KR102144579B1 - Module structure with shear reinforcement device - Google Patents

Abstract

The present invention relates to a vertically-stopped shear reinforcement body module structure and, more specifically, to a vertically-stopped shear reinforcement body module structure which connects a plurality of vertically-stopped shear reinforcement bodies to a single connection bar to integrate the vertically-stopped shear reinforcement bodies to conveniently and quickly store, move, and install the plurality of shear reinforcement bodies. The attaching force to concrete can be improved while sturdily responding to various displacements by the structure. And the connection bar is formed on a binding groove to easily bind a reinforcing bar and the shear reinforcement body when installing the shear reinforcement body. A penetration hole, through which mortar can pass, is formed on the connection bar to quickly fill mortar and prevent the formation of air gaps. Also, an arc is formed by bending an upper head making up the shear reinforcement body upwards to allow sturdy and easy deposition with a reinforcing bar. Moreover, a protruding reinforcement rib is formed on the connection bar, the bar for shear reinforcement, etc., to further improve the effect of shear reinforcement.

Description

Vertically engaging shear reinforcement module structure {MODULE STRUCTURE WITH SHEAR REINFORCEMENT DEVICE}

In the present invention, by connecting a plurality of vertically-engaged shear reinforcements to one connecting bar and integrally configured, storage, movement or installation of a plurality of shear reinforcements can be made more conveniently and quickly, as well as It relates to a vertically entangled shear stiffener module structure, which can improve adhesion to concrete while responding firmly to various displacements by the same structure.

In general, in the case of a reinforced concrete structure built with multiple floors, a slab that provides a certain area while forming the floor of each floor and the slab is supported, and the load of the building and the working load generated from each floor are distributed to the foundation. It is configured to include a number of pillars to transmit.

In such a reinforced concrete structure, in the case of the main head of the column, which is the junction where the column and the slab meet, a shear force acts between the slab along the periphery of the column, and the proof strength for this connection is insufficient. In this case, there is a risk of shear failure.

In particular, the joint between the column and the slab in the flat plate structure in which the slab is directly supported only by the column without installing girders or beams, unlike the beam and column connection, excessive stress concentration occurs around the column. Due to this, the slab causes two-way shear failure (punching shear failure) that forms the surface of the reverse trapezoid.

Such shear failure is very brittle, unlike other types of failure, so it is very critical to the safety of the joint between the column and the slab, and special attention is paid to the connection between the column and the slab during structural design to prevent shear failure from occurring. Sufficient action must be taken.

Accordingly, as a method for increasing shear strength by reinforcing the joint between the column and the slab in the above-described non-bulk structure, a method of installing a drop panel and a capital around the column is commonly used. However, it is possible to reduce shear stress through the enlargement of the cross section by installing a fingerboard or a headboard, but it is not only cumbersome to manufacture a formwork for the formation of such a fingerboard or a headboard, and it is not very effective in terms of reinforcing performance. Has a problem.

In order to improve this, as a method for reinforcing the shear performance of the joint between the column and the slab, a method of increasing the shear strength by installing a reinforcing member such as a separate shear stiffener at the joint has been proposed. Examples include a method of using stirrup, a method of installing a shear head, and a method of installing a shear stud.

The method of using the stirrup (ribs) most widely used in the current construction site is the upper and lower slabs arranged across the junction between the column 1 and the slab 2 and 3, as shown in Fig. 1(a). This is a method of reinforcing the shear strength by winding the stirrup (4) around the reinforcing bar (3).

Since the stirrup 4 is generally used by bending and processing deformed reinforcing bars with a diameter of 10 mm at a factory or construction site, it is not necessary to prepare a separate material for the configuration of the shear reinforcement, so the material supply and demand is relatively simple. On the other hand, there is a disadvantage in that it is difficult to properly maintain the covering thickness of the slab as the stirrup (4) is constructed in a form that wraps the outer circumference of the upper and lower slab reinforcing bars (3), and if it is possible to maintain the covering thickness of the slab When attempting to do so, there is a problem in that the spacing between the upper and lower slab reinforcing bars 3 is inevitably reduced, resulting in a decrease in the bending resistance ability of the slab.

Therefore, the method of increasing the shear strength by using the stirrup 4 is difficult to apply to a thin slab, and furthermore, there is a problem that the workmanship is increased as a plurality of stirrups are bound, so that the workability is relatively poor.

Meanwhile, as shown in Fig. 1(b), the method of increasing the shear strength by installing a shear head is to form a shear stiffener in a lattice shape by connecting H-beams 5 or channels vertically and horizontally. And, by installing this at the junction of the column (1) and the slab (2, see Fig. 3), it is a method to share the proof strength against the shear force.

