KR20140070267A - Precast concrete slab having horizontal shear connecting member of solid body type, and method for the same - Google Patents

Abstract

Provided are a precast concrete slab with a solid horizontal shear connecting member and a method for constructing the same capable of preventing a relative sliding motion on a concrete interface of the precast concrete slab caused by horizontal shear force by using a solid horizontal shear connecting member processed with a steel wire or a reinforced bar; increasing resistance to vertical shear force in an end part of a PC slab more than the conventional vertical type horizontal shear connecting member by using the solid horizontal shear connecting member; easily corresponding to the vertical shear force increased by controlling the thickness and the angle of the solid horizontal shear connecting member; having excellent economic feasibility compared to the conventional continuous lattice shear connecting member; and increasing construction performance compared to the conventional hook type shear connecting member by omitting a binding wire.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a precast concrete composite slab having a three-dimensional horizontal shear connector and a method of constructing the composite slab.

The present invention relates to a precast concrete composite slab, and more particularly, to a horizontal shear connecting member manufactured as a solid body as a horizontal shear connection material of a precast concrete (PC) composite slab, The present invention relates to a precast concrete composite slab and a construction method thereof.

Generally, when a building is formed of a repetitive planar module, a hollow core slab, a double T slab, a multi ribbed slab, and a reverse direction slab are used in consideration of economy and workability. And PC slab systems such as Inverted Multi Ribbed Slab are frequently applied.

For example, PC slabs are standardized precast concrete slabs that are manufactured in large quantities in the factory using metal forms, and these PC slabs have a bottom plate and a rib integrally formed, or a plurality of Since it is a hollow structure with ribs, it is light and has high rigidity and is used as a ceiling member of a wide prefabricated structure.

On the other hand, parking lots of buildings such as large shops and factories are constructed with reinforced concrete structures that are mostly used for formwork, reinforced concrete, and concrete. Such reinforced concrete structures have cracks due to the characteristics of materials, .

In order to solve this problem, a double T slab method is recently used. Referring to FIGS. 1A and 1B, the double T slab method will be described as follows.

1A and 1B are a perspective view and a front view, respectively, of a double T slab according to a conventional technique.

1A and 1B, a double tee slab construction 10 according to the related art has a structure in which pillars 11 are installed on a bottom plate so as to be spaced apart from each other by a predetermined distance, 1B, the beam 12 and the double-tee slab 13 are fitted with the double-tee slab 13 in a state where the beam 12 is seated, 14 are laid to form a slab layer.

A slab layer is formed on the double slab concrete structure 10 by slab concrete 14 placed in a state of being seated on the beam 12 or the slab of the slab 11, The beam 12 is not integrally formed, and the double tee slab 13 is designed as a simple beam.

FIG. 2 is a perspective view of a PC slab in which a lattice reinforcing bar is formed according to a conventional technique.

Referring to FIG. 2, the PC slab 50 formed with the lattice reinforcing bars according to the related art is formed such that the upper portion of the lattice reinforcing bar 55 is exposed on the upper surface 56. The PC slab 50 is secured to the lattice reinforcing slab concrete And a plurality of lifting iron pieces 51 and 52 are formed on the upper surface.

The PC slab 50 having the lattice reinforcing bars formed therein is provided with a pair of lower reinforcing bars 53 (truss reinforcing bars) extending in the longitudinal direction and spaced apart from each other, And a connecting wire 55 extending continuously in a wave form between the lattice bar 54 and the lower reinforcing bar 53. [ At this time, the upper part of the connecting wire 55 and the lattice bar 54 are exposed upward from the upper surface to ensure the integrity with the slab concrete.

However, since the thickness of the upper plate of the double tee slab is very thin, there is a problem that it is practically impossible to embed the lattice reinforcement of the PC slab 50. [

In addition, in the case of the connecting wire 55, there is a problem that it is difficult to control the shear crack as well as the amount of material required for the connecting wire 55 due to the angle formed at an angle to the shearing crack of the PC slab 50.

3A and 3B are photographs showing a lattice-type shear reinforcement and a 90-degree hook-type shear reinforcement continuously arranged over the entire span of a PC slab according to a conventional technique.

Excessive shear connectors are used for the integrated behavior between the PC slab and the pouring concrete according to the prior art. For example, the same roots are applied irrespective of the structural conditions in the production of the PC slabs according to the conventional technique, and also the lattice-like shear reinforcing bars 60 shown in Fig. 3A or the lattice- The 90-degree hook-type sheathed reinforcing bars 70 are continuously arranged, so that the cost specific gravity rises.

