KR20090063694A - Shear reinforcement device for junctional region of column-slab - Google Patents

Abstract

A shear reinforcement of a post - slab junction is provided to increase the effectiveness of construction by reducing the construction time. A shear reinforcement of a post - slab junction comprises: a reinforcement bar(20) to be perpendicularly arranged between top and bottom slab reinforcement; an upper head(40) located to be horizontal to the upper end of the reinforcement bar and having a horizontal cross section wider than the reinforcement bar; and a lower head(60) located to be horizontal to the bottom of the reinforcement bar and having the horizontal cross section wider than the reinforcement bar. The reinforcement bar has the bottom surface of the upper head closely adhered to the upper slab reinforcement and has the top surface of the bottom head to the bottom upper slab reinforcement.

Description

Shear reinforcement device for junctional region of column-slab

The present invention relates to a shear reinforcing body of the column-slab joint, and more specifically, the upper and lower ends of the shear reinforcing bar is formed in the form of a head having a horizontal cross-sectional area larger than the shear reinforcing bar is formed slab reinforced to cross each other Since the construction of the shear reinforcement for the slab reinforcement can be easily and easily carried out by being inserted into the lattice space of the slab, the shear reinforcement of the column-slab joint is improved. It is about.

In general, in the case of reinforced concrete structures, which are constructed of multiple floors, the floors of each floor are provided with a slab that provides a constant area and supports the slab, and at the same time, the self load of the building and the working loads generated in each floor are distributed to the foundation. It consists of a plurality of pillars to transmit.

In such a reinforced concrete structure, in the case of the head of the column, which is the junction where the column and the slab meet, the shear force acts between the slab along the periphery of the column, so that the strength for the joint is not sufficient. In this case, shear failure may occur.

In particular, in the flat plate structure in which the slab is directly supported only by the column without installing girders or beams, the connection between the column and the slab causes excessive stress concentration around the column, unlike the beam and column connection. This causes the slab to cause two-way shear failure (punching shear failure) that forms an inverted trapezoidal surface.

Unlike other forms of failure, such shear failure is very brittle and extremely deadly to the safety of the joint between the column and the slab, and it is necessary to pay special attention to the joint between the column and the slab in order to prevent the shear failure from occurring. Sufficient measures should be taken.

Therefore, as a method for increasing shear strength by reinforcing a joint between a pillar and a slab in the flat plate structure, a method of installing a drop panel and a capital around the column is commonly used. However, although the shear stress can be reduced through the enlargement of the cross section by installing the fingerboard or the headboard, it is not only cumbersome to manufacture the formwork for forming the fingerboard or the headboard, but also it is not very effective in terms of reinforcement performance. Has a problem.

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

Currently, the most widely used method of stubble (root) in the construction site, as shown in Figure 1 (a), the upper and lower slab reinforcement (3) disposed across the joint between the column (1) and the slab (2) Winding the stirrup (4) around (3 ') to reinforce the shear strength.

Since the stirrup 4 is generally used by bending and processing a deformed steel having a diameter of 10 mm at a factory or a construction site, it is not necessary to prepare a separate material for the construction of the shear reinforcement, and thus it is relatively easy to supply and supply materials. On the other hand, it is economical, but as the stub 4 is constructed to cover the outer circumference of the upper and lower slab reinforcing bars 3 and 3 ', it is difficult to maintain the coating thickness of the slab properly. Attempting to maintain the coating thickness inevitably reduces the spacing of the upper and lower slab reinforcing bars 3 and 3 ', thereby reducing the bending resistance of the slab.

Therefore, the method of increasing the shear strength using the stub 4 is difficult to apply to a slab with a thin thickness, and there is a problem in that the workability increases due to the binding of a plurality of stubble, the workability is relatively low.

On the other hand, the method of increasing the shear strength by installing a shear head, as shown in Figure 1 (b), the H-shaped steel (5) or the channel is longitudinally and horizontally bonded to the shear reinforcement in the form of grating And, by installing this in the joint portion of the column 1 and the slab 2 is a way to share the strength of the shear force.

However, such a shear head installation method, there is a problem that the steel load more than necessary according to the use of the shape steel, as well as the building's own load increases.

In addition, the method of installing the shear stud is, as shown in Fig. 1 (c), by assembling the welding of a plurality of stud bolts 7 on the top of the flat iron plate (6) processed in the form of a strip (Strip) The shear reinforcement is configured, and the shear strength is strengthened by installing it at the junction of the column 1 and the slab 2.

In this case, experiments have shown that it is more effective than bending reinforcement or stub reinforcement by improving the adhesion performance by the head and the steel plate of the stud bolt, but the welding work for a plurality of stud bolts (7) is required to manufacture The problem is that it is cumbersome.