However, such a shear head installation method has a problem that, depending on the use of the section steel, more than necessary steel is required, as well as the self-load of the building increases.

In addition, as shown in Fig. 1(c), the method of installing shear studs is by assembling a plurality of stud bolts 7 welded to the upper part of the flat iron plate 6 processed in the form of a strip. This is a method of reinforcing shear strength by configuring a shear stiffener and installing it at the junction of the column (1) and the slab (see Fig. 3).

In the case of this method, experiments have shown that it is more effective than bending reinforcing bars or stirrup reinforcing materials by improving the adhesion performance between the head of the stud bolt and the steel plate. However, it requires welding work for a number of stud bolts (7). There is a problem that it is cumbersome.

Various types of shear stiffeners have been developed in order to improve the problem of the conventional shear strength reinforcing method for the joint between the column and the slab. Recently, prior art such as Patent Documents 1 to 3 has been proposed.

More specifically, in Patent Document 1, the upper chord and the lower chord are arranged side by side at a predetermined interval at the upper and lower chords, and a web member bent to have a continuous wave is vertically bonded to both the upper and lower chords at the same time. As a result, it is formed in a planar thrust shape, and has a structure in which the corrugated bent portions of the pair of web materials are staggered in a zigzag manner, but in this case, there is a problem that the structure is complex and manufacturing is difficult.

In addition, Patent Document 2 is composed of a structure in which a horizontal upper member, a vertical intermediate member, and a horizontal lower member are continuously repeatedly formed, and is arranged to surround the main reinforcement in the vertical direction inside the slab, but in this case, the poured concrete is relatively densely filled. There is a problem that it cannot be done.

In addition, Patent Document 3 is configured such that a plurality of studs consisting of a coupling portion fixedly coupled to the body portion and the rail, and a head portion having a cross-sectional area larger than that of the body portion are erected at regular intervals on the strip-shaped rail, in this case, the stud There is a problem in that the manufacturing process is difficult because it must be joined to the rail one by one by welding.

In the case of the conventional shear reinforcement applied to the joint between the column and the slab, since most of the components are joined by welding, the manufacturing man-hour increases, and when an external force is applied during the transportation or construction process, the welding part is detached (脫離), there is a risk of cross-sectional loss.

Therefore, in order to solve the above problems, the applicant of the present invention has previously applied and registered a vertically engaging shear stiffener of a new type of column-slab joint as in Patent Document 4.

Specifically, Patent Document 4, as shown in FIGS. In the shear reinforcement body 100 of the column-slab joint that is vertically installed to increase resistance to shear fracture, the first shear reinforcement bar formed to have a predetermined length so as to be vertically disposed with respect to the slab reinforcement (3) (bar) (22) and a first upper head (24) positioned horizontally at the upper end of the first shear reinforcing bar (22) and having a horizontal cross-sectional area equal to or wider than that of the first shear reinforcing bar (22) ), and a first lower head 26 positioned horizontally at the lower end of the first shear reinforcing bar 22 and having a horizontal cross-sectional area equal to or wider than the first shear reinforcing bar 22 The sub-frame 20 and the second shear reinforcing bar 42 formed with a predetermined length to be disposed vertically with respect to the slab reinforcing bar 42, and the upper end of the second shear reinforcing bar 42 The second upper head 44 is positioned horizontally and has a horizontal cross-sectional area equal to or wider than that of the second shear reinforcing bar 42, and is positioned horizontally at the lower end of the second shear reinforcing bar 42, A second sub-frame 40 made of a second lower head 46 having a horizontal cross-sectional area equal to or wider than that of the second shear reinforcing bar 42; this, the first sub-frame 20 is positioned to be spaced apart from each other. ) And the insertion space 30 is formed between, and the top of the insertion space 30 crosses the insertion space 30 between the first and second subframes 20 and 40 Both sides of the connecting piece 60 to be closed are fixed to each of the first sub-frame 20 and the second sub-frame 40 spaced apart from each other, so that the first sub-frame 20 and the second sub-frame 40 By providing a vertically-engaged shear reinforcement of the column-slab joint formed by combining, after the slab reinforcement 3 is constructed, the slab reinforcement 3 is vertically vertically attached. The connecting piece 60 is lowered to and installed so that the connecting piece 60 is caught and fixed to the slab reinforcing bar 3 passing through the insertion space 30, and thus, the slab reinforcing bar ( While the construction of the shear reinforcement for 3) is made simple and easy, the strength reinforcement efficiency of the slab can be improved.