1) Korea Patent No. 10-1175525 filed on Mar. 6, 2012, entitled " PC Slab Manufacturing Method and Construction Method and Structure " 2) Korea Patent No. 10-1079267 filed on Apr. 22, 2009, entitled "T-type PC slab and its construction method" 3) Korean Patent No. 10-1152270 filed on Feb. 2, 2012, entitled "PC slab suitable for long span high-strength building & 4) Korean Patent No. 10-1036748 filed on December 31, 2009, entitled "Multi-ribbed PC slab" 5) Korean Laid-Open Patent No. 2009-50520 (published on May 20, 2009), entitled " 6) Korean Unexamined Patent Application No. 2012-36616 (Publication date: April 18, 2012), entitled "Synthetic bottom plate using a reinforcing material formed by a corrugated bent plate and method of making the same" 7) Korean Registered Patent No. 10-1200564 filed on Oct. 8, 2010, entitled "Synthetic bottom plate using reinforcing material formed by corrugated bent plate and vertical connecting plate, and synthetic bottom plate using the same "

In order to solve the above-mentioned problems, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a concrete slab having a relatively slippery behavior due to a horizontal shear force at a concrete interface of a precast concrete composite slab by using a three- The present invention provides a precast concrete composite slab having a three-dimensional horizontal shear connector and a method of constructing the composite slab.

Another object of the present invention is to provide a vertical shear joint having a horizontal shear joint at 90 degrees (horizontal) and 45 degrees (inclined shear) And a method of constructing the composite slab and a method of constructing the composite slab.

Another object of the present invention is to provide a precast concrete composite with a cubic horizontal shear joint which can easily cope with increasing vertical shear force by adjusting the diameter and connecting angle (tilt angle) Slab and a construction method thereof.

Another object of the present invention is to provide a precast concrete composite slab having a shear connection reinforced by a steel wire or a reinforced concrete and a shear coater formed by a concavo-convex shear coater on the surface of a PC slab, The present invention provides a precast concrete composite slab having a three-dimensional horizontal shear connector and a method of constructing the composite slab.

According to an aspect of the present invention,

In a Precast Concrete Slab (PC slab) having a horizontal shear connector, the horizontal shear connector

A low profile steel bar arranged in the longitudinal direction; A three-dimensional horizontal shear connection member in which the vertical roots and the oblique roots are repeatedly bent so as to surround the lower reinforcing bars to be stereoscopic; And a flat plate portion formed by pouring concrete so as to expose an upper portion of the three-dimensional horizontal shear connector in a state where the low-shear reinforcing bar and the three-dimensional horizontal shear connector are combined.

Also preferably,

In a construction method of a precast concrete slab (PC slab)

a) constructing a column;

b) installing a beam using the steps of the column;

c) disposing the beam so that the bottom of the PC slab with the cubic horizontal shear connector is supported; And

d) forming a slab layer on the PC slab having the three-dimensional horizontal shear connector and the slab concrete on the top of the beam,

Wherein the PC slab having the three-dimensional horizontal shear connector comprises:

A low-profile reinforcing bar disposed in this direction;

A three-dimensional horizontal shear connection member in which the vertical roots and the oblique roots are repeatedly bent so as to surround the lower reinforcing bars to be stereoscopic; And

And a flat plate portion formed by placing concrete so as to expose an upper portion of the three-dimensional horizontal shear connector in a state where the low-shear reinforcing bar and the three-dimensional horizontal shear connector are coupled to each other, and a three-dimensional horizontal shear connector, to provide.

Also preferably,

And a three-dimensional horizontal shear connection member disposed on the upper portion of the three-dimensional horizontal shear connection member so as to further form a vertical reinforcing bar disposed between the horizontal and oblique rods in a lengthwise direction, the reinforcing bar being repeatedly bent in the longitudinal direction, A composite slab and a construction method thereof are provided.

Also preferably,

The three-dimensional horizontal shear connector has a slope extending from a horizontal line extending horizontally in the longitudinal direction at an upper end of the vertical line, a lower line reinforced at a lower end of the slanted line formed by inclining, The present invention provides a precast concrete composite slab and a method of constructing the composite slab, wherein the vertical slab is formed by repeatedly bending the vertical roots, the horizontal roots and the inclined roots.

