as few connection points as possible. There will be no particular limitation on the number of such pillar members 10, but considering the ease of construction of the whole unit, etc., two pillar members 10 are formed as shown in the example shown in FIG. It is expected that protruding the horizontal beam 20 toward the side of 10 may be the best. In this case, the pillar members 10 may be further formed with a horizontal connecting beam 30 to interconnect the pillar members 10. You will need to be able to connect.

In addition, in the present invention, the unit is pointed out as a technical difficulty in the precast concrete structure in that the present invention is to form the entire reinforcement structure by mutually joining the precast concrete unit members manufactured in advance as described above. The treatment of joints between units is particularly important. In addition, the present invention is to reinforce the lack of seismic performance of the existing building, and the joint detail that can satisfy the easy construction property, which is an advantage of the precast concrete structure, together with the joint ductility ability particularly required for such a seismic structure, should be provided. The technical features of the invention may be effective.

Therefore, in the present invention, in connection with the processing of the joint between the unit units as described above, the horizontal joining method is a connection method using a shear connection mechanism, the vertical bonding method is a connection method through a vertical through hole 15 formed in the pillar member is preferred. It proposes as a joining system. First, the connection method using the shear connection mechanism as a horizontal connection method, which will be seen from the illustration of Figure 4, which is connected to the end of the horizontal beam 20 forming the branch reinforcement unit of the present invention ( 22) to be buried, but the connecting hardware 22 is exposed to the outside of one side, and in the connection with the adjacent unit by joining a separate iron plate 25 to the exposed part by welding or the like method This allows for horizontal connection between units. (On the other hand, in the case of the embodiment shown in Figure 4, a predetermined step is formed at the end of the horizontal beam 20, after welding the iron plate 25 as described above, filling the stepped portion with no shrinkage mortar, etc. To finish the construction of the joint.)

According to the horizontal connection method according to the present invention as described above, when the adjacent precast concrete members are bonded to each other, the construction properties are remarkably improved as compared to the conventional method of joining wet precast concrete members such as casting of wet concrete to the joint portion. It will have an effect. Particularly, in connecting the tree branch reinforcement unit of the present invention as described above, the ends of the cantilevered horizontal beams 20 are joined to each other to be joined to each other so that the bending moment is generated when the horizontal position of the joint is generated. It is located in the center of span close to 0 ', and it is hardly affected by the moment even when the horizontal connection method as shown in Fig. 4 is used, and there is no problem in structural safety and also due to the ductility of the steel plate used for joining. The effect of smoothly dissipating energy from vibration during an earthquake can also be expected.

In addition, in the present invention, as for the vertical joining between units, various methods known in the art may be applied as the joining method of precast concrete members, and there is no particular limitation thereto. An example of such a joining method may be a joining sleeve method (in this case, since it belongs to common sense in the art, a detailed description thereof will be omitted), or by the connecting hardware as described above with reference to FIG. 4. It would also be possible to apply a horizontal joining method to a vertical connection.

However, in the present invention, the pillar member 10 constituting the branch reinforcement unit 1 of the present invention as a preferred method for the vertical joining between the units as described above in terms of structural performance and construction properties, etc. The vertical through-hole 15 is formed to penetrate vertically, and a method of vertically connecting the units through the prestressed tendons 18 installed to pass through the vertical through-hole 15 is proposed.

That is, in this method, in the vertical stacking assembly of the branch-shaped reinforcing unit of the present invention, a tendon, such as a steel wire, passes through a tendon in the vertical through-hole 15 formed in the pillar member 10 as described above. By tensioning 18), prestress is applied to the respective units 1 by the contracting force of the tendons 18 so as to be in close contact with each other. At this time, the tendon 18 is vertically laminated by fixing the lower end side to the foundation (not shown) as shown in FIG. 5 and the upper end side to the reinforcing unit forming the uppermost part of the reinforcing structure 100. Configure all units to receive compression.

