KR102813051B1 - Pre-Assembly For Shear Reinforcement Of Flat Slab - Google Patents

Abstract

An invention is disclosed regarding a prefabricated body for shear reinforcement of a flat plate slab.
The prefabricated shear reinforcement of the disclosed flat plate slab maximizes the resistance to shear destruction due to vertical load or eccentric load by increasing the shear reinforcement by shear reinforcement ribs (Stirrup), and also enables precise construction and economical construction through prefabricated construction.

Description

{Pre-Assembly For Shear Reinforcement Of Flat Slab}

The present invention relates to a prefabricated body for shear reinforcement of a flat plate slab, and more particularly, to a prefabricated body for shear reinforcement of a flat plate slab which enhances the resistance to shear destruction by increasing the shear reinforcement capacity by shear reinforcement ribs (stirrup) and enables precise and economical construction.

In general, the apartment structure with a flat-plate slab applied is very advantageous in that it can implement a variable floor plan while maintaining the same floor height as the existing wall-type apartment, so it can be easily applied to remodeling work as well as meeting the various needs of users.

Despite these advantages, flat plate slab structures have no beams, so there is a risk that brittle shear failure may occur at the slab-column joint, causing the collapse of the entire structure. Therefore, great care must be taken when constructing flat plate slabs.

Recently, the supply of apartment complexes using flat plate slabs has been increasing, but the slab thickness (210-250 mm) is relatively thin, making it very difficult to apply the traditional shear reinforcement method using deformed steel bars.

In order to resolve these issues, it is necessary to develop a shear reinforcement method in the flat plate slab joint where reinforcement is concentrated by clearly analyzing the flow of stress acting on the flat plate slab joint. The following patent documents disclose shear reinforcement bodies for shear reinforcement in the flat plate slab joint.

According to Patent Document 1, 'The present invention relates to a reinforced flat plate slab punching shear reinforcement, which is installed at a slab-column joint in a reinforced concrete foundation and flat plate structure to increase the resistance to punching shear destruction of the slab, has a simple structure, and is easy to install.', and 'the flat plate slab punching shear reinforcement is characterized in that a plurality of truss reinforcing bars arranged in parallel and a plurality of straight-line connecting reinforcing bars are connected, and the truss reinforcing bars are repeatedly bent so that an upper horizontal portion and a lower horizontal portion are connected by a vertical portion, and a connecting reinforcing bar is connected by spot welding to the inside of the lower end of the side end vertical portion of the truss reinforcing bars, a connecting reinforcing bar is connected by spot welding to the lower central surface of the upper horizontal portion of the truss reinforcing bars, and a connecting reinforcing bar is connected by spot welding to the upper central surface of the lower horizontal portion of the truss reinforcing bars.'

According to 'Patent Document 2', 'a shear reinforcement structure for a slab-column joint of a flat plate structure is provided using a mesh-type shear reinforcement belt that is easy to manufacture and simple to install, so as to more effectively exert restraint against punching failure due to vertical load and eccentric shear failure due to seismic load', and 'supported on the head of the column'

The invention relates to a mesh-shaped shear reinforcement bar comprising: a lower reinforcing bar arranged; one end of which is installed to be supported by the lower reinforcing bar and positioned around the upper circumference of the main head of the column, and which is made of expanded metal having mesh holes and which has a triangular bottom edge of a predetermined width, a triangular hypotenuse that is symmetrical to each other, and a triangular support leg bent inwardly from the lower end of the triangular hypotenuse to form an expanded triangular mesh having a triangular cross-section over a predetermined length; and at least one triangular mesh reinforcing member installed at both ends of the expanded triangular mesh and between them; upper reinforcing bars arranged on the upper end of the mesh-shaped shear reinforcement bar; a concrete slab formed by pouring concrete to a predetermined thickness so that the upper reinforcing bars are installed on a formwork installed below the lower reinforcing bars; and a hypotenuse reinforcing plate made of a steel plate having a predetermined thickness and having a plate-like shape and a plurality of concrete composite holes in the longitudinal direction, which is installed on the inner surface of the triangular hypotenuse of the expanded triangular mesh and which has a plurality of concrete composite holes in the longitudinal direction.

