KR101343790B1 - Shear reinforcement device for junctional region of column-slab - Google Patents

Abstract

The present invention relates to shear reinforcement for a joint between a column and a slab to be vertically caught and, specifically, to a shear reinforcement for a joint between a column and a slab to be vertically caught as an improvement of shear reinforcement for a joint between a column and a slab to be vertically caught, previously registered as a patent (registration number: 1009473390000) by the same applicant. The present invention forms an engaging protrusion on the bottom surface of a joint piece (to be inserted with a re-bar); integrally or separately forms an engaging piece in the lateral direction of the joint piece (the progressive direction of a re-bar); engaging the engaging protrusion and engaging piece with a slab re-bar in order to prevent the movement of the joint and improve an engaging force between the slab re-bar and the joint. [Reference numerals] (AA) Moving direction of reinforcing bars

Description

Shear reinforcement device for junctional region of column-slab

The present invention is an improvement of the vertically latching shear reinforcement of the column-slab joint registered and registered by the applicant of the present invention (Korean Patent Publication No. 10-0947339), which not only effectively prevents shaking but also slab It relates to a vertically engaging shear reinforcement of the column-slab joint to further improve the fastening force and construction convenience with the rebar.

Generally, in the case of a reinforced concrete structure constructed in several layers, a slab providing a certain area while forming the floor of each layer and a slab supporting the slab are used, and the own load of the building and the working load generated in each floor are dispersed And a plurality of pillars for transferring the plurality of pillars.

In the case of such a reinforced concrete structure, a shear force acts on the main head portion of the column, which is the joint portion where the column meets the slab, with the slab along the periphery of the column. As a result, There is a possibility that shear fracture occurs.

Particularly, unlike the beam and column joint, 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 the girder or beam is excessively concentrated in the periphery of the column, As a result, the slab causes two-way shear failure (punching shear failure), which forms a reverse trapezoidal surface.

This shear failure is very brittle and very critical to the safety of the joint between the column and the slab, so that special attention is paid to the joint between the column and the slab to avoid shear failure It is necessary to take sufficient measures.

Therefore, as a method for reinforcing the joint between the column and the slab in the flat plate structure described above to increase the shear strength, a method of installing a drop panel and a column around the column is generally used. However, it is possible to reduce the shear stress through enlargement of the cross section by providing the fingerboard or the head, but it is not only not only troublesome but also ineffective in terms of the reinforcement performance There is a problem.

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 providing a reinforcing member such as a separate shear reinforcement on the joint has been proposed. A method of using a stirrup (a rack), a method of installing a shear head, and a method of installing a shear stud.

The most widely used method of stubble (root) is currently used in construction sites, as shown in Figure 1 (a), the upper and lower slabs disposed across the joint between the column (1) and the slab (see 2, 3) Winding the stirrup (4) on the reinforcing bar (3) is a way to reinforce the shear strength.

Since the stirrup 4 is generally bent and machined at a factory or a construction site, it is not necessary to provide a separate material for the construction of the shear reinforcement, It is difficult to keep the thickness of the slab coating properly as the stirrup 4 is installed in such a manner as to surround the outer circumference of the upper and lower slab reinforcing bars 3, The spacing between the upper and lower slab reinforcing bars 3 can not be reduced and thus the bending resistance of the slab is reduced.

Therefore, the method of increasing the shear strength by using the stirrup 4 is difficult to apply to a slab having a small thickness, and further, since a plurality of stirrups are bound to each other, the number of workings increases and the workability is relatively lowered.

On the other hand, in the method of increasing the shear strength by installing the shear head, as shown in Fig. 1 (b), the H-shaped beams 5 or channels are joined longitudinally and transversely to form a shear reinforcement in a lattice form (See FIG. 3), and the shear force is distributed to the shear force by providing it at the joint between the column 1 and the slab 2 (see FIG. 3).

However, such a shear head installation method has a problem that the steel itself requires more than necessary steel according to the use of the shaped steel, and the self-load of the building becomes large.