Also preferably,

The present invention provides a precast concrete composite slab having a three-dimensional horizontal shear connector formed by pressing a steel rod or a wire having the same diameter as the vertical roots, the horizontal roots and the inclined roots, and a construction method thereof.

Also preferably,

Wherein the three-dimensional horizontal shear connector is formed by adjusting the diameter of the vertical roots, the horizontal roots and the oblique roots, and the angle of inclination, which is the connection angle between the horizontal roots and the oblique roots, and a method of constructing the precast concrete composite slab .

Also preferably,

The three-dimensional horizontal shear connector is characterized in that the three-dimensional horizontal shear connectors are formed so that the three-dimensional horizontal shear connectors having the same vertical angle, the diameter of the horizontal roots and the oblique roots, A concrete composite slab and a method of constructing the same are provided.

Also preferably,

Wherein the three-dimensional horizontal shear connector has a three-dimensional horizontal shear connector for forming other three-dimensional horizontal shear connectors that are different from each other in the perpendicular direction, the diameter of the horizontal roots and the angular roots, and the angle of inclination A precast concrete composite slab and a construction method thereof are provided.

According to the present invention, by using a three-dimensional horizontal shear connector fabricated by using a wire or a reinforcing bar, it is possible to prevent a relatively slip behavior due to a horizontal shear force at a concrete interface of a precast concrete composite slab.

According to the present invention, the resistance to vertical shear force at the end of the PC slab can be improved by using a stereolithic horizontal shear connection material than the conventional horizontal shear connection material.

According to the present invention, it is possible to easily cope with an increasing vertical shearing force by adjusting the diameter and connecting angle of the horizontal shear connector to be subjected to stereolithography.

According to the present invention, the horizontal shear strength, which may be insufficient only by the shear connection reinforcing bars, can be reinforced through the shear coater, thereby reducing the amount of shear connecting reinforcing bars.

1A and 1B are a perspective view and a front view, respectively, of a double T slab according to a conventional technique.
2 is a perspective view of a PC slab in which a lattice reinforcing bar is formed according to a conventional technique.
FIGS. 3A and 3B are photographs showing lattice-type shear reinforcing bars and 90-degree hook-type shear reinforcing bars continuously arranged over the entire span of the PC slabs according to the prior art.
FIGS. 4A, 4B and 4C are views showing a three-dimensional horizontal shear connector of a precast concrete composite slab according to the first, second, and third embodiments of the present invention.
5A and 5B are a perspective view and a bottom perspective view of a PC slab having a shear connection reinforcing bar and a shear coater according to a first embodiment of the present invention, respectively.
6 is a front view of a PC slab having a shear connection reinforcing bar and shear coater according to a first embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

[Precast concrete composite slab with three-dimensional horizontal shear connector according to an embodiment of the present invention (PC slab)]

4A, a three-dimensional horizontal shear connector 110 of a precast concrete slab (PC slab) according to the first embodiment of the present invention includes a vertical rope 111, a horizontal rope 113 And the oblique roots 112 are repeatedly bent so as to prevent the relative slip behavior due to the horizontal shear force at the concrete interface and increase the resistance performance against the vertical shear force.

The three-dimensional horizontal shear connector 110 is formed by repeatedly bending the vertical roots 111, the horizontal roots 113 and the oblique roots 112 in the longitudinal direction.

At this time, a lower reinforcing bar 120a is installed at the lower end of the three-dimensional horizontal shear connector 110, and an upper reinforcing bar 120b is provided at the upper end so as to extend in the longitudinal direction.

In this case, the vertical roots 111 of the three-dimensional horizontal shear connector 110 are reinforcing bars to resist vertical load, and the oblique roots 112 are inclined at a predetermined inclination angle? In the diagonal direction above the vertical rods 111, , It may be formed by being bent at an angle of 30 to 60 degrees, preferably 45 degrees. The horizontal roots 113 above the vertical roots 111 are reinforcing bars formed between the vertical roots 111 and the oblique roots 112 to resist horizontal loads.

The inclined angle 112 is formed to be perpendicular to the sinusoidal crack due to the load acting on the precast concrete composite slab in the inclination angle and the extension direction. 45 angles.

As a result, the oblique roots 112 are extended downwardly in the longitudinal direction of the three-dimensional horizontal shear connector 110 from the horizontal roots 113 above the vertical roots 111, The horizontal roots 113 and the oblique roots 112 are continuously formed in the extending direction of the precast concrete composite slabs.