According to 'Patent Document 3', a structure is provided on the upper side of a slab formwork in all directions around a column for two-way shear reinforcement around the column, wherein a plurality of unit reinforcing bars are formed by bending the middle portion of the reinforcing bars of a predetermined length to form a 'V' shape, and a fixing upper reinforcing bar is inserted into the upper bend portion of the unit reinforcing bars arranged at a predetermined interval to connect and integrally fix the unit reinforcing bars.' It relates to a two-way shear reinforcement structure of a flat plate slab, wherein 'the hook structure improves the anchorage in concrete, and the covering member and the insertion member installed at the lower portion can solve the problem of covering maintenance and rust prevention. In addition, it can be used as a support for the upper reinforcing bar (and the lower reinforcing bar) of the slab, and since it is modularized, it can be installed on site without a separate process or increase in personnel, and thus has improved effects in terms of constructability and economy.'

However, among the above-mentioned prior arts, the flat plate slab punching shear reinforcement of Patent Document 1 has a structure in which parallel-arranged truss reinforcement bars are connected with straight-line connecting reinforcement bars, and therefore has a disadvantage in that its resistance to shear destructive force due to vertical load or eccentric load is weak.

Patent Document 2 also maintains the shear reinforcement force by the expanded triangular mesh by installing the mesh outside the triangular mesh reinforcing material arranged inside, so it has the same weakness as the case of Patent Document 1, and also, the configuration of the triangular mesh using the mesh requires a lot of manufacturing manpower and work processes, which has the disadvantage of high manufacturing costs.

The shear reinforcement structure of Patent Document 3 is made by connecting multiple unit reinforcing bars processed to have a 'V' shape by bending the middle portion of reinforcing bars of a predetermined length to an upper reinforcing bar to exert reinforcing force. However, this also has the same disadvantage of weak resistance to shear destructive force due to vertical load or eccentric load of Patent Document 1.

Therefore, there is an urgent need for the development of a shear reinforcement body having a shear reinforcement structure with increased shear reinforcement capacity so that it can stably exert restraint against shear destruction due to vertical load or eccentric load at slab-column joints.

KR Patent Registration No. 10-1188367 KR Patent Registration No. 10-2320411 KR Utility Model Registration No. 20-0441389

The present invention has been developed to complement the problems of the above-described prior art and to provide various additional advantages. The purpose of the present invention is to provide a pre-assembly for shear reinforcement of a flat plate slab that enhances the resistance to shear destruction due to vertical load or eccentric load by increasing the shear reinforcement force by shear reinforcing ribs (Stirrup) and enables precise and economical construction by pre-assembly.

The above object is achieved by a shear reinforcement pre-assembly of a flat plate slab provided according to the present invention.

According to one aspect of the present invention, a shear reinforcement prefabricated body for a flat plate slab is provided, comprising: first and second closed rib shear reinforcement bodies formed with hook-shaped anchoring portions, wherein a plurality of first and second closed shear reinforcement ribs are welded at a predetermined interval along a plurality of connecting reinforcing bars of a predetermined length to form a closed rib portion for shear reinforcement; And a closed rib joint shear reinforcement provided by an overlapping portion in which a portion of the first closed rib shear reinforcement body and a portion of the second closed rib shear reinforcement body are overlapped and connected to each other; Including the first and second closed rib shear reinforcement bodies, when the first and second closed rib shear reinforcement bodies are installed between the main reinforcing bars of the column and the upper and lower reinforcing bars of the slab, the increased reinforcing force due to the combination of the closed rib joint shear reinforcement bodies with the first and second closed rib shear reinforcement bodies acts as a shear reinforcing force that resists shear destruction occurring at the joint between the column and the slab.
According to another aspect of the present invention, a shear reinforcement prefabricated for a flat plate slab is provided, including: a hoop reinforcement member formed of closed ribs having anchorage portions, in which hoop reinforcement portions having hook-shaped anchorage portions are positioned at one or two locations in the inner center of a closed rib shear reinforcement member, the upper and lower hook-shaped anchorage portions of the hoop reinforcement portions being in contact with the closed ribs and integrally welded thereto, thereby increasing shear reinforcement force; and when the closed rib shear reinforcement member is installed between the main reinforcing bar of a column and the upper and lower reinforcing bars of a slab, the increased reinforcing force caused by combining the hoop reinforcement portion with the closed rib shear reinforcement member acts as a shear reinforcement force that resists shear destruction occurring at the joint between the column and the slab.