As shown in FIG. 1 (c), a plurality of stud bolts 7 are welded to an upper portion of a flat steel plate 6 processed in the form of a strip to assemble the shear studs Shear reinforcement member is provided at the joining portion of the column 1 and the slab 2 (see Fig. 3) to reinforce the shear strength.

In the case of this method, it has been shown that the stud bolt is more effective than the bending steel or stirrup reinforcement due to the improvement of the adhesion performance by the head and steel plate. However, since welding is required for a plurality of stud bolts (7) There is a problem 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, 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 a horizontal upper member, a vertical intermediate member and a horizontal lower member are formed in a continuous repeating manner to be 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 fixed 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.

Accordingly, in order to solve the problems as described above, the applicant of the present invention has been filed and registered (Korean Patent Publication No. 10-0947339) for the vertically latching shear reinforcement of the new type pillar-slab joint.

Specifically, as shown in FIGS. 2A, 2B, and 3, the pillar 1 and the slab 2 forming the reinforced concrete structure are vertically installed on the slab reinforcement 3 which is horizontally reinforced at a portion where the slab is joined to each other and sheared. In the shear reinforcement 100 of the column-slab joint to increase the resistance to breakage, the first shear reinforcing bar (22) is formed to a predetermined length so as to be perpendicular to the slab reinforcing bar (3) ), A first upper head 24 horizontally positioned at an upper end of the first shear reinforcing bar 22 and having a horizontal cross-sectional area that is greater than or equal to the first shear reinforcing bar 22, and the first upper reinforcing bar 22; The first subframe 20, which is horizontally positioned at the bottom of the first shear reinforcing bar 22 and has a first lower head 26 having a horizontal cross-sectional area that is wider or the same as that of the first shear reinforcing bar 22. And disposed perpendicularly to the slab reinforcing bar 3. A second shear reinforcing bar 42 formed to a predetermined length so as to be horizontally positioned at an upper end of the second shear reinforcing bar 42, and wider than the second shear reinforcing bar 42, or Or a horizontal cross-sectional area of the second upper head 44 having the same horizontal cross-sectional area and horizontally positioned at a lower end of the second shear reinforcing bar 42 and wider than or equal to the second shear reinforcing bar 42. A second subframe 40 formed of a second lower head 46 having a second lower head 46 having an insertion space 30 formed between the first subframe 20 and spaced apart from each other; Both sides of the connecting piece 60 to close the upper end of the insertion space 30 across the insertion space 30 between the first subframe 20 and the second subframe 40 are spaced apart from each other. The first subframe 20 and the second subframe 40 are fixed to the frame 20 and the second subframe 40, respectively. ) By providing a vertically latching shear reinforcement of the column-slab joint formed by combining the slab reinforcing bar, and after installing the slab reinforcing bar (3), it is installed by lowering vertically from the upper side of the slab reinforcing bar (3). 60 is caught by the slab reinforcing bar (3) passing through the insertion space 30, and is thereby easily fixed to the slab reinforcement (3), thereby the shear reinforcement for the slab reinforcement (3) While the construction is made simple and easy, the strength reinforcement efficiency of the slab is to be improved.

However, the vertically latching shear stiffener of the pillar-slab joint registered and registered by the applicant of the present invention, the construction convenience is lowered due to the shaking of the independent first subframe and the second subframe during construction. In addition, the fastening force with the slab rebar was also insufficient.

: Republic of Korea Patent Registration No. 10-676627 "Shear Reinforcement of Slab-Column Joint and Shear Reinforcement Structure Using It" : Republic of Korea Patent Publication No. 10-2007-53836 "Shear reinforcement of the joint between the column slab and its manufacturing method" : Republic of Korea Patent Publication No. 10-2004-76644 "Reinforced concrete reinforcement and reinforced concrete structure construction method including the same" : Republic of Korea Patent Publication No. 10-0947339 "Vertical locking type shear reinforcement of the column-slab joint"

In order to solve the above problems, the present invention is to improve the vertically latching shear reinforcement of the column-slab joint, which is pre- filed and registered by the applicant of the present invention (Korean Patent Publication No. 10-0947339), By forming a fastening protrusion on the lower surface of the reinforcement (rebar insertion surface), by forming the fastening piece integrally or separately in the lateral direction (reinforcing bar direction) of the connecting piece, so that the fastening projection and the fastening piece is fixed to the slab reinforcement Another object is to provide a vertically engaging shear stiffener at the column-slab joint to prevent its shaking and to further improve the fastening force with the slab reinforcement.