The three-dimensional horizontal shear connector 110 is manufactured such that a reinforcing bar, a wire or the like is arranged in a straight line, and then a vertical bar, a horizontal bar and an inclined bar are integrally bent in a press. .

Therefore, the efficiency and economical efficiency of fabrication can be sufficiently secured in comparison with the conventional horizontal shear connector.

The lower reinforcing bars 120a are installed at the lower reinforcing bars 120a and the lower reinforcing bars 120a so that the lower reinforcing bars 120a are connected to the lower reinforcing bars 120a. So that the lower reinforcing bar 120a is formed to penetrate the lower portion of the reinforcing bar 112 in the longitudinal direction.

The lower rebar 120a is formed to extend in the longitudinal direction below the three-dimensional horizontal shear connector 110.

The reinforcing bars 120b may be further provided to secure the upper and lower ends of the three-dimensional horizontal shear connector 110 in the longitudinal direction. The reinforcing bars 120b may be provided on the upper portion of the three- , And may be arranged in the longitudinal direction by being in contact with the horizontal muscle and the oblique muscle.

At this time, the vertical roots 111, the horizontal roots 113, and the oblique roots 112 may be formed by pressing a reinforcing bar or a wire having the same diameter. (Related to claim 4)

However, the three-dimensional horizontal shear connector 100 has a vertical slope 111, a horizontal slope 113 and an inclined slope 112, and a slope angle, which is a connection angle between the horizontal slope and the slope root, corresponding to the vertical shear force of the PC slab So that various resistance performance against the vertical shear force can be adjusted and secured (related to claim 5).

4A and 4B, the three-dimensional horizontal shear connector 110a of the precast concrete slab (PC slab) according to the second embodiment of the present invention has a height h, And the other three-dimensional horizontal shear connectors 110b are arranged so as to overlap each other between the right and the medial muscles with a pitch b between the rectus and the medial muscles.

Typically, the three-dimensional horizontal shear connectors 110 are disposed within the ribs of the precast concrete composite slabs. In the case of long-span precast concrete composite slabs, the amount of installation of the three-dimensional horizontal shear connectors 110 must be increased.

However, in order to increase the installation amount, the conventional method of increasing the diameter of the reinforcing bar or the wire used for manufacturing the three-dimensional horizontal shear connector 110 has been used.

4B, the three-dimensional horizontal shear connectors 110 using reinforcing bars and wires are overlapped with each other in the longitudinal direction.

As a result, it can be understood that the spacing between the vertical roots 111, the horizontal roots 113, and the oblique roots 112 is very narrow. By this effect, the installation amount of the three-dimensional horizontal shear connector 110 is increased will be.

In addition, using this method, the space occupied by the three-dimensional horizontal shear connector 110 is not large, which makes it possible to arrange the three-dimensional horizontal shear connector 110 very efficiently.

Accordingly, the three-dimensional horizontal shear connector 100 may be formed in a shape corresponding to the vertical shear force of the PC slab, such that the vertical three-dimensional horizontal shear connectors having the same diameter as the horizontal roots and the inclined roots The composite slab may be formed of a precast concrete composite slab having three-dimensional horizontal shear connectors formed to overlap with each other (relating to claim 6)

4A and 4C, the three-dimensional horizontal shear connector 110a of the precast concrete slab (PC slab) according to the third embodiment of the present invention includes the three-dimensional horizontal shear connector 110a, It can be seen that the reinforcing bars 110a and 110b can be formed using reinforcing bars or wires having different diameters.

That is, the three-dimensional horizontal shear connector 100 has different vertical three-dimensional horizontal shear connectors, which differ in the diameter of the vertical roots and the vertical roots and the inclination angles, which are the connecting angles between the horizontal roots and the oblique roots, corresponding to the vertical shear force of the PC slab The composite slab can be formed as a precast concrete composite slab having three-dimensional horizontal shear connectors formed to overlap with each other.

4A and 4B, unlike the three-dimensional horizontal shear connector 110a described above, the three-dimensional horizontal shear connector 110c has a diameter d _b and an inclination angle d _b corresponding to the vertical shear force of the PC slab (?) can be controlled.

When the three-dimensional horizontal shear connectors 110a and 100c have different diameters, the three-dimensional horizontal shear connectors having different diameters are used, so that a desired installation amount can be precisely adjusted.