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According to the following embodiment of the present invention, the effect of increasing the resistance to shear destruction due to vertical load or eccentric load at the joint between a column and a slab is provided by increasing the shear reinforcement force by the shear reinforcing rib (Stirrup), and also providing the effect of precise construction and economical construction by pre-assembly.

Figure 1 is a drawing showing an example of installation of a pre-assembly for shear reinforcement of a flat plate slab according to the present invention.
Figure 2 is a perspective view showing the appearance of only the pre-assembly for shear reinforcement of the flat plate slab according to the present invention in Figure 1, separated from FIG.
Figure 3 is a perspective view showing a modified example of a prefabricated body for shear reinforcement of a flat plate slab as shown in Figure 2.
Figure 4 is a perspective view showing another embodiment of a shear reinforcement pre-assembly of a flat plate slab according to the present invention.
Figure 5 is a perspective view showing a modified example of a prefabricated body for shear reinforcement of the flat plate slab of Figure 4.
Figure 6 is a perspective view showing another modified example of the pre-assembly for shear reinforcement of the flat plate slab of Figure 5.

The present invention can have various modifications and embodiments, and thus specific embodiments will be described in detail.

However, this is not intended to limit the present invention to specific embodiments, but should be understood to include all modifications, equivalents, or substitutes included in the spirit and technical scope of the present invention.

In addition, when explaining the present invention, if it is judged that a detailed description of a related known technology may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. In addition, the terms described below are terms defined in consideration of their functions in the present invention, and thus may vary depending on the intention or custom of the user or operator, and therefore, their definitions should be made based on the contents of the entire specification explaining the present invention.

Hereinafter, with reference to the attached drawings, a preferred embodiment of a prefabricated body for shear reinforcement of a flat plate slab according to the present invention is described in detail.

Figure 1 is a drawing showing an example of installation of a prefabricated body for shear reinforcement of a flat plate slab according to the present invention.

As shown in the drawing, the pre-assembly (100) for shear reinforcement of a flat plate slab according to the present invention is installed in a roughly cross shape when viewed from above between the main reinforcing bars (12) of a column (10) and the upper and lower reinforcing bars (22) of the slab (in the drawing, the upper reinforcing bar is omitted to avoid confusion with other parts due to the upper reinforcing bar indication. The upper reinforcing bar is installed corresponding to the upper part of the lower reinforcing bar (22)). The maximized reinforcing force provided from each of the pre-assemblies (100) acts as an enhanced shear reinforcing force that resists shear destruction occurring at the joint between the column (10) and the slab (30), thereby enabling more stable resistance to shear destruction force caused by a vertical load mainly occurring at the joint between the column (10) and the slab (30) or an eccentric load caused by an earthquake.

In FIG. 1 according to the present embodiment, a pair of shear reinforcement line assemblies (100) are installed between the wall surface of the column and the slab. However, it will be understood that the number of shear reinforcement line assemblies (100) installed can be changed as desired depending on the thickness (cross-sectional area) of the column. In addition, the detailed configuration of the shear reinforcement line assemblies (100) will be described in detail with reference to FIG. 2.

FIG. 2 is a perspective view showing the appearance of only the pre-assembly for shear reinforcement of a flat plate slab according to the present invention in FIG. 1.