Various types of shear stiffeners have been developed to improve the problems of the shear strength reinforcing method for the joint between the column and the slab, and recently, Patent Registration No. 10-676627 (Shear stiffener of the slab-column joint and Shear reinforcement structure using the same), Published Patent No. 10-2007-53836 (Sheet reinforcement between the column slab and its manufacturing method), Patent Publication No. 10-2004-76644 (Reinforced concrete reinforcement and the same The construction method of the crete structure has been proposed as a prior art.

The prior art of the Patent Registration No. 10-676627 is that the upper and lower chords are arranged side by side at a predetermined interval from the top and bottom, and the web member bent to have a continuous waveform at the same time in both the upper and lower chords It is vertically bonded to form a planar trust, and a pair of wave-shaped bent portions of the web material are arranged in a staggered manner, but in this case, there is a problem in that the structure is complicated and difficult to manufacture.

In addition, the prior art of the Patent Publication No. 10-2007-53836 consists of a structure in which the horizontal upper member, the vertical intermediate member and the horizontal lower member are formed repeatedly in succession, and arranged to surround the upper and lower main reinforcing bars in the slab, in which case the casting There is a problem in that the concrete is not packed relatively densely.

In addition, the prior art of the Patent Publication No. 10-2004-76644 is a plurality of studs made up of the body portion and the coupling portion fixedly coupled on the rail and the head portion having a wider cross-sectional area than the body portion is erected at regular intervals on the strip-shaped rail Although it is configured to be installed, in this case, there is a problem that the manufacturing process is difficult because the studs must be welded to the rails one by one.

In the case of the shear reinforcement applied to the joint between the column and the slab as described above, most of the components are manufactured by welding, so that the number of manufacturing labor is increased, and when the external force is applied during the transportation or construction, the welding part is detached. There is a risk of cross-sectional loss.

In order to solve the problem of the shear body applied to the joint between the conventional column and the slab, the present applicant has an upper side formed in parallel in the longitudinal direction from the upper side, the lower side formed in parallel in the longitudinal direction from the lower side of the upper portion And the connecting portion formed by connecting the upper and lower portions integrally and separated by a piercing hole spaced apart in the longitudinal direction, the "I" type cross section, the "c" type cross section, the "Z" type cross section structure. A single type of shear reinforcement and a pair of shear reinforcement having an assembly type shear reinforcement connected by a separate support plate was proposed and filed.

However, when applying the single type of shear reinforcement or prefabricated shear reinforcement proposed by the applicant to the joint between the column and the slab, the slab reinforcement and the shear reinforcement are interlaced with each other in the longitudinal direction and the width direction during the construction process. There is a problem that interference occurs between them.

In particular, in order to penetrate the widthwise slab reinforcing into the piercing hole on the shear reinforcement body, ① construct the slab reinforcement only to the periphery of the portion where the slab and the pillar are joined, and After placing the slab rebar in the piercing hole on the shear reinforcement one by one, the slab reinforcing bar should be connected to the slab reinforcing bar. There is a problem that the number of airborne and the work process is very demanding.

Therefore, the present invention improves the problems of the prior art, and the upper and lower ends of the shear reinforcing bar is formed in the form of a head having a horizontal cross-sectional area larger than the shear reinforcing bar is inserted into the lattice space formed by the slab reinforcement bar to cross each other Since the construction of the shear reinforcement for the slab reinforcement can be made easily and easily, the shear reinforcement of the column-slab joint of the column-slab joint can be improved. It aims to provide.

According to a feature of the present invention for achieving the above object, the present invention is a slab reinforcement (3) which is respectively reinforced horizontally in the upper and lower sides at the site where the column (1) and the slab (2) constituting the reinforced concrete structure are bonded to each other In the shear reinforcement 100 of the column-slab joint which is installed perpendicular to (3 ') to increase the resistance to shear failure, it is arranged vertically between the upper and lower slab reinforcement (3) (3') Shear reinforcing bar (bar) formed to a predetermined length (20); An upper head 40 horizontally positioned at an upper end of the shear reinforcing bar 20 and having a horizontal cross-sectional area larger than that of the shear reinforcing bar 20; A lower head 60 positioned horizontally at the lower end of the shear reinforcing bar 20 and having a horizontal cross-sectional area wider than that of the shear reinforcing bar 20; Including, after the construction of the slab reinforcing bar (3) (3 '), characterized in that the upper head 40 is caught by the upper slab reinforcement (3) to be fixed.