However, the vertically entangled shear stiffener of the column-slab joint previously applied and registered by the applicant of the present invention, during construction, decreases in construction convenience due to the shaking of the respective independent first and second subframes. , There was also a problem that the fastening force with the slab reinforcement was insufficient.

However, when a plurality of shear reinforcements according to Patent Document 4 are handled, storage, movement, and installation are cumbersome and cannot be quickly performed, and each shear reinforcement may not efficiently respond to lateral displacement. In addition, there is a problem that the adhesion to concrete may be insufficient.

Patent Document 1: Korean Patent Registration Publication No. 10-676627 "Shear reinforcement of slab-column joint and shear reinforcement structure using the same" Patent Document 2: Korean Patent Laid-Open Publication No. 10-2007-53836 "Shear reinforcement for joints between column slabs and manufacturing method thereof" Patent Document 3: Republic of Korea Patent Publication No. 10-2004-76644 "Reinforced concrete reinforcement and construction method of a reinforced concrete structure including the same" Patent Document 4: Republic of Korea Patent Publication No. 10-0947339 "Vertical engaging shear stiffener of column-slab joint"

The present invention is to solve the above problems, by connecting a plurality of vertically-engaged shear stiffeners to one connecting bar and integrally configured, storage, movement or installation of a plurality of shear stiffeners is easier and faster. In addition to making it possible to achieve this, it is an object to improve adhesion to concrete while responding firmly to various displacements by the above structure.

In addition, the present invention makes it easy to bind the reinforcing bar and the shear reinforcement when the shear reinforcement is installed by forming a binding groove in the connecting bar, and by forming a through hole through which the mortar can pass through the connecting bar Not only does the filling take place quickly, but also prevents the formation of voids, and by bending the upper head forming the shear reinforcement upward to form an arc, the deposition with the reinforcing bar can be made more robust and easier, and Another task is to further improve the shear reinforcement effect by forming a reinforcing rib protruding in the shear reinforcing bar and the connecting bar.

The present invention is a shear reinforcement bar 11 formed to a predetermined length so as to be disposed vertically with respect to the slab reinforcement (3); An upper head 12 extending laterally from an upper end of the shear reinforcing bar 11; And a lower head 13 horizontally extending laterally from the lower end of the shear reinforcing bar 11; vertically engaging shear stiffener 10 comprising a plurality of vertically engaging shear stiffeners In the module structure, characterized in that the plurality of vertically engaging shear stiffeners 10 are coupled to one connecting bar 20, the vertically engaging shear stiffeners module structure as a means of solving the problem. .

Here, the combination of the vertically engaging shear stiffener 10 and the connecting bar 20 is configured by combining the lower surface of the lower head 13 of the vertically engaging shear stiffener 10 and the connecting bar 20 It is desirable to be.

In addition, the connection bar 20 is preferably formed with a plurality of binding grooves 21 along the edges of both sides.

In addition, it is preferable that a through hole 22 is formed at a joint portion between the lower head 13 and the connection bar 20.

In addition, the upper head 12 is configured to extend laterally from the upper end of the shear reinforcing bar 11, forming an arc in an upward direction and extending, and the shear reinforcing bar 11 and the connecting bar 20 It is preferable that each of the ribs 23 protruding linearly is formed in ).

In the present invention, by connecting a plurality of vertically-engaged shear reinforcements to one connecting bar and integrally configured, storage, movement or installation of a plurality of shear reinforcements can be made more conveniently and quickly, as well as The same structure has the effect of improving adhesion to concrete while responding firmly to various displacements.

In addition, the present invention makes it easy to bind the reinforcing bar and the shear reinforcement when the shear reinforcement is installed by forming a binding groove in the connecting bar, and by forming a through hole through which the mortar can pass through the connecting bar Not only does the filling take place quickly, but also prevents the formation of voids, and by bending the upper head forming the shear reinforcement upward to form an arc, the deposition with the reinforcing bar can be made more robust and easier. There is an effect of forming a reinforcing rib protruding in the shear reinforcing bar and the connecting bar to further improve the shear reinforcing effect.

Figure 1 (a), (b), (c) is a plan view for showing the shear reinforcement of a general column-slab connection
2A and 2B are diagrams showing the technical idea of a vertically-engaged shear stiffener of a column-slab joint previously applied and registered by the applicant of the present invention
3 is a view for showing a state in which a vertically engaged shear stiffener of a column-slab joint previously applied and registered by the applicant of the present invention is installed on a slab reinforcement laid around the column-slab joint
Figure 4 is a real photo of the vertically hung type shear stiffener module structure according to an embodiment of the present invention
5 is a partial enlarged real photo of a vertically hung shear stiffener module structure according to an embodiment of the present invention

The present invention relates to a vertically-engaged shear stiffener module structure, in each drawing and in the detailed description, configurations and actions that can be easily understood by those in the field, and specific elements that are not directly related to the technical features of the present invention Detailed descriptions and illustrations of the technical configuration and operation have been simplified or omitted.