As shown in the drawing, the configuration of the prefabricated body (100) for shear reinforcement of a flat plate slab according to the present invention roughly includes a first open rib shear reinforcement body (110), a second open rib shear reinforcement body (130), and an open rib joint shear reinforcement part (150).

As shown in the drawing, the first open-type rib shear reinforcement (110) is formed by bending and forming a U-shape approximately with reinforcing bars having a predetermined length, and forming hook-shaped anchoring portions (111-1) that are bent inwardly at the upper ends on both sides, and arranging and welding a plurality of first open-type shear reinforcement ribs (111) at a predetermined interval along connecting reinforcing bars (170) having a predetermined length.

As shown in the drawing, the second open-type rib shear reinforcement (130) also has second open-type shear reinforcement ribs (131) having hook-shaped anchoring parts (131-1) similar to the shear reinforcement ribs (111) of the first open-type rib shear reinforcement (110), arranged and welded at a predetermined interval along connecting reinforcing bars (170) having a predetermined length.

As shown in the drawing, the open rib joint shear reinforcement member (150) is configured by joining the first open rib joint shear reinforcement member (110) and the second open rib joint shear reinforcement member (130) so as to overlap each other to form an overlapping member.
As shown in the drawing, the open rib joint shear reinforcement member (150) is formed by arranging the first open shear reinforcement ribs (111) of the first open rib shear reinforcement body (110) between the ribs in a number corresponding to the number of second open shear reinforcement ribs (131) of the second open rib shear reinforcement body (130), while connecting the first open shear reinforcement ribs (111) and the second open shear reinforcement ribs (131) in a state where they overlap to form an overlapping portion, thereby integrally welding the overlapping portion to each other. This makes it possible to form a single shear reinforcement pre-assembly (100).

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The shear reinforcement pre-assembly (100) of the flat plate slab of this configuration is installed to extend from the inside of the main reinforcing bar (12) at the joint between the column (10) and the slab (10) to between the upper and lower reinforcing bars (22) of the slab (10), so that the shear reinforcement force increased by the first and second open rib shear reinforcement bodies (110, 130) and the open rib joint shear reinforcement body (150) in which they are combined to form an overlapping portion acts as a shear reinforcement force that resists shear destruction that may occur due to vertical load generated at the joint between the column (10) and the slab (20) or eccentric load due to an earthquake.

The shear reinforcement pre-assembly (100) of the above-mentioned flat plate slab can be composed entirely of the same reinforcing bar, but it is economically preferable to use the connecting reinforcing bar (170) as a reinforcing material for connecting the ribs using a thinner steel wire than the reinforcing bar used in manufacturing the ribs.

Figure 3 is a perspective view showing a modified example of a prefabricated body for shear reinforcement of a flat plate slab as shown in Figure 2.

As shown in the drawing, the shear reinforcement prefabricated body (100a) of the flat plate slab according to the present embodiment is formed by integrally welding a plurality of hoop reinforcing bars (121a) having hook-shaped anchoring portions (121a-1) on both upper and lower sides, which are arranged at a predetermined interval along connecting reinforcing bars (170a) of predetermined lengths arranged upper and lower, and installing the hoop reinforcing bar reinforcing bar (120a) in an open rib shear reinforcing body (110a) configured in the same manner as the first open rib shear reinforcing body (110) or the second open rib shear reinforcing body (130) of the above embodiment to form a hoop reinforcing bar reinforcing bar (120a), which is different from the above embodiment.

Therefore, in the following, only the configuration of the hoop reinforcing bar reinforcement part (120a), which is different from the first and second open rib shear reinforcing bars (110, 130) of the above embodiment, will be mainly described.