In the shear reinforcement of the column-slab joint according to the present invention, the shear reinforcing bar 20 has a bottom surface of the upper head 40 in close contact with the upper slab reinforcement 3, and the lower head 60. The upper surface of is characterized in that it has a length in close contact with the lower slab reinforcement (3 ').

In the shear reinforcement of the column-slab joint according to the present invention, the shear reinforcing bar 20 has an upper and lower ends connected to the centers of the upper head 40 and the lower head 60, respectively, and the upper head ( 40 and the lower head 60 is made of any one selected from a polygonal flat plate, a circular plate characterized in that the shear reinforcement (100) to have a symmetrical shape.

In the shear reinforcement of the pillar-slab joint according to the present invention, the shear reinforcing bar 20 is characterized in that it is detachably coupled to the upper head 40 and the lower head 60, respectively.

To this end, in the shear reinforcement of the column-slab joint according to the present invention, the shear reinforcing bar 20 is male threaded at the upper and lower ends, respectively, and the upper head 40 and the lower head 60 are the shear reinforcement. Coupling holes 42 are female-threaded at positions corresponding to upper and lower ends of the bar 20, and the shear reinforcing bar 20 is bolted to the upper head 40 and the lower head 60. It is characterized by.

In the shear reinforcement of the pillar-slab joint according to the present invention, a guide plate 80 having a predetermined length is further provided, and the upper head 40 is attached to the bottom surface of the guide plate 80 at a predetermined interval. It is characterized in that the three shear reinforcement 100 is integrally stored, moved, installed.

Here, the guide plate 80 is formed with a plurality of through-holes 82, the through-holes 82 is a portion to which the upper head 40 is welded, or when the concrete is poured into the concrete guide plate ( 80) is characterized in that the part for being integrally combined with the concrete.

According to another feature of the present invention for achieving the above object, the present invention is a slab reinforcing bar (3) which is respectively reinforced horizontally up and down at the site where the column 1 and the slab (2) constituting the reinforced concrete structure are bonded to each other In the shear reinforcing body 100 of the column-slab joint that is installed perpendicular to the (3 ') to increase the resistance to shear failure, the upper and lower parts 12, 14 are bent in the same direction and the upper and lower parts 12 A pair of subframes 10 having a connecting portion 16 formed vertically between the (14) is provided, the pair of subframes 10 are symmetrically facing each other and the connecting portions 16 are coupled to each other, The connecting portions 16 of the pair of subframes 10 coupled to each other are shear reinforcing bars 20 formed to have a predetermined length vertically disposed between the upper and lower slab reinforcing bars 3 and 3 '. Make up; The upper part 12 of the pair of subframes 10 coupled to each other is positioned horizontally at the top of the shear reinforcing bar 20 and has a horizontal cross-sectional area larger than that of the shear reinforcing bar 20 ( 40); The lower portion 14 of the pair of subframes 10 coupled to each other is horizontally positioned at the lower end of the shear reinforcing bar 20 and has a horizontal cross-sectional area larger than that of the shear reinforcing bar 20 ( 60), and after the upper slab reinforcement (3) is constructed, the upper head 40 is characterized in that it is caught by the upper slab reinforcement (3).

In the shear reinforcement of the column-slab joint according to the present invention, the subframe 10 is characterized in that the upper and lower portions of the 'I' type plate 19 is formed in a 'c' shape bent at a right angle.

In the shear reinforcement of the column-slab joint according to the present invention, the subframe 10 is coupled to each other by a spot welded portion, or a fixed clip 18 is attached to the portions that are abutted to each other. It is characterized by.

In the shear reinforcement of the pillar-slab joint according to the present invention, a guide plate 80 having a predetermined length is further provided, and the upper head 40 is attached to the bottom surface of the guide plate 80 at a predetermined interval. It is characterized in that the three shear reinforcement 100 is integrally stored, moved, installed.

In the shear reinforcement of the pillar-slab joint according to the present invention, the guide plate 80 has a plurality of through holes 82 formed therein, and the through holes 82 are welded portions of the upper head 40. Or, when the concrete is poured into the concrete is characterized in that the guide plate 80 is a portion to be integrally combined with the concrete.

