KR100947339B1 - Shear reinforcement device for junctional region of column-slab - Google Patents

Abstract

The present invention is vertically sheared of the column-slab joint that is installed vertically to the slab reinforcement horizontally reinforcement horizontally at the site where the column and the slab constituting the reinforced concrete structure are horizontally reinforced up and down respectively Provide reinforcement. The vertically engaging shear stiffeners of the column-slab joints are composed of subframes that are symmetrical to each other on both sides with insertion spaces formed in the center in the vertical direction. By being lowered vertically from the upper side to be easily fixed to the slab rebar, the construction of the shear reinforcement for the slab reinforcement is made simple and easy, while improving the strength reinforcing efficiency of the slab.

The vertically fastened shear reinforcement 100, 100 ′ of the column-slab joint according to the present invention includes a first subframe 20, 20 ′, a second subframe 40, 40 ′, and a connecting piece. It consists of 60 (60 '). The first subframes 20 and 20 'are first shear reinforcing bars 22 and 22' formed to have a predetermined length so as to be disposed perpendicularly to the slab reinforcing bar 3, and the first shear reinforcing bars. First upper heads 24 and 24 'positioned horizontally on top of the bar 22 and 22' and having a horizontal cross-sectional area wider than the first shear reinforcing bars 22 and 22 '; It consists of first lower heads 26 and 26 'that are horizontally positioned at the bottom of the shear reinforcing bars 22 and 22' and have a horizontal cross-sectional area wider than the first shear reinforcing bars 22 and 22 '. . The second subframes 40 and 40 'are second shear reinforcing bars 42 and 42' formed to have a predetermined length so as to be perpendicular to the slab reinforcing bar 3, and second shear reinforcing bars ( Second upper heads 44 and 44 'which are horizontally positioned at the top of the 42 and 42' and have a horizontal cross-sectional area wider than the second and second shear bars 42 and 42 '; A second lower head 26, 26 'horizontally positioned at the bottom of the bars 42, 42' and having a horizontal cross-sectional area wider than the second shear reinforcing bars 42, 42 '; The insertion space 30 is formed to be spaced apart from the first subframe 20, 20 ′ with the first subframe 20, 20 ′. In addition, both ends of the connecting pieces 60 and 60 'are fixed to both sides of the first subframe 20, 20 ′ and the second subframe 40, 40 ′ spaced apart from each other. 20 'and the second subframe 40 and 40', and the insertion space 30 between the first subframe 20 and 20 'and the second subframe 40 and 40'. The upper end of the insertion space 30 is closed across. The vertically engaging shear stiffeners 100 and 100 'of the column-slab joint configured as described above are constructed by slab reinforcing bar 3 and then vertically lowered from the upper side of the slab reinforcing bar 3 to be connected to the connecting piece 60. 60 'is characterized in that it is fixed to the slab reinforcement (3) passing through the insertion space (30).

Column, slab, slab rebar, shear reinforcement, shear reinforcing bar, head

Description

Shear reinforcement device for junctional region of column-slab}

The present invention relates to a vertically engaging shear reinforcement of a column-slab joint, and more specifically, to a subframe having a shape symmetrical to each other on both sides with an insertion space formed in an up-down direction in the center. The column is lowered from the upper side of the slab reinforcement to be intersected to be installed so that it can be easily fixed to the slab reinforcement, so that the construction of the shear reinforcement for the slab reinforcement is made simple and easy, and the column reinforcement efficiency is improved. It relates to a vertically engaging shear stiffener of a slab joint.

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. Examples include the use of sturups, the installation of shear heads, and the installation of shear studs.

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 sterrup (4) is a way 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 since the stub (4) is constructed in the form of wrapping the outer circumference of the upper and lower slab reinforcement (3), it is difficult to maintain the coating thickness of the slab properly, and if the slab coating thickness is maintained Attempts to reduce the spacing of the upper and lower slab reinforcement (3), there is a problem that the bending resistance capacity of the slab is reduced.