Hereinafter, referring to the accompanying drawings, a detailed description of the module structure of the vertically engaged shear stiffener according to the present invention is as follows.

4 is a real picture of the vertically hung type shear stiffener module structure according to an embodiment of the present invention, and Fig. 5 is a partially enlarged real picture of the vertically hung type shear stiffener module structure according to an embodiment of the present invention.

The present invention is characterized in that, as shown in Figs. 4 and 5, a plurality of vertically engaged shear stiffeners 10 are connected to one connecting bar 20 to be integrated.

Here, the vertically engaging shear reinforcement 10 is a shear reinforcing bar 11 formed to have a predetermined length so as to be vertically disposed with respect to the slab reinforcing bar 3, and a side from the upper end of the shear reinforcing bar 11 It is preferable to include an upper head 12 extending in the direction and a lower head 13 extending horizontally in the lateral direction from the lower end of the shear reinforcing bar 11, but is not necessarily limited thereto and is already known. Various shear stiffeners can be applied.

On the other hand, the coupling of the vertically-engaged shear stiffener 10 and the connection bar 20 is a combination of the lower head 13 of the shear stiffener 10 and the connection bar 20, the general bolting, Various previously known bonding methods, such as welding, can be used.

That is, by connecting a plurality of vertically engaged shear reinforcements 10 to one connecting bar 20 and integrally configured, storage, movement or installation of a plurality of shear reinforcements 10 is more convenient and quicker. In addition, it is possible to improve adhesion to concrete while responding firmly to various displacements by the above structure.

Here, the connection bar 20 has a plurality of binding grooves 21 formed along the edges of both sides. That is, by forming a binding groove 21 in the connection bar 20, when the shear stiffener 10 is installed, the reinforcing bar and the shear stiffener 10 are connected using the binding groove 21 of the connection bar 20. By binding with a connecting body (for example, a string member, etc.), it is possible to bind more simply and firmly.

In addition, a through hole 22 is formed at a joint portion between the lower head 13 and the connection bar 20. That is, by forming the through hole 22 penetrating the lower head 13 and the connection bar 20 at the same time at the coupling portion, not only the mortar passes through the mortar to facilitate rapid filling, but also voids (the mortar is filled And the empty part) can be prevented.

In addition, the upper head 12 of the shear reinforcement body 10 extends laterally from the top of the shear reinforcement bar 11, but forms an arc in the upward direction and extends so that the deposition of the reinforcing bar is more robust and easy. So that it can be done.

In addition, as the shear reinforcing bar 11 and the connecting bar 20 have ribs 23 protruding linearly, respectively, the shear reinforcing effect can be further improved.

In addition, the present invention described above is not limited by the above-described embodiments and the accompanying drawings, and various substitutions, modifications and changes are possible within the scope of the technical spirit of the present invention. It will be obvious to those of ordinary skill in the art.

10: vertically engaging shear reinforcement 11: shear reinforcement bar
12: upper head 13: lower head
20: connecting bar 21: binding groove
22: through hole 23: rib

Claims (5)

Shear reinforcement bar 11 formed with a predetermined length so as to be disposed vertically with respect to the slab reinforcement 3; An upper head 12 extending laterally from an upper end of the shear reinforcing bar 11; And a lower head 13 horizontally extending laterally from the lower end of the shear reinforcing bar 11; vertically engaging shear stiffener 10 comprising a plurality of vertically engaging shear stiffeners In the module structure,
The plurality of vertically-engaged shear stiffeners 10 are configured to be coupled to one connecting bar 20,
The combination of the vertically engaging shear stiffener 10 and the connecting bar 20 is configured by coupling the lower surface of the lower head 13 of the vertically engaging shear stiffener 10 and the connecting bar 20,
The connection bar 20 has a plurality of binding grooves 21 formed along the edges of both sides,
A through hole 22 is formed in the coupling portion between the lower head 13 and the connection bar 20,
The upper head 12 is configured to extend laterally from the upper end of the shear reinforcing bar 11, forming an arc in the upward direction and extending,
The shear reinforcement bar (11) and the connecting bar (20), characterized in that the linearly protruding ribs (23) are each formed, vertically engaging shear reinforcement module structure. delete delete delete delete

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