Shear reinforcement of the column-slab joint according to the present invention can be inserted into the lattice space formed by the slab reinforcement to be crossed to each other can be fastened to the slab reinforcement so that the slab reinforcement is easily installed after the shear reinforcement is installed When the shear reinforcement is installed by simply fixing the shear reinforcement to the slab rebar, the construction of the shear reinforcement can be easily performed, while the time required for construction is reduced, thereby increasing the construction efficiency. In addition, the shear reinforcing body of the column-slab joint according to the present invention has the effect of improving the strength reinforcing efficiency of the slab as it is embedded in concrete in the form of a head having a horizontal cross-sectional area larger than the shear reinforcing bar at the top and bottom of the shear reinforcing bar Has

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to FIGS. 2 to 12. On the other hand, in the drawings and detailed description showing and referring to the construction and operation easily understood by those skilled in the art from the shear reinforcement of the general column-slab junction is briefly or omitted. In particular, in the drawings and detailed description of the drawings, detailed descriptions and illustrations of specific technical configurations and operations of elements not directly related to technical features of the present invention are omitted, and only the technical configurations related to the present invention are briefly shown or described. It was.

2 (a) and (b) is a view for showing the technical idea of the shear reinforcement of the column-slab joint according to the present invention, Figure 3 (a) and (b) is a preferred embodiment of the present invention Figure 4 is a view showing the technical idea of the shear reinforcement of the column-slab joint according to, Figure 4 (a), (b), (c) is a shear of the column-slab joint according to the first embodiment of the present invention Figure 5 is a view for showing the reinforcement, Figure 5 (a) and (b) is a view showing a shear reinforcement of the column-slab joint according to the second embodiment of the present invention, Figures 6 (a) and (b) is a view for showing the shear reinforcement of the column-slab joint according to the third embodiment of the present invention, Figure 7 is a sub-shear of the shear reinforcement of the column-slab joint according to the third embodiment of the present invention 8 is a view illustrating an embodiment of forming a frame, and FIGS. 8A and 8B illustrate pillars according to a third embodiment of the present invention. FIG. 9 is a view illustrating a state in which a subframe of a shear reinforcement of a slab joint is joined by spot welding, and FIGS. 9A and 9B illustrate shear reinforcement of a column-slab joint according to a third embodiment of the present invention. 10 is a view illustrating a state in which a subframe of a sieve is bonded with a fixed clip, and FIGS. 10 (a) and 10 (b) attach a shear reinforcement of a column-slab joint according to the present invention to guide plates at predetermined intervals. Figure 11 is a view showing a state to use a plurality of shear reinforcement body integrally, Figure 11 (a) and (b) is a shear reinforcement of the column-slab joint according to the present invention is attached to the guide plate formed through holes 12 is a view for showing the state, Figure 12 is a view for showing a state in which the shear reinforcement of the column-slab joint according to the present invention is installed on the slab reinforcement around the column-slab joint.

The shear reinforcement of the column-slab joint is installed in the site where the pillars 1 and the slab 2 constituting the reinforced concrete structure are joined to each other to increase resistance to shear failure, according to the present invention. The shear reinforcement of the column-slab joint is formed in the form of a head having a horizontal cross-sectional area larger than the shear reinforcing bar at the upper and lower ends of the shear reinforcing bar. Inserted into the lattice space to be locked to the slab reinforcement is a technical feature. Accordingly, the construction of the shear reinforcement for the slab reinforcement is made simple and easy, and the strength reinforcing efficiency of the slab is increased.

The slab (2) constituting the reinforced concrete structure is made by slab reinforcing bars (3) (3 ') are horizontally reinforced horizontally, and then concrete is poured and hardened. Such slab reinforcing bars (3) (3') The upper and lower sides cross each other to form a grid space (A).

Here, after the slab reinforcement (3) (3 ') is constructed as described above as a shear reinforcement of the column-slab joint, it is wound directly on the slab reinforcement (3) (3') formed along the circumference of the column-slab joint Stirrups installed in the standing and shear studs joined by a method such as welding between the slab reinforcing bars 3, 3 ', etc., but the workmanship as described above in the background art of the present specification. The construction was cumbersome, causing inconvenience and increase of working time. On the other hand, unlike the above, as a shear reinforcement of the column-slab joint installed before the construction of the slab reinforcing bar (3) (3 '), the slab of the application head No. 10-2007-0098914 filed by the present applicant And the shear reinforcement of the column joint, but also, the step of assembling the shear reinforcement, positioning the shear reinforcement in the column and the slab joint, slab reinforcement between the shear reinforcement located in the column and the slab joint (3) As it is necessary to step through the slab reinforcing bars (3) and (3 ') while passing through (3'), the number of labors is high, resulting in inconvenience and increase of working time.

However, the shear reinforcing body 100 of the column-slab joint according to the present invention is formed with heads 40 and 60, which are fastened to the upper and lower ends of the slab reinforcing bars 3, 3 ', and the slab reinforcing bars 3 intersecting with each other. (3 ') is smaller than the unit lattice space (A) formed, the slab reinforcement (3) (3') cross each other as shown in (a) and (b) of FIG. After completion, the slab reinforcement (3) (3 ') intersecting with each other is simply inserted into each of the lattice space (A) formed and is fixed to the slab reinforcement (3) (3') is installed.