As shown in the drawing, the hoop reinforcing bar reinforcement part (120a) is composed of a hoop reinforcing bar (121a) having a hook-shaped anchoring part (121a-1) formed by bending in the same direction at both upper and lower ends. The hoop reinforcing bars (121a) of the hoop reinforcing bar reinforcement part (120a) are installed in the center of the open rib shear reinforcing body (110a) in a number corresponding to each rib (111a) of the open rib shear reinforcing body (110a), and the lower part is welded integrally with the rib (111a) so as to be in contact with the rib (111a).
The connecting reinforcing bar (170a) welded to the upper portion of the hoop reinforcing bar (121a) is welded only to the hook-shaped anchorage portion (121a-1), whereas the connecting reinforcing bar (170a) placed and welded to the lower portion is welded integrally with the hook-shaped anchorage portion (121a-1) and the rib (111a) of the open rib shear reinforcement body (110a) to form a solid structure.
Accordingly, the shear reinforcement pre-assembly (100a) of the flat plate slab according to the present embodiment also has a shear reinforcement force corresponding to the above embodiment by combining an open rib shear reinforcement body (110a) with a hoop reinforcement member (120a).

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The shear reinforcement pre-assembly (100a) of the above-mentioned flat plate slab can also be composed of all the same reinforcing bars as in the above-mentioned embodiment, but since the connecting reinforcing bars only require connection, the hoop reinforcing bars can be economically connected using thinner wires rather than reinforcing bars.

FIG. 4 is a perspective view showing another embodiment of a shear reinforcement pre-assembly of a flat plate slab according to the present invention.

As shown in the drawing, the configuration of the prefabricated body (200) for shear reinforcement of a flat plate slab according to the present embodiment broadly includes a first closed rib shear reinforcement body (210), a second closed rib shear reinforcement body (230), and a closed rib joint shear reinforcement part (250).

As shown in the drawing, the first closed rib shear reinforcement body (210) is formed by arranging a plurality of first closed shear reinforcement ribs (211) that are formed by bending reinforcing bars of a predetermined length to form a square shape and forming hook-shaped anchoring portions (211-1) at both ends where they meet, and connecting them integrally by welding them with connecting reinforcing bars (270), and the second closed rib shear reinforcement body (230) is also formed by arranging a plurality of second closed shear reinforcement ribs (311) that are configured to have hook-shaped anchoring portions (231-1) like the first closed shear reinforcement rib (211), and connecting them integrally by welding them with connecting reinforcing bars (270).

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As shown in the drawing, the closed rib joint shear reinforcement member (250) is formed by an overlapping portion in which the first closed rib joint shear reinforcement member (210) and the second closed rib joint shear reinforcement member (230) are partially overlapped with each other.
As shown in the drawing, the second closed shear reinforcing ribs (231) are arranged between the first closed shear reinforcing ribs (211), and the second closed shear reinforcing ribs (231) corresponding to the number of the first closed shear reinforcing ribs (211) are arranged in a state in which a portion of the second closed shear reinforcing ribs (231) overlaps the first closed shear reinforcing rib shear reinforcing body (211), thereby forming the closed shear reinforcing rib joint shear reinforcing member (250) by welding the overlapping portion with the first closed shear reinforcing ribs (211).
As shown in the drawing, the closed rib joint shear reinforcement member (250) connects the ribs (211, 231) of the first and second closed rib shear reinforcement bodies (210, 230) integrally by a plurality of connecting reinforcing bars (270) arranged at regular intervals along the first and second closed rib shear reinforcement bodies (210, 230), thereby enabling the construction of a pre-assembled shear reinforcement pre-assembly body (100). When the first and second closed rib shear reinforcement bodies (210, 230) are overlapped and connected, they are connected in a state where some connecting reinforcing bars (270) are absent, and then welded later.
The shear reinforcement pre-assembly (200) of the flat plate slab of this configuration is also installed to extend from the inside of the main reinforcing bar (12) at the joint between the column (10) and the slab (10) to between the upper and lower reinforcing bars (22) of the slab (10), so that the further maximized shear reinforcement force provided by the combination of the first and second closed rib shear reinforcement bodies (210, 230) and the closed rib joint shear reinforcement body (250) acts as a shear reinforcement force that more stably resists shear destruction that may be caused by vertical load generated at the joint between the column (10) and the slab (20) or eccentric load due to an earthquake.