Therefore, the method of increasing the shear strength by using the stub 4 is difficult to apply to a slab with a thin thickness, and there is a problem 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 it at the junction 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, 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 separating the upper and lower portions integrally and separated by a piercing hole which is formed to be spaced apart in the longitudinal direction, the "I" type cross section, the "c" type cross section, and the "Z" type cross section. A single type shear reinforcement having a structure and a pair of shear reinforcing bodies are proposed and proposed by connecting the assembled shear reinforcement by a separate support plate.

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.

Accordingly, the present invention is to improve the problems of the prior art, consisting of a configuration in which the sub-frames of the shape symmetrical to each other on both sides with the insertion space formed in the center in the vertical direction between the reinforcement of the slab reinforcement to cross each other As it is fixed to the slab rebars by being lowered and installed from the upper side, the construction of the shear reinforcement for the slab reinforcement is made simple and easy, while the new form of column-slab joint that can improve the strength reinforcement efficiency of the slab. An object of the present invention is to provide a vertically engaging shear reinforcement.

According to a feature of the present invention for achieving the above object, the present invention is installed vertically on the slab reinforcement (3) which is horizontally reinforcement at the site where the column (1) and the slab (2) constituting the reinforced concrete structure are joined to each other In the shear reinforcement of the column-slab joint to increase the resistance to shear failure, the first shear reinforcing bar (22) formed to a predetermined length to be disposed perpendicular to the slab reinforcement (3) 22 'and a first upper portion horizontally positioned at an upper end of the first shear reinforcing bars 22 and 22' and having a horizontal cross-sectional area larger than the first shear reinforcing bars 22 and 22 '. A horizontal cross-sectional area located horizontally at the bottom of the head 24, 24 'and the first shear reinforcing bars 22, 22' and wider than the first shear reinforcing bars 22, 22 '. A first subframe 20 (20 ') having a first lower head (26) (26') having; The second shear reinforcing bars 42 and 42 'are formed to have a predetermined length so as to be disposed perpendicularly to the slab reinforcing bar 3, and the second shear reinforcing bars 42 and 42' are horizontal to the upper end. Second upper heads 44 and 44 'having a horizontal cross-sectional area larger than the second shear reinforcing bars 42 and 42', and the second shear reinforcing bars 42 and 42 '. And a second lower head 46 and 46 'horizontally positioned at the bottom of the second lower reinforcing bar 42 and 42' and having a horizontal cross-sectional area larger than that of the second shear reinforcing bars 42 and 42 '. A second subframe 40 (40 ') spaced apart from the second subframe such that an insertion space 30 is formed between the first subframe and the second subframe; Both ends are fixed to both sides of the first subframe 20, 20 ′ and the second subframe 40, 40 ′ spaced apart from each other so that the first subframe 20, 20 ′ and the second subframe are fixed. 40 and 40 ', and the insertion space 30 across the insertion space 30 between the first subframe 20, 20' and the second subframe 40, 40 '. Including the connecting pieces 60, 60 'to close the upper end of the slab reinforcement (3) after the construction, the slab reinforcement (3) is installed by lowering the vertically from the upper side of the connecting piece (60) It is characterized in that it is fixed to the slab reinforcement (3) passing through the insertion space (30).

The vertically latching shear reinforcement of the column-slab joint according to the present invention is that the first subframe 20, 20 'and the second subframe 40, 40' is made of '' 'shape It is any one selected from the 'I' shape, the connecting piece (60, 60 ') is characterized in that any one selected from the plate form and the clip form.

The first subframe 20, 20 ′ and the second subframe 40, 40 ′ in the vertically latching shear reinforcement of the pillar-slab joint according to the present invention have a 'c' shape. The upper and lower portions 52 and 54 of the 'I'-shaped plate 50 are bent at right angles to form a' c 'shape, and the upper and lower portions 52' and 54 'of the rectangular flat plate 50' are bent at a right angle. It is characterized in that it is any one selected from the 'c' form.