The present invention is located horizontally on the first shear reinforcing bar (22) and the first shear reinforcing bar (22) formed to have a predetermined length to be disposed perpendicular to the slab reinforcing bar (3) The first upper head 24 and the first shear reinforcing bar 22 that is wider than the first shear reinforcing bar 22 or have the same horizontal cross-sectional area as the first shear reinforcing bar 22. A first subframe (12) positioned horizontally at a lower end and having a first lower head (26) having a horizontal cross-sectional area that is wider than the first shear reinforcing bar (22) or the same as the first shear reinforcing bar (22) 20);

A second shear reinforcing bar 42 formed to a predetermined length so as to be disposed vertically with respect to the slab reinforcing bar 3, and horizontally positioned at an upper end of the second shear reinforcing bar 42; A second upper head 44 wider than the second shear reinforcing bar 42 or having the same horizontal cross-sectional area as the second shear reinforcing bar 42, and a lower end of the second shear reinforcing bar 42; Positioned horizontally and wider than the second shear reinforcing bar 42 or the same as the second shear reinforcing bar 42 A second lower head 46 having a horizontal cross-sectional area, the second lower head 46 being spaced apart from the first subframe 20 to form an insertion space 30 between the first subframe 20 and the first subframe 20. Two subframes 40; And

Both ends are fixed to both sides of the first subframe 20 and the second subframe 40 spaced apart from each other to combine the first subframe 20 and the second subframe 40, and the first subframe Including a connecting piece 60 to close the upper end of the insertion space 30 across the insertion space 30 between the 20 and the second subframe 40.

After constructing the slab reinforcement (3) horizontally reinforced at the site where the column (1) and the slab (2) constituting the reinforced concrete structure is bonded to each other, and then descending vertically from the upper side of the slab reinforcement (3) In the vertically latching shear stiffener of a column-slab joint, the 60 is fixed to the slab reinforcing bar 3 so as to increase resistance to shear failure of the joint between the column 1 and the slab 2. ,

Protruding the fastening protrusion (60b) to the insertion space 30 side on the lower surface of the connecting piece 60,

The vertically engaging shear reinforcement of the column-slab joint, characterized in that the fastening piece 60a is integrally formed in the lateral direction of the connecting piece 60 as a means for solving the problem.

In addition, the first shear reinforcing bar (22) and the first shear reinforcing bar (22) formed to have a predetermined length so as to be disposed perpendicularly to the slab reinforcement (3) and is positioned horizontally on the upper end of the first shear reinforcing bar (22) A first upper head 24 and a lower end of the first shear reinforcing bar 22 that are wider than the first shear reinforcing bar 22 or have the same horizontal cross-sectional area as the first shear reinforcing bar 22. A first subframe 20 which is positioned horizontally in the first lower head 26 and is wider than the first shear reinforcing bar 22 or has the same horizontal cross-sectional area as the first shear reinforcing bar 22. );

A second shear reinforcing bar 42 formed to a predetermined length so as to be disposed vertically with respect to the slab reinforcing bar 3, and horizontally positioned at an upper end of the second shear reinforcing bar 42; A second upper head 44 wider than the second shear reinforcing bar 42 or having the same horizontal cross-sectional area as the second shear reinforcing bar 42, and a lower end of the second shear reinforcing bar 42; Positioned horizontally and wider than the second shear reinforcing bar 42 or the same as the second shear reinforcing bar 42 A second lower head 46 having a horizontal cross-sectional area, the second lower head 46 being spaced apart from the first subframe 20 to form an insertion space 30 between the first subframe 20 and the first subframe 20. Two subframes 40; And

Both ends are fixed to both sides of the first subframe 20 and the second subframe 40 spaced apart from each other to combine the first subframe 20 and the second subframe 40, and the first subframe Including a connecting piece 60 to close the upper end of the insertion space 30 across the insertion space 30 between the 20 and the second subframe 40.