According to this vertical joining method, the vertical fixing of the whole unit can be carried out by one tendon tension as compared to the above-mentioned joint sleeve method. Therefore, the efficiency of the construction is increased and the seismic reinforcing performance is as follows. The same advantageous effect can be expected. That is, in the case of the vertical joining method by the prestressed tendon as described above with respect to the generation of the tensile force of the pillar member, which is particularly a problem in the vertical structure such as the pillar member at the time of the earthquake, the tensile force generated in the pillar member of the tensioned tendon 18 It can be attenuated by a considerable amount of contraction force, so that the horizontal displacement during an earthquake can be effectively restrained. According to the vertical joining method provided by the present invention as described above, axial force transmission due to gravity load and tensile force generation against a seismic structure are generated. It is possible to obtain a beneficial effect that can be solved at the same time.

Although the present invention has been described in detail by the embodiments described above, those skilled in the art to which the present invention pertains will be capable of various substitutions, additions and modifications without departing from the technical spirit described above. Naturally, such modified embodiments should also be understood as belonging to the protection scope of the present invention as defined by the appended claims.

According to the present invention as described in detail above, in forming the reinforcement structure on the outside of the existing building, such as an aging apartment in the seismic reinforcement, the column corresponding to the beam and stem corresponding to the branch as a precast concrete member By constructing the unit units of the unit and combining the unit units vertically and horizontally, the seismic reinforcement structure of the three-dimensional solid lattice shape can be assembled and constituted. And it is possible to obtain the effect that can compensate for the disadvantages of the steel structure.

Claims (7)

A precast concrete reinforcement unit for forming a three-dimensional grid seismic reinforcement structure by continuously joining a plurality of units in up, down, left and right, A pillar member made of concrete and having a height corresponding to one or more floors of the building to be reinforced; And, Branch-type precast concrete reinforcement unit for the seismic performance reinforcement of the remodeling building comprising a; horizontal beam of the cantilever form protruding horizontally on one side or left and right sides of the pillar member. A precast concrete reinforcement unit for forming a three-dimensional grid seismic reinforcement structure by continuously joining a plurality of units in up, down, left and right, A plurality of pillar members each having a height corresponding to one or more floors of the building to be reinforced and made of concrete; A horizontal beam having a cantilever shape protruding outwardly toward a side of the outermost pillar member among the plurality of pillar members; And, A horizontal connection beam interconnecting the plurality of pillar members; Branch-type precast concrete reinforcement unit for the seismic performance reinforcement of the remodeling building comprising a. The method of claim 1 or claim 2, wherein the pillar member is a branch-shaped precast concrete reinforcement unit for reinforcing the seismic performance of the remodeling building, characterized in that the through-hole further penetrating up and down. According to claim 1 or claim 2, Branched precast concrete reinforcement unit for the seismic performance reinforcement of the remodeling building, characterized in that the connecting means is further formed at the end of the horizontal beam to be connected to the adjacent unit. The method of claim 4, wherein the connecting means is embedded in the end of the horizontal beam to expose a portion of a separate connecting hardware, the connection is made to the adjacent unit by welding the steel plate on the exposed portion of the connecting hardware. Twig-type precast concrete reinforcement unit for seismic performance reinforcement of remodeling buildings, characterized in that it is made to be. In the remodeling seismic reinforcing structure that reinforces additional reinforcing structures to existing buildings to reinforce the seismic performance of the remodeling building, Existing buildings requiring reinforcement; And, Including; three-dimensional lattice-shaped reinforcement structure installed on at least one surface of the existing building; The reinforcement structure is a branch type precast for reinforcing the seismic performance of the remodeling building characterized in that the coupling is made by connecting the tree-shaped precast concrete reinforcement unit for the seismic performance reinforcement of the remodeling building according to claim 1 in up, down, left and right Seismic reinforcement structure using concrete reinforcement unit. The pillar member of the branch type precast concrete reinforcement unit for reinforcing the seismic performance of the remodeling building constituting the reinforcing structure is formed in the through hole penetrating up and down and the tendon in the tensioned state in the through hole. The prestress is applied by passing through, but the tendons are installed from the foundation to the top of the reinforcement structure. The seismic reinforcement structure using the branch type precast concrete reinforcement unit for reinforcing the seismic performance of the remodeling building.

Images