That is, the shear reinforcement body 100 of the column-slab joint according to the present invention, after the operator inserts the shear reinforcement body 100 in each of the grid space (A) perpendicular to the slab reinforcement (3) (3) It is installed by being fixed to the slab reinforcing bar (3) (3 ') by a simple operation of moving to'). Thus, unlike the conventional shear reinforcement of the column-slab joint, the shear for the slab reinforcing bar (3) (3 ') Construction of the reinforcement 100 is to be made simply and easily.

In addition, the shear reinforcement body 100 of the column-slab joint according to the present invention has a shape in which the head 40, 60 having a larger horizontal cross-sectional area than the shear reinforcing bar 20 is formed at the upper and lower ends of the shear reinforcing bar 20. Thus, the shear reinforcement 100 of the column-slab joint according to the present invention embedded in the concrete forming the slab (2) is integrally and firmly coupled to the concrete by the head (40) (60) As a result, the resistance to shear force is further increased by the heads 40 and 60 which are firmly coupled with the concrete. In addition, the shear reinforcing body 100 of the column-slab joint according to the present invention is to be reinforced by the head 40, 60 of the upper and lower ends to the compressive force in the vertical direction with respect to the slab (2).

As described above, the shear reinforcing body 100 of the column-slab joint according to the present invention includes a shear reinforcing bar 20, an upper head 40, and a lower head 60.

Shear reinforcing bar 20 is vertically disposed between the slab reinforcement (3) (3 ') which is respectively horizontally arranged up and down horizontally at the site where the column (1) and the slab (2) are bonded to each other, the present invention The shear reinforcing bar 20 according to the preferred embodiment of the upper head 40 is in close contact with the upper slab reinforcement (3), the upper surface of the lower head 60 is in close contact with the lower slab reinforcement (3 '). Has a length. Accordingly, the shear reinforcement 100 of the column-slab joint according to the preferred embodiment of the present invention is stably fixed to the upper slab reinforcement 3 and the lower slab reinforcement 3 'as shown in FIG. By being supported by the upper slab reinforcing bar 3 and the lower slab reinforcing bar 3 ', resistance to the shear force acting in the lateral direction of the slab 2 can be further increased.

The upper head 40 is positioned horizontally on the upper end of the shear reinforcing bar 20, and has a wider horizontal cross-sectional area than the shear reinforcing bar 20, the upper slab reinforcement (3) is in close contact with the bottom, Accordingly, the upper head 40 according to the present invention is caught by the upper slab reinforcing bar 3 so that the shear reinforcement 100 of the column-slab joint according to the present invention is vertically fixed to the slab reinforcing bars 3 and 3 '. It can be installed.

The lower head 60 is positioned horizontally at the bottom of the shear reinforcing bar 20, and has a horizontal cross-sectional area wider than that of the shear reinforcing bar 20, similarly to the upper head 40, and accordingly, the lower slab rebar As the 3 'is in close contact with the upper surface, the shear reinforcing bar 20 positioned between the upper head 40 and the lower head 60 can be stably and vertically installed to act in the lateral direction of the slab 2. It will be able to further increase the resistance to shear.

The upper head 40 and the lower head 60 as described above may be formed in various shapes, as shown in the drawing of the embodiment of the present invention may be made of a flat plate of polygonal cross-section including a square cross-section, otherwise circular It may be made of a cross-sectional flat plate, or may be made of a truncated pyramid or cone shape.

In addition, the shear reinforcing bar 20 may also be formed in a polygonal cross-sectional shape including a square cross section, as shown in the drawings in which an embodiment of the present invention is shown, or alternatively, may be formed in a circular cross-sectional shape.

Here, the shear reinforcement 100 of the column-slab joint according to the embodiment of the present invention as shown in Figures 4 to 6 is the upper head 40 and the lower head 60 consisting of a flat plate of a square section or a circular section ), And a shear reinforcing bar 20 having upper and lower ends respectively connected to the center of the upper head 40 and the lower head 60, respectively, the pillar-slab joint according to the embodiment of the present invention configured as described above. Shear reinforcement of the 100 is installed on the slab reinforcement (3) (3 ') as it has a symmetrical shape, while after being embedded in concrete for the shear force acting in the lateral direction of the slab (2) It generates resistance uniformly and stably.