After constructing the slab reinforcement (3) horizontally reinforced at the site where the column (1) and the slab (2) constituting the reinforced concrete structure is bonded to each other, and then descending vertically from the upper side of the slab reinforcement (3) In the vertically latching shear stiffener of a column-slab joint, the 60 is fixed to the slab reinforcing bar 3 so as to increase resistance to shear failure of the joint between the column 1 and the slab 2. ,

Protruding the fastening protrusion (60b) to the insertion space 30 side on the lower surface of the connecting piece 60,

Connecting plate 60c is coupled to the upper surface of the connecting piece 60, vertical fastening type shear reinforcement of the column-slab joint, characterized in that the fastening pieces 60a are formed at both ends of the connecting plate 60c. As another solution to the problem.

On the other hand, in the upper surface of the connecting piece 60, a portion corresponding to the portion where the fastening protrusion 60b is formed is preferably cut to the insertion space 30 side to form the fastening protrusion (60b).

In addition, it is preferable that the fastening piece 60a has elasticity in the form of wrapping the slab reinforcing bar 3.

The present invention is an improvement of the vertically latching shear reinforcement of the column-slab joint, which is pre- filed and registered by the applicant of the present invention (Korean Patent Publication No. 10-0947339), and is provided on the lower surface (rebar insertion surface) of the connecting piece. The fastening protrusion is formed, and the fastening piece is formed integrally or separately in the lateral direction (reinforcing bar direction) of the connecting piece so that the fastening protrusion and the fastening piece can be fastened and fixed to the slab reinforcing bar, thereby preventing the shaking and There is an effect to further improve the tightening force of.

1 (a), (b), (c) is a plan view for showing the shear reinforcement of the general column-slab joint
Figures 2a and 2b is a view for showing the technical concept of the vertically engaging shear stiffener of the column-slab joint registered and registered by the applicant of the present invention
3 is a view for showing a state in which the vertically engaging shear reinforcement of the column-slab joint registered and registered by the applicant of the present invention is installed on the slab reinforcement around the column-slab joint;
Figure 4 is a perspective view of the vertical fastening type shear reinforcement of the column-slab joint according to an embodiment of the present invention
Figure 5 is a side view of the vertically fastening type shear reinforcement of the column-slab joint according to an embodiment of the present invention
Figure 6 is a perspective view of the connecting piece according to an embodiment of the present invention
Figure 7 is a plan view of the vertically engaging shear reinforcement of the column-slab joint according to an embodiment of the present invention
Figure 8 is a perspective view showing the binding state of the vertically engaging shear reinforcement and the slab reinforcement of the column-slab joint according to another embodiment of the present invention

The above objects, features and advantages of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description.

4 is a perspective view of a vertically fastened shear reinforcement of the column-slab joint according to an embodiment of the present invention, Figure 5 is a side view of a vertically fastened shear reinforcement of the column-slab joint according to an embodiment of the present invention 6 is a perspective view of a connecting piece according to an embodiment of the present invention, FIG. 7 is a plan view of a vertically engaging shear reinforcement of a column-slab joint according to an embodiment of the present invention, and FIG. Perspective view showing the binding state between the vertically engaging shear stiffener of the column-slab joint and the slab rebar according to another embodiment

In the vertically engaging shear reinforcement 100 of the pillar-slab joint according to the present invention, subframes 20 and 40 are symmetrical to each other on both sides with an insertion space 30 therebetween. The paired subframes 20 and 40 are shear reinforcing bars 22 and 42 disposed vertically, respectively, and shear reinforcing bars 22 and 42 at upper and lower ends of the shear reinforcing bars 22 and 42. It has a shape having a top head 24, 44 and the bottom head 26, 46 having a horizontal cross-sectional area greater than or equal to 42, so that the pillar according to the present invention embedded in the concrete constituting the slab 2 The vertically engaging shear stiffener 100 of the slab joint is a pair of subframes 20 and 40 and an upper head 24 and 44 of the subframes 20 and 40 with an insertion space 30 therebetween. ) And lower heads (26) (46) are firmly coupled to the concrete integrally so that the resistance to shear forces is integrally tight with the concrete. It is further increased by engaging the sub-frame 20, 40 and the sub-frame 20 (40), the upper head 24, 44 and the lower head 26 (46).