The vertically engaging shear reinforcement of the column-slab joint according to the present invention is installed by descending vertically from the upper side of the slab reinforcement, which is arranged to intersect with each other, so that the shear reinforcement can be easily installed after the slab reinforcement is constructed. As the shear reinforcement is installed in the operation of locking the shear reinforcement to the slab reinforcing bars, the construction of the shear reinforcement can be easily performed, while the time taken 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 the accompanying drawings, FIGS. 2 to 11. 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 joints are 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.

(A) and (b) and (c) of Figure 2 is a view for showing the technical concept of the vertically engaging shear stiffener of the column-slab joint according to the present invention, Figure 3 (a) of the present invention An exploded perspective view of the vertically fastening shear reinforcement of the column-slab joint according to the embodiment, Figure 3 (b) is a combined perspective view of the vertically fastening shear reinforcement of the column-slab joint according to the embodiment of the present invention, Figure 3 (c) is a cross-sectional view of the vertically engaging shear reinforcement of the column-slab joint according to an embodiment of the present invention, Figure 3 (d) is a vertical latch of the column-slab joint according to an embodiment of the present invention 4 is a plan view of the type shear reinforcement, and FIG. 4 is a view showing an embodiment of a first subframe and a second subframe constituting a vertically engaging shear reinforcement of a column-slab joint according to an embodiment of the present invention. 5 is a pillar-slab joint according to another embodiment of the present invention. FIG. 6 is a view illustrating an embodiment of a first subframe and a second subframe constituting a vertically engaging shear reinforcement of FIG. 6, and FIG. 6 is a vertically engaging shear reinforcement of a column-slab joint according to another embodiment of the present invention. 7 is a perspective view of the sieve, Figure 7 (a), (b), (c) is a view showing a vertically engaging shear reinforcement of the column-slab joint according to another embodiment of the present invention, (a) and (b) is a view for showing a state in which the first subframe and the second subframe constituting the vertically engaging shear stiffener of the column-slab joint according to the present invention are joined by a clip-shaped connecting piece. 9 (a) and (b) is a state in which the vertically engaging shear stiffener of the column-slab joint according to the present invention is attached to the guide plate at predetermined intervals to use a plurality of shear stiffeners integrally. 10A and 10A are views for showing, and FIGS. (b) is a view showing a state in which the vertically engaging shear reinforcement of the column-slab joint according to the present invention is attached to the guide plate formed with a through hole, and FIG. 11 is a vertically engaging type of the column-slab joint according to the present invention. Shear reinforcement is a view showing the state is installed in the slab reinforcement reinforced 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 vertically engaging shear stiffeners 100 and 100 'of the column-slab joint are subframes 20 and 20' that are symmetrical to each other on both sides with an insertion space 30 formed in an up-down direction in the center. (40) It is characterized in that the configuration is made to be lowered from the upper side of the slab reinforcement (3) which is arranged to cross each other made of a configuration in which the position is positioned. Accordingly, the vertically fastened shear reinforcement 100 (100 ') of the column-slab joint according to the present invention is easily fixed to the slab reinforcement (3) so that the shear reinforcement 100 for the slab reinforcement (3) ( 100 ') construction is simple and easy, and the strength reinforcing efficiency of the slab (2) is increased.

The slab (2) constituting the reinforced concrete structure is made by slab reinforcement (3) cross-reinforced horizontally up and down, respectively, after the concrete is poured and hardened, such slab reinforcement (3) cross each other on the upper and lower sides The grid space A is formed.