Also, if the diameters are different, the placement of the three-dimensional horizontal shear connectors 110a and 100b becomes very easy.

In addition, the inclination angle of the inclined roots extending from the horizontal roots is closely related to the cracks of the precast concrete composite slab. However, it is not easy to predict exactly how the directions of these cracks will be formed.

As in the case of the third embodiment, unlike the three-dimensional horizontal shear connector 110a in which the inclination angles of the inclined roots 112 are different in consideration of uncertainty such as direction, the three-dimensional horizontal shear connector 110c is used. Thus, it is possible to provide more efficient precast concrete composite slabs.

Meanwhile, the precast concrete composite slab 100 having three-dimensional horizontal shear connectors according to the first, second, and third embodiments of the present invention may include the three-dimensional horizontal shear connector 110 and the flat plate 130 have.

4A, 4B and 4C, and the flat plate part 130 is formed of a concrete pouring body. The three-dimensional horizontal shear connector 110 shown in FIGS.

Specifically, the flat plate part 130 acts as a concrete pouring body for pouring slab concrete, and is synthesized integrally with a subsequently inserted slab concrete to form a composite bottom plate.

Since the flat plate portion 130 is formed of a thin plate, a reinforcing bar or a wire mesh can be laid to reinforce the flexure, and a tension member composed of a PS steel bar or a PS strand can be disposed Prestress may be introduced.

At this time, the portion protruding from the upper surface of the flat plate part 130 is resistant to the horizontal shear force, and the part buried in the stem part of the flat plate part 130 is a part of the diagonal crack It is possible to effectively suppress the occurrence of such a phenomenon. Here, the diagonal tension is the main tensile stress generated in the beam by the combination of the normal stress and the horizontal stress, and the crack in the sagittal plane is a sloped crack, for example, Refers to the inclination of about 45 degrees with respect to the member axis.

The ribs may be formed on the upper surface of the flat plate 130 at regular intervals over the entire length in the longitudinal direction or the width direction of the flat plate 130. Accordingly, the rigidity of the flat plate part 130 can be reinforced, and the bottom plate can be made long-span without significantly increasing its own weight. At this time, the cross-sectional shape of the rib portion may be a rectangular shape, but is not limited thereto and may be formed into various cross-sectional shapes. Further, a reinforcing bar or a steel wire corresponding to the tensile force may be disposed on the rib portion so as to correspond to the upper tensile force due to the introduction of the prestress.

It can be seen that the three-dimensional horizontal shear connector 110 is arranged in a vertical plane on the rib portion.

As a result, the PC slab 100 having a three-dimensional horizontal shear connector according to an embodiment of the present invention can be manufactured by using the three-dimensional horizontal shear connector 110 fabricated using a wire or a reinforcing bar, It is possible to prevent a relatively slip behavior by the horizontal shear force at the concrete interface.

The PC slab 100 having the cubic horizontal shear connector according to the embodiment of the present invention can easily cope with the increasing vertical shear force by adjusting the straightness and the connecting angle of the cubic horizontal shear connector.

[Three-dimensional horizontal shear connector 110 of the present invention and PC slab 100a having shear coater]

5A and 5B are perspective and bottom perspective views, respectively, of a PC slab having a three-dimensional horizontal shear connector and shear coater according to a first embodiment of the present invention.

The three-dimensional horizontal shear connector 110 will be described with reference to FIG. 4A.

5A and 5B, a PC slab 100a having a three-dimensional horizontal shear connector and a shear coater according to the first embodiment of the present invention includes a lower rebar 120a, a three-dimensional horizontal shear connector 110, Section 130 and a shear cutter 140, and the presenting wire 120b shown in FIG. 4A described above may be omitted.

 The three-dimensional horizontal shear connector 110 is as shown in FIG. 4A. The lower reinforcing bars 120a are arranged in the longitudinal direction at the lower portion of the flat plate portion. The present reinforcing bars 120b are arranged in the longitudinal direction at the upper portion of the flat plate portion.

At this time, the vertical roots of the three-dimensional horizontal shear connector 110 are bent 90 degrees so as to surround the lower reinforcing bar 120a and are coupled to the shear coater 140, and the inclined roots of the three- And is bent at an inclination angle of 30 degrees to 60 degrees from the horizontal muscle of the upper portion of the medial rectus.