In addition, the vertically engaging shear stiffener 100 of the column-slab joint according to the present invention has a resistance to the compressive force in the vertical direction with respect to the slab 2, and the upper head 24, 44 and the lower head 26 of the upper and lower ends. (46) is to be reinforced.

As described above, the vertically engaging shear reinforcement 100 of the pillar-slab joint according to the present invention has a shape in which the upper and lower parts protrude in the lateral direction, and a first subframe having a vertically connected connection part connecting the upper and lower parts ( 20 and the second subframe 40, and the connecting piece 60 for coupling the first subframe 20 and the second subframe 40 to each other.

The first subframe 20 consists of a first shear reinforcing bar 22, a first upper head 24 and a first lower head 26, and the second subframe 40 has a second shear reinforcement. And a second bar, a second upper head 44 and a second lower head 46.

Here, the first shear reinforcing bar 22 and the second shear reinforcing bar 42 are formed to have a predetermined length so as to be vertically disposed with respect to the slab reinforcing bar 3, and the first shear frame of the first subframe 20 may be formed. The shear reinforcing bar 22 and the second shear reinforcing bar 42 of the second subframe 40 are preferably formed in the same shape and the same size, which is perpendicular to the column-slab joint according to the present invention. For the structural stability of the locking type shear reinforcement (100).

In addition, the first upper head 24 and the second upper head 44 are horizontally positioned at the upper end of the shear reinforcing bars 22 and 42, and are wider than or sheared by the shear reinforcing bars 22 and 42. It has the same horizontal cross-sectional area as the reinforcing bars 22 and 42, and may have various shapes such as a flat plate having a polygonal cross section including a rectangular cross section, a flat plate having a circular cross section, and a pyramid or cone shape with an upper end cut. The first reinforcement body according to the present invention is that the first upper head 24 of the first subframe 20 and the second upper head 44 of the second subframe 40 are formed in the same shape and the same size. Preferred to impart structural stability of (100).

In addition, the first lower head 26 and the second lower head 46 are horizontally positioned at the lower end of the first shear reinforcing bar 22, and are wider than or shear shear reinforcing bars 22 and 42. It has the same horizontal cross-sectional area as the bars 22 and 42, and may have various shapes such as a flat plate having a polygonal cross section including a rectangular cross section, a flat plate having a circular cross section, and a pyramid or cone with a cut end. The first lower head 26 of the first subframe 20 and the second lower head 46 of the second subframe 40 are formed in the same shape and the same size as the shear reinforcement according to the present invention ( 100) to impart the structural stability.

In addition, the first upper head 24 and the first lower head 26, the second upper head 44 and the second lower head 46 are also formed in the same shape and the same size, respectively, the shear reinforcement according to the present invention It is desirable to impart structural stability of the sieve 100.

The first subframe 20 and the second subframe 40 according to the present invention made as described above are spaced apart from each other so that the first shear reinforcing bar 22 and the second subframe of the first subframe 20. An insertion space 30 is formed in the vertical direction between the second shear reinforcing bars 42 of the frame 40.

The upper side of the insertion space 30 is closed by the connecting piece 60 coupling the first subframe 20 and the second subframe 40, and the lower side of the insertion space 30 is open. Accordingly, the slab reinforcement (3) is passed through the lower side of the insertion space 30 is caught by the connecting piece 60 from the upper side of the insertion space (30).

The connecting piece 60 according to the present invention is for coupling the first subframe 20 and the second subframe 40 spaced apart from each other, and the connecting piece 60 has both ends of the first subframe 20. ) And the second subframe 40.

On the other hand, the present invention as shown in Figures 4 to 6, to form a fastening protrusion (60b) to the insertion space 30 side, respectively, on the lower surface of the connecting piece 60, the side of the connecting piece 60 By forming the fastening piece 60a integrally extending in the reinforcing direction, the fastening protrusion 60b and the fastening piece 60a are fastened to the slab reinforcing bar 3 so as to be firmly fixed. Can be prevented.