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The prefabricated body (200) for shear reinforcement of the flat plate slab according to the above embodiment is also composed entirely of the same reinforcing bars, and it is more economical to connect the ribs using thinner steel wires than the reinforcing bars used in making the ribs.

Figure 5 is a perspective view showing a modified example of a shear reinforcement pre-assembly of the flat plate slab of Figure 4.

As shown in the drawing, the prefabricated body (200a) for reinforcing the shear of the flat plate slab according to the present embodiment differs from the above embodiment only in that it is installed on a closed rib shear reinforcing body (210a) configured in the same manner as the first and second closed rib shear reinforcing bodies (210, 230) of the above embodiment, by integrally welding a plurality of hoop reinforcing bars (221a) having hook-shaped anchoring portions (221a-1) on both the upper and lower sides, and arranging connecting reinforcing bars (270a) of a predetermined length at the upper and lower sides.

Therefore, in the following, only the configuration of the hoop reinforcing bar reinforcement part (220a), which is different from the first and second closed rib shear reinforcing bars (210, 230) of the above embodiment, will be mainly described.

As shown in the drawing, the closed rib shear reinforcement (210a) of the present embodiment is formed in a wide rectangular shape (rectangular shape) to provide a stable hoop reinforcement part (220a), unlike the first and second closed rib shear reinforcements (210, 230) of FIG. 4, which are formed in a square shape.

As shown in the drawing, the hoop reinforcing bar reinforcement (220a) is composed of a hoop reinforcing bar (221a) having hook-shaped anchoring portions (221a-1) formed by bending in the same direction at both upper and lower ends. The hoop reinforcing bars (221a) are installed in the inner center of the closed rib shear reinforcing body (210a) in a number corresponding to each rib (211a) of the closed rib shear reinforcing body (210a). The hook-shaped anchoring portions (221a-1) at the upper and lower ends are in contact with each rib (211a) so that they can be integrally welded with the rib (211a). In addition, a connecting bar (270a) having a predetermined length is arranged at the upper and lower hook-shaped anchoring portions (221a-1) of the hoop reinforcing bar (221a) to form a hook-shaped The fixing members (221a-1) are placed in contact with each rib (211a) and then welded together to form a solid structure.

Accordingly, the shear reinforcement pre-assembly (200a) of the flat plate slab forming the closed hoop reinforcing bar joint shear reinforcement body according to the present embodiment is also formed by combining the closed rib shear reinforcement body (210a) with the hoop reinforcing bar reinforcement part (220a) to have a shear reinforcement force corresponding to the above embodiment.

The shear reinforcement pre-assembly (200a) of the above-mentioned flat plate slab can also be made of the same reinforcing bars as in the above-mentioned embodiment, but it is more economical to use thinner steel wires as the connecting reinforcing bars than the reinforcing bars used in the production of hoop reinforcing bars.

Figure 6 is a perspective view showing another modified example of the pre-assembly for shear reinforcement of the flat plate slab of Figure 5.

As shown in the drawing, the shear reinforcement pre-assembly (200b) of the flat plate slab according to the present embodiment is different from the modified example above in that the reinforcing force is further increased by installing a plurality of hoop reinforcing bar reinforcing parts (220b) inside the closed rib shear reinforcing bar (210b). That is, hoop reinforcing bars (221b) having hook-shaped anchoring portions (221b-1) are installed in parallel with a predetermined interval inside the closed rib shear reinforcing body (210b) in a number corresponding to each rib (211b) of the closed rib shear reinforcing body (210b), and each hook-shaped anchoring portion (221b-1) integrally welded by the upper and lower connecting reinforcing bars is in contact with each rib (211b) and integrally welded to each rib (211b), so that the hook-shaped anchoring portions (221b-1) of the hoop reinforcing bars (221b) connected by the connecting reinforcing bars (270b) are integrally welded at two locations like each rib (211b) to form a more solid structure.