Here, after the slab reinforcement (3) is constructed as described above as a shear reinforcement of the conventional column-slab joints, the stub (Stirrup: installed directly wound on the slab reinforcement (3) formed along the periphery of the column-slab joints (Stirrup: ) And shear studs that are joined between the slab reinforcing bars 3 by welding or the like, but as described above in the background art of this specification, the number of working hours is increased, which makes the construction cumbersome and increases inconvenience and working time. Caused. On the other hand, unlike the above, as a shear reinforcement of the column-slab joints installed before the slab reinforcing bar 3 is constructed, the shear head or the slab and column joints of the application No. 10-2007-0098914 filed by the present applicant There is a shear reinforcement, but also, the step of assembling the shear reinforcement, positioning the shear reinforcement to the column and the slab joint, the slab reinforcement (3) is passed through the slab reinforcement (3) between the shear reinforcement located in the column and the slab junction As the step of reinforcing the reinforcing bar (3) is necessary, the number of work is cumbersome, the construction is cumbersome, causing the inconvenience and increased working time was the same.

In order to improve this, the applicant has devised an application No. 10-2007-0131149 "shear reinforcement of the column-slab joint", such a shear reinforcement of the column-slab joint after the slab reinforcement (3) is constructed After being inserted into the lattice space (A) formed by the slab reinforcement (3) formed to cross each other to be intersected with each other to move to the side of the slab reinforcement (3) to be fixed to the slab reinforcement (3), shear reinforcement compared to the conventional Although the construction of the sieve has the advantage of ease, the step of inserting the shear reinforcement into the lattice space (A) and within the lattice space (A) by moving the shear reinforcement in the lateral direction of the slab reinforcement (3) is locked The hassle of going through two stages of letting go remained.

However, the vertically engaging shear reinforcement body 100 (100 ′) of the column-slab joint according to the present invention is formed in the vertical direction by inserting the upper space is closed in the center and the lower end in the vertical direction, as shown in FIG. As in (a) and (b) and (c), the worker lowers the shear reinforcement body 100, 100 'vertically on the upper side of the slab reinforcement 3, which is cross-rebard and completed construction. Shear reinforcement (100, 100 ') is installed to be fixed to the slab reinforcement (3). As described above, the vertically engaging shear stiffener of the column-slab joint according to the present invention is shear shear reinforced as the work of installing the shear stiffeners 100 and 100 'on the slab reinforcement 3 is performed in one operation. Construction of the sieve 100, 100 'is to be made more simply and easily than in the prior art.

In addition, the vertically engaging shear reinforcement body 100 (100 ') of the column-slab joint according to the present invention has a subframe 20 (20') having a shape symmetrical to each other with an insertion space 30 therebetween. 40, 40 'are positioned, and the pair of subframes 20, 20', 40, 40 'positioned in this manner are shear reinforcing bars 22, 22' disposed vertically, respectively. (42) (42 ') and the upper and lower ends of the shear reinforcing bars (22), 22', 42, 42 'are horizontal than the shear reinforcing bars (22), 22', 42, and 42 '. It has a shape having a top section 24, 24 ', 44, 44' and a bottom head 26, 26 ', 46, 46' with a large cross-sectional area. Vertically fastened shear stiffeners 100, 100 'of the column-slab joints embedded in the concrete to make up are a pair of subframes 20, 20' (40) with an insertion space 30 therebetween. 40 'and the upper heads 24, 24', 44, 44 'and the lower heads 26, 26' of the subframes 20, 20 ', 40 and 40' ( 46) by 46 ' Subframes 20, 20 ', 40, 40' and subframes 20, 20 'and 40, wherein the subframes 20, 20', 40, 40 'are integrally and firmly coupled, and thus the resistance to shear forces is firmly combined with the concrete. Is further augmented by upper heads 24, 24 ', 44, 44' and lower heads 26, 26 ', 46, 46'. In addition, the vertically engaging shear stiffeners 100 and 100 'of the column-slab joint according to the present invention also have upper and lower upper heads 24 and 24' with respect to the compressive force in the vertical direction with respect to the slab 2. (44) 44 'and lower heads 26, 26', 46 and 46 '.

As described above, the vertically engaging shear reinforcement body 100 (100 ') of the column-slab joint according to the present invention has a shape in which the upper and lower parts protrude in the lateral direction, and the connecting part connecting the upper and lower parts is formed vertically. First subframe 20, 20 ′ and second subframe 40, 40 ′ and such first subframe 20, 20 ′ and second subframe 40, 40 ′. It consists of a connecting piece 60, 60 'for coupling.