The shear reinforcement 100 of the column-slab joint according to the present invention has a shape in which the shear reinforcing bar 20, the upper head 40, and the lower head 60 are integrally formed as shown in FIG. It can be prepared as. The shear reinforcement 100 of the column-slab joint according to the first embodiment of the present invention may be manufactured by casting, forging, etc. by a mold, and the shear reinforcing bar 20 and the upper head. 40 and the lower head 60 may be provided separately and then welded together to be integrally manufactured.

In addition, in the application No. 10-2007-0098914 filed by the present applicant "shear reinforcement of the slab and column joint and the method of manufacturing the same", the shear reinforcement manufactured by the press method is perpendicular to the site where the piercing hole is formed. By cutting, the shear reinforcement 100 of the column-slab joint according to the present invention may be manufactured.

On the contrary, the shear reinforcing bar 20, the upper head 40, and the lower head 60 are shown in FIG. 5, in which the shear reinforcement 100 of the pillar-slab joint according to the second embodiment of the present invention is shown. After separately prepared, the shear reinforcing bar 20 may be configured to the shear reinforcement 100 of the column-slab joint so that it is detachably coupled to the upper head 40 and the lower head 60.

To this end, the shear reinforcement body 100 of the column-slab joint according to the second embodiment of the present invention is to allow the upper and lower ends of the shear reinforcing bar 20 to be male threaded to a predetermined length, respectively, the upper head 40 and the lower head. 60 is to form a coupling hole 42 is female threaded in a position corresponding to the upper and lower ends of the shear reinforcing bar 20, the shear reinforcing bar 20 is the upper head 40 and the lower head 60 Bolted).

Here, the drilling holes 42 formed in the upper head 40 and the lower head 60 are simply drilled, and the upper and lower ends of the shear reinforcing bar 20 are male threaded longer than the depth of the coupling holes 42. By doing so, the male threaded upper and lower ends of the shear reinforcing bar 20 may be inserted into the coupling holes 42 of the upper head 40 and the lower head 60, respectively, and then coupled to the nut.

In addition, the shear reinforcement body 100 of the column-slab joint according to the present invention may be manufactured in a form in which the sub-frames 10 of which the shear reinforcement body 100 is bisected and joined to each other as shown in FIG. have.

The subframe 10 constituting the shear reinforcement 100 of the pillar-slab joint according to the third embodiment of the present invention is the upper and lower parts 12, 14 are bent in the same direction and the upper and lower parts 12, 14 The connecting portion 16 is formed vertically therebetween, and the pair of subframes 10 formed as described above are symmetrically opposed to each other and the connecting portions 16 are coupled to each other to be coupled to each other according to the third embodiment of the present invention. Shear reinforcement 100 of the column-slab joint is made.

Here, the connecting portions 16 of the pair of subframes 10 coupled to each other in the shear reinforcement 100 of the column-slab joint according to the third embodiment of the present invention are upper and lower slab reinforcing bars 3 and 3 '. Shear reinforcement bar (bar) 20 is formed to a predetermined length to be disposed vertically between.

In addition, the upper part 12 of the pair of subframes 10 coupled to each other in the shear reinforcement body 100 of the pillar-slab joint according to the third embodiment of the present invention is formed on the upper end of the shear reinforcing bar 20. The upper head 40 is positioned horizontally and has a horizontal cross-sectional area wider than that of the shear reinforcing bar 20.

In addition, the lower portion 14 of the pair of subframes 10 coupled to each other in the shear reinforcement 100 of the column-slab joint according to the third embodiment of the present invention is at the lower end of the shear reinforcing bar 20. The lower head 60 is positioned horizontally and has a horizontal cross-sectional area wider than that of the shear reinforcing bar 20.

Here, in the shear reinforcement 100 of the column-slab joint according to the third embodiment of the present invention, the subframe 10 has upper and lower portions 12 and 14 of the 'I' type plate 19 as shown in FIG. It is preferably made of a 'c' shape bent at a right angle. This 'I' type flat plate 19 can be easily and easily manufactured by press working, and the process of bending the upper and lower portions of the 'I' type flat plate 19 in the same direction can also be made easily and easily. Therefore, the shear reinforcing body 100 of the pillar-slab joint according to the third embodiment of the present invention is made easy and easy to manufacture.

In addition, the pair of subframes 10 forming the shear reinforcement 100 of the pillar-slab joint according to the third embodiment of the present invention are abutted with each other, and then the portions of the connector 16 which are butted together as shown in FIG. 8. Is welded by spot welding, or by a fixed clip 18 attached to the connecting portions 16 butted together as shown in FIG.