The shear cutter 140 is roughly machined at the surface of the flat plate 130 and joined with the vertical roots of the three-dimensional horizontal shear connector 110 to form the three-dimensional horizontal shear connector 110 Together, reinforce the horizontal shear strength. At this time, the shear coater 140 is formed into a elliptical shape so as to increase the upper surface area of the slab layer flat part 130, thereby increasing the horizontal crack generation path, thereby increasing the horizontal shear resistance performance.

The flat plate portion 130 is a concrete pouring body and is formed by placing the concrete in a state where the lower reinforcing bar 120a, the three-dimensional horizontal shear connector 110 and the shear cutter 140 are coupled.

Specifically, the flat plate part 130 acts as a concrete pouring body for pouring over concrete, and is integrally combined with a laterally placed overwintered concrete (slab concrete) to form a composite bottom plate.

Since the flat plate portion 130 is formed of a thin plate, a reinforcing bar or a wire mesh can be laid to reinforce the flexure, and a tension member composed of a PS steel bar or a PS strand can be disposed Prestress may be introduced.

The PC slab 100a having a shear connection reinforcing bar and a shear coater according to an embodiment of the present invention includes a three-dimensional horizontal shear connector 110 processed using a wire or a reinforcing bar and a shear coater 140 It is possible to prevent the slip behavior of the precast concrete composite slab 100a due to the horizontal shear force at the concrete interface.

The PC slab 100a having the shear connection reinforcing bar and the shear coater according to the embodiment of the present invention can be manufactured by using the horizontal shear connection material 110, which is repeatedly formed by 90 degrees and 45 degrees, The resistance to vertical shear force at the end of the PC slab 100a can be improved more than the vertical horizontal shear connection of the PC slab 100a.

The PC slab 100a having the shear connection reinforcing bars and the shear coater according to the embodiment of the present invention is more economical than the conventional continuous lattice shear connection member and omits the bundling operation, The workability can be improved.

[Method of constructing the three-dimensional horizontal shear connector 110 of the present invention and the PC slab 100a having the shear coater]

6 is a front view of the construction of a PC slab having the three-dimensional horizontal shear connector 110 and the shear coater 140 of the present invention.

6, a method of constructing the PC slab 100a having the three-dimensional horizontal shear connector 110 and the shear coater 140 according to the present invention includes the steps of constructing the column 200, So that the beam 300 is installed.

Then, the bottom of the PC slab 100a having the three-dimensional horizontal shear connector 110 and the shear coater 140 of the present invention is disposed in the beam 300 to be supported. Specifically, the PC slab includes a lower reinforcing bar 120a disposed at a lower portion of the flat plate portion in the longitudinal direction; The vertical horizontal shear is formed by repeatedly bending the vertical roots and the oblique roots such that the horizontal rope 120a is wrapped around the vertical roots 120a so as to prevent relative slip behavior due to the horizontal shear force at the concrete interface, A coupling member 110; A shear coater 140 which is corrugated and worked on the surface of the flat plate portion and is joined to the vertical roots of the shear connection reinforcing bars to reinforce the horizontal shear strength together with the shear connection reinforcing bars; And a flat plate part 130 which is a concrete pouring body formed by pouring concrete in a state where the lower reinforcing bar 120a, the three-dimensional horizontal shear connector 110 and the shear cotter 140 are coupled to each other. At this time, the rectilinear muscle of the three-dimensional horizontal shear connector 110 is bent at 90 degrees so as to surround the rear reinforcing bar, and is coupled to the shear coater 140, and the inclined roots of the three- At an angle of 30 to 60 degrees.

The PC slab 100a having the shear connection reinforcing bars and the shear coater according to the first embodiment of the present invention penetrates the connection reinforcing bars 170 to the annular reinforcing bars 160 of the PC slabs 100a, ) Can be secured.

Next, slab concrete 400 is placed on top of the PC slab 100a having the three-dimensional horizontal shear connector 110 and the shear coater 140 of the present invention and the beam 300 to form a slab layer. At this time, the slab concrete 400 is put together with the connection part of the PC slab 100a having the column 200 and the beam 300, the three-dimensional horizontal shear connector 110 according to the present invention and the shear cotter 140, .