The first subframe 20, 20 ′ comprises a first shear reinforcing bar 22, 22 ′, a first upper head 24, 24 ′ and a first lower head 26, 26 ′. The second subframe 40, 40 ′ includes a second shear reinforcing bar 42, 42 ′, a second upper head 44, 44 ′ and a second lower head 46. (46 ').

Here, the first shear reinforcing bars 22 and 22 'and the second shear reinforcing bars 42 and 42' are formed to have a predetermined length so as to be vertically disposed with respect to the slab reinforcing bar 3. The first shear reinforcing bars 22 and 22 'of the subframes 20 and 20' and the second shear reinforcing bars 42 and 42 'of the second subframes 40 and 40' are It is preferable to be formed in the same shape and the same size with each other, which is for the structural stability of the vertically engaging shear reinforcement (100, 100 ') of the column-slab joint according to the present invention.

The first upper head 24, 24 ′ and the second upper head 44, 44 ′ are positioned horizontally on top of the shear reinforcing bars 22, 22 ′, 42, 42 ′. It has a horizontal cross-sectional area wider than the shear reinforcing bars 22, 22 ', 42 and 42', and includes a polygonal cross section including a square cross section, a flat cross section, and a pyramid or cone with an upper end cut. It may have a variety of forms, such as, the first upper head 24, 24 'of the first subframe 20, 20' and the second upper portion of the second subframe 40, 40 ' The heads 44 and 44 'are preferably formed in the same shape and the same size to provide structural stability of the shear reinforcement 100 and 100' according to the present invention.

In addition, the first lower head 26, 26 'and the second lower head 46, 46' are horizontally positioned at the lower end of the first shear reinforcing bars 22, 22 'and the shear reinforcing bars. It has a wider horizontal cross-sectional area than (22) (22 ') (42) (42'). And the first lower heads 26 and 26 'of the first subframes 20 and 20' and the second lower head 46 of the second subframes 40 and 40 '. 46 ') is preferably formed in the same shape and the same size to give the structural stability of the shear reinforcement (100, 100') according to the present invention.

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

Here, the vertically engaging shear reinforcement body 100 (100 ') of the column-slab joint according to the present invention has a first subframe 20 and a second subframe having a' c 'shape as shown in FIGS. 3 to 6. 40 may be used, wherein the first subframe 20 and the second subframe 40 having the 'c' shape are the shear reinforcing bars 22 and 42 as shown in FIGS. 3 and 4. Is formed in a narrower width than the upper head 24, 44 and the lower head 26, 46, or the shear reinforcing bars 22, 42 as shown in Figure 5 and 6 the upper head 24 ( 44 and the lower head 26 and 46 may have the same width.

On the contrary, the vertically latching shear reinforcement 100 (100 ') of the column-slab joint according to the present invention has a first subframe having an' I 'shape as shown in FIG. 20 ') and the second subframe 40' may be used. Of course, the first and second subframes having different shapes may be used.

The first subframe 20, 20 ′ and the second subframe 40, 40 ′ are each shear reinforcing bars 22, 22 ′ by casting, forging, etc. by casting. 42, 42 ', upper head 24, 24', 44, 44 ', and lower head 26, 26', 46, 46 'are integrally molded. Can be.

The first subframe 20, 20 ′ and the second subframe 40, 40 ′ are each shear reinforcing bars 22, 22 ′, 42, 42 ′, and an upper head ( 24, 24 ', 44, 44', and lower heads 26, 26 ', 46, 46' may be manufactured separately and then welded together to form a single piece.

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 first subframe 20, 20 ′ and the second subframe 40, 40 ′ according to the present invention may be manufactured.