The shear reinforcement 100 of the column-slab joint according to the present invention as described above is further provided with a guide plate 80 of a predetermined length, as shown in Figure 10, the upper head 40 to the bottom of the guide plate 80 Is attached at a predetermined interval so that the plurality of shear reinforcement 100 can be integrally stored, moved, and installed, in this case, when the plurality of shear reinforcement 100 is attached to the guide plate 80, storage, Movement and installation can be made more easily and quickly has the effect of shortening the construction time of the shear reinforcement (100).

In the guide plate 80 according to the preferred embodiment of the present invention, a plurality of through holes 82 may be formed as shown in FIG. 11, and the through holes 82 are sheared at the column-slab joint according to the present invention. The upper head 40 of the reinforcement 100 may be used as a welded portion. That is, the upper head 40 of the shear reinforcement 100 of the pillar-slab joint according to the present invention is brought into close contact with the bottom of the guide plate 80 at the portion where the through hole 82 is formed, and the filler or welder 82 and then weld the guide plate 80 and the upper head 40 of the shear reinforcement 100 of the column-slab joint according to the present invention. When the through-hole 82 is formed in the guide plate 80 as described above, the welding efficiency can be increased as the operator can perform welding work on the upper side of the guide plate 80 without lowering the posture.

On the other hand, the through hole 82 formed in the guide plate 80 may be used as a portion for allowing the concrete to be introduced when the concrete is poured when the guide plate 80 is integrally combined with the concrete, between the guide plate 80 As the concrete is connected to the through hole 82, the shear reinforcement 100 of the column-slab joint according to the present invention attached to the guide plate 80 and the guide plate 80 forms a slab 2 more firmly. It is embedded in concrete to perform the shear reinforcement function for the slab (2).

As described above, the shear reinforcement of the column-slab joint according to the embodiment of the present invention is shown in accordance with the above description and drawings, but this is merely described for example and within the scope without departing from the spirit of the present invention. It will be appreciated by those skilled in the art that various changes and modifications are possible.

1 (a), (b) and (c) are plan views for showing the shear reinforcement of a general column-slab joint;

Figure 2 (a) and (b) is a view for showing the technical idea of the shear reinforcement of the column-slab joint according to the present invention;

Figure 3 (a) and (b) is a view for showing the technical idea of the shear reinforcement of the column-slab joint according to the preferred embodiment of the present invention;

Figure 4 (a), (b), (c) is a view for showing the shear reinforcement of the column-slab joint according to the first embodiment of the present invention;

Figure 5 (a) and (b) is a view for showing the shear reinforcement of the column-slab joint according to the second embodiment of the present invention;

Figure 6 (a) and (b) is a view for showing the shear reinforcement of the column-slab joint according to the third embodiment of the present invention;

7 is a view showing an embodiment of forming a subframe of the shear reinforcement of the column-slab joint according to the third embodiment of the present invention;

8 (a) and (b) are views for showing a state in which the subframe of the shear reinforcement of the column-slab joint according to the third embodiment of the present invention is joined by spot welding;

9 (a) and (b) are views for showing a state in which the subframe of the shear reinforcement of the column-slab joint according to the third embodiment of the present invention is bonded with a fixed clip;

10 (a) and (b) is a view for showing a state in which the shear reinforcement of the column-slab joint according to the present invention attached to the guide plate at a predetermined interval to use a plurality of shear reinforcement body integrally. ;

Figure 11 (a) and (b) is a view for showing a state in which the shear reinforcement of the column-slab joint according to the invention is attached to the guide plate formed through holes;

12 is a view showing a state in which the shear reinforcement of the column-slab joint according to the present invention is installed on the slab reinforcement around the column-slab joint.

* Description of the symbols for the main parts of the drawings *

1: pillar 2: slab

3, 3 ': slab rebar 4: stirrup

5: H-beam 6: Flat iron plate

7: stud bolt 10: subframe

12: upper part 14: lower part

16: connecting portion 18: fixed clip

19: 'I' type plate 20: shear reinforcing bar

40: upper head 42, 62: coupling hole

60: lower head 80: guide plate

82: through hole 100: shear reinforcing body

A: Grid space

Claims (12)