At this time, a portion corresponding to a portion where the fastening protrusion 60b is formed in the upper surface of the connecting piece 60, as shown in Figure 4 to 7, the incision is formed in the insertion space 30 side the fastening protrusion 60b ) Is formed.

And, the fastening piece 60a may have a variety of forms that can be bound with the slab rebar, as shown in Figures 4, 5 and 6 as an embodiment, surrounding the slab reinforcing bars (3, 8) Fastening piece 60a having elasticity in the form can be applied.

Meanwhile, the fastening piece 60a configured as described above may be formed integrally by extending in the lateral direction (reinforcing bar direction) of the connecting piece 60, as shown in FIGS. 4 to 7. As described above, after the connecting plate 60d is coupled to the upper side of the connecting piece 60 separately from the connecting piece 60, the fastening pieces 60a are formed at both ends of the connecting plate 60c (rebar traveling direction). You can also

The present invention is not limited to the above-described embodiments and the accompanying drawings, and various changes, modifications and variations may be made without departing from the scope of the present invention. Will be apparent to those of ordinary skill in the art.

1: pillar 2: slab
3: slab rebar 3a: rib
20: first subframe 22: first shear reinforcing bar
24: first upper head 26: first lower head
30: insertion space 40: second subframe
42: second shear reinforcing bar 44: second upper head
46: second lower head 60: connection piece
60a: fastening piece 60b: fastening protrusion
60c: connection plate 100: vertically engaging shear stiffener

Claims (4)

A first shear reinforcing bar 22 formed to a predetermined length so as to be vertically disposed with respect to the slab reinforcing bar 3, and positioned horizontally on an upper end of the first shear reinforcing bar 22 and the first A first upper head 24 wider than the shear reinforcing bar 22 or having the same horizontal cross-sectional area as the first shear reinforcing bar 22, and horizontal to a lower end of the first shear reinforcing bar 22; A first subframe (20) consisting of a first lower head (26) positioned so as to be wider than the first shear reinforcing bar (22) or having the same horizontal cross-sectional area as the first shear reinforcing bar (22);
A second shear reinforcing bar 42 formed to a predetermined length so as to be disposed vertically with respect to the slab reinforcing bar 3, and horizontally positioned at an upper end of the second shear reinforcing bar 42; A second upper head 44 wider than the second shear reinforcing bar 42 or having the same horizontal cross-sectional area as the second shear reinforcing bar 42, and a lower end of the second shear reinforcing bar 42; Positioned horizontally and wider than the second shear reinforcing bar 42 or the same as the second shear reinforcing bar 42 A second lower head 46 having a horizontal cross-sectional area, the second lower head 46 being spaced apart from the first subframe 20 to form an insertion space 30 between the first subframe 20 and the first subframe 20. Two subframes 40; And
Both ends are fixed to both sides of the first subframe 20 and the second subframe 40 spaced apart from each other to combine the first subframe 20 and the second subframe 40, and the first subframe Including a connecting piece 60 to close the upper end of the insertion space 30 across the insertion space 30 between the 20 and the second subframe 40.
After constructing the slab reinforcement (3) horizontally reinforced at the site where the column (1) and the slab (2) constituting the reinforced concrete structure is bonded to each other, and then descending vertically from the upper side of the slab reinforcement (3) In the vertically latching shear stiffener of a column-slab joint, the 60 is fixed to the slab reinforcing bar 3 so as to increase resistance to shear failure of the joint between the column 1 and the slab 2. ,
On the lower surface of the connecting piece 60 to form a fastening protrusion (60b) protruding toward the insertion space 30 side, to form a fastening piece (60a) integrally in the side of the connecting piece 60,
Of the upper surface of the connecting piece 60, a portion corresponding to the portion in which the fastening protrusion 60b is formed is formed in the cut portion toward the insertion space 30 to form the fastening protrusion 60b,
The fastening piece (60a), the vertically engaging type shear reinforcement of the column-slab joint, characterized in that it has elasticity in the form of wrapping the slab reinforcement (3). delete delete delete

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