Here, when the first subframe 20 and the second subframe 40 having a 'c' shape are used, the first subframe 20 and the second subframe 40 according to the present invention are shown in FIG. As shown in FIG. 5, the upper and lower portions 52 and 54 of the 'I' type flat plate 50 are bent at right angles, or the upper and lower portions 52 'and 54' of the rectangular flat plate 50 'as shown in FIG. 5. It is preferable that the 'c' shape bent at a right angle, the 'I' type flat plate 50 or the rectangular flat plate 50 'can be easily and easily manufactured by press working, such' I 'type Since the process of bending the upper and lower portions 52, 52 ', 54 and 54' of the flat plate 50 and the rectangular flat plate 50 'in the same direction can also be made simply and easily, the first subframe 20 And the second subframe 40 is made easy and easy to manufacture.

The first subframe 20, 20 ′ and the second subframe 40, 40 ′ according to the present invention as described above are positioned to be spaced apart from each other to form the first subframe 20, 20 ′ of the first subframe 20, 20 ′. 1 Insertion space 30 is formed in the vertical direction between the shear reinforcing bars 22 and 22 'and the second shear reinforcing bars 42 and 42' of the second subframe 40 and 40 '. do.

The upper side of the insertion space 30 is closed by the connecting pieces 60 and 60 'connecting the first subframes 20 and 20' and the second subframes 40 and 40 '. The lower side of the space 30 is open. Accordingly, the slab reinforcing bar 3 passes through the lower side of the insertion space 30 and is caught by the connecting pieces 60 and 60 'above the insertion space 30.

Here, the first subframe 20, 20 'and the second subframe 40, 40' according to the present invention is preferably located to face each other symmetrically, as shown in Figure 3 to 6 In the first subframe 20 and the second subframe 40 having a 'C' shape, the upper heads 24 and 44 and the lower heads 26 and 46, respectively, are formed in the outward direction of the insertion space 30. Positioned so as to face each other.

In addition, the first subframe 20 and the second subframe 40 having a 'c' shape may have a gap between the shear reinforcing bars 22 and 42 constituting the side of the insertion space 30. It is preferable to make it equal to the thickness of the slab reinforcement (3), which is to ensure that the shear reinforcement (100) according to the present invention is firmly and stably locked to the slab reinforcement (3).

The connecting pieces 60 and 60 'according to the present invention are for coupling the first subframes 20 and 20' and the second subframes 40 and 40 'which are spaced apart from each other. 60, both ends are fixed to the first subframe 20, 20 'and the second subframe 40, 40'.

Here, the shear reinforcement body 100, 100 'according to the present invention can use a variety of forms of connecting pieces 60, 60', connecting pieces 60 made of a flat form as shown in Figures 3 to 7 ) May be used, or a connecting piece 60 'made of a clip form as shown in FIG. 8 may be used.

As shown in FIGS. 3 to 7, the connecting piece 60 having a flat plate shape includes first upper heads 24 and 24 ′ of the first subframes 20 and 20 ′, and second subframes 40 and 40. Both ends are fixed to the second upper heads 44 and 44 'by spot welding or the like, and the connecting piece 60 having a flat plate shape is formed so that smooth spot welding can be performed. Both ends of the connecting piece 60 may have a length corresponding to the length from the outer end of the upper head 24, 24 ′ to the outer end of the second upper head 44, 44 ′. It is desirable to be positioned at the outer end of 24) (24 ') and the outer end of second upper head (44) (44').

On the contrary, as shown in FIG. 8, the connecting piece 60 ′ having a clip shape has a pair of locking jaws 64 ′ formed therebetween with open grooves 62 ′ corresponding to the insertion space 30 at both ends of the bottom. The connecting piece 60 'is formed of the first upper head 24, 24' of the first subframe 20, 20 'and the second subframe 40, 40'. Lowering from the upper side of the second upper heads 44 and 44 'and locking projections 64' to the bottom of the first upper heads 24 and 24 'and the bottom of the second upper heads 44 and 44'. ) Is locked so that the first subframe 20 (20 ') and the second subframe 40 (40') are coupled to each other.