Accordingly, the shear reinforcement pre-assembly (200b) of the flat plate slab of the closed hoop reinforcing bar joint shear reinforcement body according to the present embodiment also has a shear reinforcement capacity that is further increased compared to the modified example above by combining two hoop reinforcing bar reinforcement parts (220b) in addition to the closed rib shear reinforcement body (210b).

The shear reinforcement pre-assembly (200b) of the above-mentioned flat plate slab can also be composed of all the same reinforcing bars as in the above-mentioned embodiment, but it is economical to use thinner steel wires rather than hoop reinforcing bars for the connecting reinforcing bars.

The shear reinforcement prefabricated body of the flat plate slab according to the present invention having the above configuration provides the advantage of more stably acting against shear destruction that may be caused by vertical load or eccentric load due to an earthquake at the joint between a column (10) and a slab (20), by increasing the shear reinforcement force by combining the shear reinforcement stirrup and the shear reinforcement rib overlap, or by reinforcing the shear reinforcement force by combining the shear reinforcement stirrup and the hoop reinforcement body.

In addition, the on-site introduction of prefabricated shear reinforcement prefabricated structures enables precise construction of buildings and economical construction by allowing mass production without delay, thus reducing construction costs.

Although the present invention has been described in detail above only with respect to the described specific examples, it will be apparent to those skilled in the art that various modifications and variations are possible within the technical scope of the present invention, and it is natural that such modifications and variations fall within the scope of the appended claims.

The present invention is useful for preventing shear failure at a joint between a column and a flat plate slab.

10 : Pillar
20 : Slab
22: Upper and lower reinforcing bars
100: Prefabricated shear reinforcement for flat plate slab
110: First open rib shear reinforcement
130: Second open rib shear reinforcement
150: Open rib joint shear reinforcement
100a: Prefabricated shear reinforcement for flat plate slab
110a: Open rib shear reinforcement
120a: Hoop reinforcement
200: Prefabricated shear reinforcement for flat plate slab
210: First closed rib shear reinforcement
230: Second closed rib shear reinforcement
250: Closed rib joint shear reinforcement
200a: Prefabricated shear reinforcement for flat plate slab
220a: Hoop reinforcement
200b: Prefabricated shear reinforcement for flat plate slab
220b: Hoop reinforcement

Claims (3)

delete First and second closed rib shear reinforcement bodies formed by welding first and second closed shear reinforcement ribs formed with hook-shaped anchorages at regular intervals along a plurality of connecting reinforcing bars of a predetermined length to form a closed rib for shear reinforcement; and
Includes a closed rib joint shear reinforcement provided by an overlapping portion in which a part of the first closed rib shear reinforcement and a part of the second closed rib shear reinforcement are overlapped with each other;
A shear reinforcement pre-assembly of a flat plate slab, in which the first and second closed rib shear reinforcement bodies are installed between the main reinforcing bars of the column and the upper and lower reinforcing bars of the slab, and the increased reinforcing force is combined with the closed rib joint shear reinforcement body to act as shear reinforcement force that resists shear destruction occurring at the joint between the column and the slab. A closed rib shear reinforcement body formed by closed ribs having anchoring portions is provided with hoop reinforcement bars having hook-shaped anchoring portions at upper and lower portions at one or two locations in the inner center, and the upper and lower hook-shaped anchoring portions of the hoop reinforcement bars are welded integrally by contacting the closed ribs to increase shear reinforcing force; including:
A shear reinforcement pre-assembly of a flat plate slab, in which the closed rib shear reinforcement body is installed between the main reinforcing bars of the column and the upper and lower reinforcing bars of the slab, and the reinforcing force increased by combining the hoop reinforcing bars with the closed rib shear reinforcement body acts as a shear reinforcing force that resists shear destruction occurring at the joint between the column and the slab.

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