KR101303721B1 - Headed rib precast slab and construction method therefor - Google Patents

Abstract

This invention relates to a headed rib PC slab and a construction method thereof, which can more effectively secure structural integrity of beams and PC slabs, and to effectively prevent shear cracking of PC slabs. Shear key in the form of a triangular block body formed in W; And a vertical planar lattice reinforcing bar which is arranged in a vertical plane shape inside the rib and the upper plate, the upper part of which protrudes upward from the upper surface of the upper plate, and a plurality of triangular block body shaped shear keys and ribs are respectively formed. The upper surface B1 of the upper plate and the upper surface B2 of the triangular block body-shaped shear key are formed to have the same height so that the triangular block body-shaped shear key extends horizontally from the upper plate.

Description

HEADED RIB PRECAST SLAB AND CONSTRUCTION METHOD THEREFOR}

The present invention relates to a headed rib PC slab and its construction method. More specifically, the present invention relates to a headed rib PC slab capable of securing structural integrity of beams, columns and PC slabs (precast slabs) more effectively, and effectively preventing shear cracking of PC slabs, and a construction method thereof.

In general, parking lots of buildings such as large stores and factories are constructed with reinforced concrete structures, which are mostly formed of formwork, reinforcement, and concrete.Reinforced concrete structures have cracks due to the characteristics of materials and leak defects. It is emerging.

In order to solve the above problem, a double tee slab method is recently used, and the double tee slab method 10 is spaced apart from the bottom plate at a predetermined interval as shown in FIGS. 1A and 1B. The beam 11 is installed, the beam 12 is seated on the jaw 11 ′ of the pillar 11, and the beam 12 is mounted with the double tee slab 13 mounted on the beam 12. ) And the slab concrete S is poured into the double tee slab 13 to form a slab layer.

However, in the double tee slab method, a slab layer is formed by slab concrete (S) that is poured in a state seated on the jaw of the beam or pillar, and the pillar and the beam are not integrally formed, and the double tee slab is simple. As the beam is designed to be weak between the slab and the beam, there is a problem of cracking in the slab layer and leakage of inflow water such as snow or rain to the cracked portion of the slab layer, which causes the vehicle to be parked on the lower floor. There was a problem of messing up the surface of the vehicle.

The upper plate 20 as shown in Figure 1c; An inclined curling plate 30 extending inclined downwardly from both ends in the longitudinal direction of the upper plate and a plurality of ribs 40 extending in the longitudinal direction of the upper plate and parallel to each other at regular intervals in the width direction on the lower surface of the upper plate. The ribs on both ends of each rib have an upper inclined surface connected to the inclined copper plate and a lower inclined surface having an inclined direction opposite to the upper inclined surface, and both end sides of the rib portion in which both ends of the rib become an upper inclined surface become thicker toward the inclined copper plate. An increasing thickness of the tapered horizontal haunch 60 is formed with the PC slab is introduced.

Accordingly, the rib width of the end can be expanded with the horizontal haunch 60, and at the same time, the rib plate can be installed to increase the concrete cross-sectional area of the compression zone in the continuous joint, and the tensile reinforcement ratio resisting the parent can be designed to be less than the maximum reinforcement ratio. By making the copper plate inclined, the slab-beam connection facilitates the placing of concrete and the reinforcement of reinforcing bars, and at the same time, the strength of the load increases as the upper section of the beam is enlarged.

At this time, in the case of the upper surface of the inclined copper plate 30 is formed as a continuous mountain 31, as shown in Figure 1d so that the surface of the mountain copper surface acts as a shear key to improve the integrity of the beam when placing slab concrete (S) It can be seen.

1E illustrates a conventional PC slab 50. The PC slab 50 is formed so as to expose the upper portion of the lattice reinforcement on the upper surface (A) can be said to ensure the integrity with the lattice reinforced slab concrete, and a plurality of lifting irons (51, 52) formed on the upper surface It can be seen that.

The lattice reinforcing bar 50 extends in the longitudinal direction of the PC slab and a pair of lower reinforcing bars (53, truss reinforcing bars) installed to be spaced apart from each other, the lattice bar is disposed to be spaced apart from the lower reinforcement to the upper center ( 54, it can be seen that including a connecting wire 55 extending continuously in a wave form between the lattice bar 54 and the lower rebar.

At this time, the upper portion of the connecting wire 55 and the lattice bar 54 is exposed upward from the upper surface surface to ensure the integrity of the slab concrete.

However, since the top plate of the headed rib PC slab or double tee slab is very thin, there is a problem that it is almost impossible to bury the conventional lattice reinforcement 50 of the PC slab 50.

In addition, particularly in the case of the connecting wire 55 is formed at an angle that is unfavorable to the shear cracking of the PC slab 50, there is a problem that only the amount of material required for the connecting wire 55 is increased, the efficient shear crack control is not possible.

Accordingly, the present invention can easily install the lattice reinforcing bar in the headed rib PC slab formed of the top plate and ribs to ensure more secure the integrity of the slab concrete, the structure of the lattice reinforcement The shear rib of the headed rib PC slab is optimized to be formed, and the shear key can be more effectively formed on the inclined copper plate of the top plate, but the reinforcing bar is formed at the shear key at the same time so that the connecting reinforcing bar can be penetrated. The technical task is to solve the provision of a headed rib PC slab with a lattice reinforcing bar to secure structural integrity of the column and headed rib PC slab.

Accordingly,

First, in the headed rib PC slab, the lattice reinforcing bar is formed in a vertical plane to be embedded in the rib, but formed into a structure (N-shaped) that effectively resists shear cracking so as to effectively secure the integrity with the slab concrete. It was.