Unlike the above, of course, a bar or block type connecting piece may be used. In addition, unlike the embodiment of the present invention, the connecting piece is formed of the first shear reinforcing bars 22 and 22 'of the first subframe 20 and 20' and the second subframe 40 and 40 '. 2 may be fixed to the upper side of the shear reinforcing bar (42, 42 ').

The connecting pieces 60 and 60 'according to the present invention cross the upper side of the insertion space 30 formed between the first subframe 20, 20' and the second subframe 40, 40 '. The upper side of the insertion space 30 is closed as it is installed. Thus, the slab reinforcement (3) passes through the insertion space 30 of the shear reinforcement (100, 100 ') according to the present invention that the worker is vertically lowered on the upper side of the slab reinforcement (3) that is intersected with each other to be reinforced ) Will be caught by the connecting piece 60 (60 ').

Vertical fastening type shear reinforcement (100) (100 ') of the column-slab joint according to the present invention configured as described above is further provided with a guide plate 80 of a predetermined length as shown in Figs. As the bottom surface of the plate 80, the connecting pieces 60 and 60 'of the shear reinforcement 100 and 100' according to the present invention are attached at predetermined intervals so that a plurality of shear reinforcement 100 and 100 'are integrated. As such, when a plurality of shear reinforcements 100, 100 'are attached to the guide plate 80, the storage, movement, and installation can be made more easily and quickly. The construction time of the shear reinforcement (100, 100 ') has the effect of shortening.

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. 10. Such through holes 82 are sheared at the column-slab joint according to the present invention. The connecting pieces 60 and 60 'of the reinforcement 100 and 100' may be used as a welded portion. That is, the connecting pieces 60 and 60 'of the shear reinforcement 100 and 100' of the pillar-slab joint of the present invention are brought into close contact with the bottom surface of the guide plate 80 at the portion where the through hole 82 is formed. After the solvent or welder is brought close to the through hole 82, the guide plate 80 and the connecting pieces 60 and 60 'of the shear reinforcement 100 and 100' of the column-slab joint according to the present invention are welded. It is. 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 Since the concrete is connected to the through hole 82, the shear reinforcement body 100, 100 'of the pillar-slab joint according to the present invention attached to the guide plate 80 and the guide plate 80 is more firmly slab ( 2) is buried in the concrete to perform a shear reinforcement function for the slab (2).

As described above, the vertically engaging shear reinforcement of the column-slab joint according to the embodiment of the present invention has been shown in accordance with the above description and drawings, but this is merely described for example and does not depart from the spirit of the present invention. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope.

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

Figure 2 (a) and (b) and (c) is a view for showing the technical concept of the vertically engaging shear stiffener of the column-slab joint according to the present invention;

Figure 3 (a) is an exploded perspective view of the vertically engaging shear reinforcement of the column-slab joint according to an embodiment of the present invention;

Figure 3 (b) is a perspective view of the coupling of the vertically engaging shear reinforcement of the column-slab joint according to an embodiment of the present invention;

Figure 3 (c) is a cross-sectional view of the vertically engaging shear stiffener of the column-slab joint according to an embodiment of the present invention;

Figure 3 (d) is a plan view of the vertically engaging shear stiffener of the column-slab joint according to an embodiment of the present invention;

4 is a view illustrating an embodiment of a first subframe and a second subframe constituting a vertically engaging shear reinforcement of a column-slab joint according to an embodiment of the present invention;

5 is a view illustrating an embodiment of a first subframe and a second subframe constituting a vertically engaging shear stiffener of a column-slab joint according to another embodiment of the present invention;

6 is a perspective view of a vertically engaging shear reinforcement of a column-slab joint according to another embodiment of the present invention;

Figure 7 (a), (b), (c) is a view for showing the vertically engaging shear reinforcement of the column-slab joint according to another embodiment of the present invention;

(A) and (b) of FIG. 8 show a state in which the first subframe and the second subframe constituting the vertically engaging shear reinforcement of the column-slab joint according to the present invention are joined by a clip-shaped connecting piece. Drawings for giving;