100: PC slab
110, 110a, 110b, 110c: three-dimensional horizontal shear connector
120a:
120b:
130:
140: Reinforcing bars
150: connection reinforcing bar
200: Column
300: Bo
400: slab concrete

Claims (13)

In a precast concrete slab (PC slab) having horizontal shear connectors,
The horizontal shear connector
A downstream rebar 120a disposed in the longitudinal direction;
A cubic horizontal shear connector 110 in which the vertical roots 111 and the oblique roots 112 are repeatedly bent so as to surround the lower reinforcing bars to be cubic; And
And a flat plate part 130 formed by placing concrete such that the upper part of the cubic type horizontal shear connector is exposed in a state where the lower reinforcing bar 120a and the cubic horizontal shear connector 110 are coupled to each other. Precast Concrete Composite Slab with Shear Connectors. The method according to claim 1,
The vertical reinforcing bars 120b are disposed on the upper portion of the three-dimensional horizontal shear connector 110 so as to be in contact with the horizontal roots and the oblique roots in the longitudinal direction. Precast Concrete Composite Slab with Three - Dimensional Horizontal Shear Connectors. The method according to claim 1,
The three-dimensional horizontal shear connector 110 includes an inclined root 112 extending obliquely from a horizontal root 113 extending horizontally in the longitudinal direction at an upper end of the vertical stem 111, And the horizontal and vertical roots are repeatedly bent so that the rectilinear muscles extend upward from the wrapped oblique roots so as to be bent repeatedly. The method of claim 3,
Wherein the vertical roots (111), the horizontal roots (113), and the oblique roots (112) are formed by pressing a reinforcing bar or a wire having the same diameter by press working. The method of claim 3,
Wherein the three-dimensional horizontal shear connector 110 is formed by adjusting the diameter of the vertical roots, the horizontal roots and the oblique roots, and the angle of inclination, which is the connection angle between the horizontal roots and the oblique roots. Concrete composite slabs. The method of claim 3,
Wherein the three-dimensional horizontal shear connectors 110 are formed so that the three-dimensional horizontal shear connectors 110, which are the same as the connecting angles of the vertical roots, the horizontal roots and the oblique roots, and the connecting angles of the vertical roots and the oblique roots, Precast Concrete Composite Slab with Shear Connectors. The method according to claim 1,
The three-dimensional horizontal shear connector 110 is formed so that the three-dimensional horizontal shear connectors 110, 120, 130, 130, 130, 130, 130, Precast Concrete Composite Slab with Three - Dimensional Horizontal Shear Connectors. In a construction method of a precast concrete slab (PC slab)
a) constructing a column;
b) installing a beam using the steps of the column;
c) disposing the beam so that the bottom of the PC slab with the cubic horizontal shear connector is supported; And
d) forming a slab layer on the PC slab having the three-dimensional horizontal shear connector and the slab concrete on the top of the beam,
Wherein the PC slab having the three-dimensional horizontal shear connector comprises:
A low-profile reinforcing bar disposed in this direction;
A three-dimensional horizontal shear connection member in which the vertical roots and the oblique roots are repeatedly bent so as to surround the lower reinforcing bars to be stereoscopic; And
And a flat plate portion formed by placing concrete so that an upper portion of the three-dimensional horizontal shear connector is exposed in a state where the low-shear reinforcing bar and the three-dimensional horizontal shear connector are combined. 2. The precast concrete composite slab according to claim 1, . 9. The method of claim 8,
The horizontal and vertical roots of the PC slab having the three-dimensional horizontal shear connector 110 are formed by pressing a reinforcing bar or a wire having the same diameter by press working. Construction method of concrete composite slab. 9. The method of claim 8,
Wherein the three-dimensional horizontal shear connector 110 is formed by adjusting the diameter of the vertical roots, the horizontal roots and the oblique roots, and the angle of inclination, which is the connection angle between the horizontal roots and the oblique roots. Construction method of concrete composite slab. 9. The method of claim 8,
Wherein the three-dimensional horizontal shear connectors 110 are formed such that the three-dimensional horizontal shear connectors 110, which have the same diameter as the perpendicular roots, the horizontal roots and the oblique roots, and the inclination angles, A method of constructing precast concrete composite slab with shear connectors. 9. The method of claim 8,
Wherein the three-dimensional horizontal shear connector 110 is formed so that the three-dimensional horizontal shear connectors 110, which are different in the perpendicular direction, the diameter of the horizontal and the oblique angles, and the inclination angles, A Method of Construction of Precast Concrete Composite Slab with Horizontal Shear Connectors. 9. The method of claim 8,
The method of claim 1, wherein in step c), the connection reinforcing bars are passed through the annular reinforcing bars of the PC slabs to secure the structural integrity of the PC slabs and the beams.

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