Vertically installed slabs (3) (3 ') which are horizontally reinforced horizontally at the site where the pillar (1) and the slab (2) forming the reinforced concrete structure are joined to each other to increase resistance to shear failure In the shear reinforcing body 100 of the pillar-slab joint being A shear reinforcing bar 20 formed to have a predetermined length so as to be vertically disposed between the upper and lower slab reinforcing bars 3 and 3 '; An upper head 40 horizontally positioned at an upper end of the shear reinforcing bar 20 and having a horizontal cross-sectional area larger than that of the shear reinforcing bar 20; A lower head 60 positioned horizontally at the lower end of the shear reinforcing bar 20 and having a horizontal cross-sectional area wider than that of the shear reinforcing bar 20; including, After the slab reinforcing bar (3) (3 ') construction, the upper reinforcement of the column-slab joint, characterized in that the upper head (40) is caught by the upper slab reinforcement (3). The method of claim 1, The shear reinforcing bar 20 has a length at which a bottom surface of the upper head 40 is in close contact with the upper slab reinforcement 3, and an upper surface of the lower head 60 is in close contact with the lower slab reinforcement 3 ′. Shear reinforcement of the column-slab joint characterized in that it has a. The method according to claim 1 or 2, The shear reinforcing bar 20 has an upper and lower ends connected to the centers of the upper head 40 and the lower head 60, respectively, and the upper head 40 and the lower head 60 are formed in a polygonal flat plate and a circular plate. Shear reinforcement of the column-slab joint, characterized in that the shear reinforcement 100 is made of any one selected to have a symmetrical shape. The method according to claim 1 or 2, The shear reinforcing bar 20 is a shear reinforcement of the column-slab joint, characterized in that detachably coupled to the upper head 40 and the lower head 60, respectively. The method of claim 4, wherein The shear reinforcing bar 20 is the top and bottom ends of the male threaded, respectively, the upper head 40 and the lower head 60 is a coupling hole female threaded at a position corresponding to the upper and lower ends of the shear reinforcing bar 20 ( 42) is formed, the shear reinforcement bar is characterized in that the shear reinforcing bar (20) is bolted to the upper head (40) and the lower head (60). The method of claim 1 or 2, A guide plate 80 having a predetermined length is further provided, and the upper head 40 is attached to the bottom surface of the guide plate 80 at predetermined intervals so that a plurality of shear reinforcement bodies 100 are integrally stored, moved, and installed. Shear reinforcement of the column-slab joint, characterized in that. The method of claim 6, The guide plate 80 has a plurality of through-holes 82 are formed, the through-holes 82 is a portion to which the upper head 40 is welded, or when the concrete is poured concrete guides the guide plate 80 Shear reinforcement of the column-slab joint, characterized in that the part to be integrally combined with the concrete. Vertically installed slabs (3) (3 ') which are horizontally reinforced horizontally at the site where the pillar (1) and the slab (2) forming the reinforced concrete structure are joined to each other to increase resistance to shear failure In the shear reinforcing body 100 of the pillar-slab joint being A pair of subframes 10 having upper and lower portions 12 and 14 bent in the same direction and a connecting portion 16 formed vertically between the upper and lower portions 12 and 14 are provided, and the pair of subframes 10 Facing symmetrically with each other and the connecting portion 16 are coupled to each other, The connecting portions 16 of the pair of subframes 10 coupled to each other are shear reinforcing bars 20 formed to have a predetermined length vertically disposed between the upper and lower slab reinforcing bars 3 and 3 '. Make up; The upper part 12 of the pair of subframes 10 coupled to each other is positioned horizontally at the top of the shear reinforcing bar 20 and has a horizontal cross-sectional area larger than that of the shear reinforcing bar 20 ( 40); The lower portion 14 of the pair of subframes 10 coupled to each other is horizontally positioned at the lower end of the shear reinforcing bar 20 and has a horizontal cross-sectional area larger than that of the shear reinforcing bar 20 ( 60) Shear reinforcement of the column-slab joint, characterized in that after the upper slab reinforcement (3) is constructed, the upper head (40) is caught by the upper slab reinforcement (3). The method of claim 8, The subframe 10 is a shear reinforcement of the column-slab joint, characterized in that the 'c' shape of the upper and lower portions of the 'I' plate 19 is bent at a right angle. The method according to claim 8 or 9, The subframe 10 is a shear-reinforced body of the column-slab joint, characterized in that the butt-welded portions are joined by spot welding, or a fixed clip (18) attached separately to the portions opposed to each other is attached. The method according to claim 8 or 9, A guide plate 80 having a predetermined length is further provided, and the upper head 40 is attached to the bottom surface of the guide plate 80 at predetermined intervals so that the plurality of shear reinforcement bodies 100 are integrally stored, moved, and installed. Shear reinforcement of the column-slab joint, characterized in that. The method of claim 11, The guide plate 80 has a plurality of through-holes 82 are formed, the through-holes 82 is a portion to which the upper head 40 is welded, or when the concrete is poured concrete guides the guide plate 80 Shear reinforcement of the column-slab joint, characterized in that the part to be integrally combined with the concrete.

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