9 (a) and 9 (b) show a state in which a vertically engaging shear stiffener of a column-slab joint according to the present invention is attached to a guide plate at a predetermined interval so as to use a plurality of shear stiffeners integrally. Drawing for;

10 (a) and (b) is a view for showing a state in which the vertically engaging shear stiffener of the column-slab joint according to the present invention is attached to the guide plate formed with a through hole;

11 is a view showing a state in which the vertically engaging 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: Slab rebar A: Grid space

20, 20 ': first subframe 22, 22': first shear reinforcing bar

24, 24 ': first upper head 26, 26': first lower head

30: insertion space 40: second subframe

42, 42 ': second shear reinforcing bar 44, 44': second upper head

46, 46 ': 2nd lower head 50:' I 'type plate

52: upper part 54: lower part

60: connecting piece 80: guide plate

82: through hole 100: vertically engaging shear reinforcement

Claims (3)

Shear reinforcement of column-slab joints installed vertically to the slab reinforcement (3) which is horizontally reinforced at the site where the column (1) and the slab (2) forming the reinforced concrete structure are joined to each other, thereby increasing the resistance to shear failure In the sieve, The first shear reinforcing bars 22 and 22 'and the first shear reinforcing bars 22 and 22' formed to have a predetermined length so as to be disposed perpendicularly to the slab reinforcing bar 3. First upper heads 24 and 24 ′ horizontally positioned at the top and having a horizontal cross-sectional area wider than the first shear reinforcing bars 22 and 22 ′, and the first shear reinforcing bars 22 ( A first subframe (20) consisting of first lower heads (26) and (26 ') having a horizontal cross-sectional area that is horizontally positioned at the bottom of the 22 ' 20 '; The second shear reinforcing bars 22 and 22 'formed to have a predetermined length so as to be perpendicular to the slab reinforcing bar 3, and the second shear reinforcing bars 42 and 42'. Second upper heads 44 and 44 'horizontally positioned at the top and having a horizontal cross-sectional area wider than the second shear reinforcing bars 42 and 42', and the second shear reinforcing bars 42 ( And a second lower head 46, 46 'horizontally positioned at the bottom of the second lower reinforcing bar 42, 42' and having a horizontal cross-sectional area larger than that of the second shear reinforcing bars 42, 42 '. Second subframes (40) (40 ') spaced apart from each other (20) (20') such that an insertion space (30) is formed between the first subframe (20) and 20 '; Both ends are fixed to both sides of the first subframe 20, 20 ′ and the second subframe 40, 40 ′ spaced apart from each other, so that the first subframe 20, 20 ′ and the second subframe are fixed. 40 and 40 ', and the insertion space 30 across the insertion space 30 between the first subframe 20, 20' and the second subframe 40, 40 '. Including a connecting piece 60 (60 ') to close the top of the, After the slab reinforcing bar 3 is installed, the slab reinforcing bar 3 through which the connecting piece 60, 60 'passes through the insertion space 30 by being vertically lowered from the upper side of the slab reinforcing bar 3 and installed. Vertical fastening type shear reinforcement of the pillar-slab joint, characterized in that the fastening to be fixed. The method of claim 1, The first subframe 20, 20 ′ and the second subframe 40, 40 ′ are any one selected from a 'c' shape and an 'I' shape. The connecting piece (60) (60 ') is a vertically engaging shear reinforcement of the column-slab joint, characterized in that any one selected from the one consisting of a flat plate and a clip. The method of claim 2, The first subframe 20, 20 ′ and the second subframe 40, 40 ′ have a 'c' shape, and upper and lower portions 52, 54 of the 'I' type flat plate 50 are formed. A pillar, characterized in that it is any one selected from the form of a 'c' bent at right angles and the upper and lower portions 52 'and 54' of a rectangular flat plate 50 'bent at a right angle to form a' c'- Vertically engaging shear stiffeners at slab joints.

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