Second, a triangular block body shear key is formed on the top surface of the inclined copper plate of the headed rib PC slab, and the top surface of the top plate is formed to have the same height as the top surface of the shear key. It protrudes outward to expose the outside so that the reinforcing bar penetrates at the continuous end joint. This ensures a more solid headed rib PC slab and pillars.

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According to the present invention, the headed rib PC slab can secure the structural integrity of the pillar and the slab concrete more reliably, and by applying a lattice reinforcement to the headed rib PC slab, it is possible to effectively prevent the shear cracking of the continuous end joint. In addition, it is possible to effectively lay out the lattice rebar, making it possible to manufacture and construct a slimmer and more economical PC slab, and to reduce the manufacturing cost (reinforcement loss cost) due to the structural shape of the lattice rebar.

The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

1a and 1b is a perspective view and a front view of the construction of a conventional double tee slab (Double Tee Slab),
Figure 1c is a perspective view of a conventional headed rib PC slab,
1D is a perspective view of an inclined copper plate of a conventional headed rib PC slab,
Figure 1e is a perspective view of the configuration of a PC slab formed with a conventional lattice rebar,
2 is a comparative perspective view of a conventional lattice rebar and a lattice rebar of the present invention;
3a and 3b is a combination configuration and perspective view of the lattice reinforcement and headed rib PC slab of the present invention,
Figures 4a and 4b is a perspective view and cross-sectional view of headed rib PC slab formed lattice reinforcement of the present invention
5A and 5B are headed rib PC slab perspective view and excerpt sectional view of a lattice reinforcing bar of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. 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 the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Lattice rebar 200 of the present invention

2 is a manufacturing diagram of the lattice rebar of the present invention.

This is compared with the conventional lattice rebar as follows.

First, it can be seen that the conventional lattice reinforcing bar 50 is formed in a triangular three-dimensional truss shape, a pair of lower reinforcing bars (53, truss reinforcing bars) installed spaced apart from each other as shown in FIG. It can be seen that it comprises a lattice bar 54 disposed to extend in the longitudinal direction, the connecting wire 55 continuously extending in a wave form between the lattice bar 54 and the lower reinforcing bar.

However, the main role of the actual shear reinforcing bar is the connecting wire 55 and the lattice bar 54 because the connecting wire 55 and the lattice bar 54 is disposed to be embedded in the slab concrete.

However, the lattice reinforcing bar of the conventional PC slab is formed in the form of a triangular solid truss is virtually impossible to use in the PC slab structure in which the thickness of the top plate is thin and the rib protrudes downward on the bottom of the top plate as in the present invention.

Accordingly, the present invention is to form a lattice reinforcement 200 in a vertical plane. It is to be formed in a vertical plane so that it can be placed perpendicular to the thin ribs and top plate.

At this time, the vertical flat lattice reinforcement 200 has an N-shaped portion in which the inclined portion B is formed between both left and right vertical portions A, that is, extending from the lower left vertical portion to the upper right vertical portion as shown in FIG. 2. N-shaped rebars (200a, 200b) formed in succession to use.

Accordingly, the pair of N-shaped rebars 200a and 200b are positioned vertically to each other as shown in FIG. Are combined to make contact with each other (J).

As the lattice reinforcing bar can effectively cover not only the inclined part but also the vertical part based on the anticipated fracture line due to the shear force, the slab concrete and the lattice reinforcing bar can secure the structural integrity of each other. The cracks can be effectively prevented, and according to such a structure, the material can be saved as compared with the case of manufacturing the conventional lattice reinforcement 50, thereby enabling the use of a more effective lattice reinforcing bar.

[Headed rib PC slab 100 formed with a lattice rebar 200 of the present invention]

3A and 3B are a schematic diagram illustrating the coupling structure of the lattice reinforcing bar and headed rib PC slab of the present invention in which the lattice reinforcing bar 20 of the present invention is applied to a headed rib PC slab 100 composed of a top plate and ribs. Fig., Perspective and plan views.

That is, the headed rib PC slab 100 is composed of a top plate 110 formed of an inclined copper plate 120 formed by inclining both ends downward and a plurality of ribs 130 extending downward on the bottom of the top plate. It can be seen that, as shown in Figure 4a the end of the rib is formed in contact with the inner surface of the inclined copper plate and the horizontal outer portion 140 is formed on the outer surface of the end of the rib.

In addition, the shear key 150 of the triangular block body form is formed on the upper surface W of the inclined copper plate, and the height of the upper surface B1 of the upper plate 110 and the upper surface B2 of the shear key 150 of the triangle block body form It is formed to be the same (H1 = H2).

Accordingly, the meaning that the shear key 150 having a triangular block shape is integrally formed on the rib 130 and the inclined copper plate 120 will be referred to as a headed rib in the present invention.

In addition, the c-shaped ring reinforcement 160 is protruded from the front portion of the front end of the triangular block type shear key 150 to be exposed.

Accordingly, the connecting reinforcement 170 penetrates through the ring reinforcement 160, thereby making it easier to secure the integrity of the headed rib PC slab 100 and the slab concrete 400.

In addition, as shown in FIG. 5B, the vertical flat lattice rebar 200 may be disposed to protrude upward from the upper surface of the upper plate to ensure structural integrity with the slab concrete 400.

The vertical flat lattice reinforcement 200 is a vertical plane in which a shear key 150 having a triangular block body shape is formed at a position corresponding to the rib 130 so that one vertical flat lattice reinforcement 200 is formed from the shear key 150 at the center of the slab. It can be seen that the two vertical planar lattice rebars 200 are extended so as to be symmetrical with respect to the center part in such a manner that the ribs 130 are continuous. The vertical flat lattice reinforcement 200 is advantageous for shear cracking so that a plurality of each of the shear keys and ribs can be installed to be spaced apart from each other, thereby making it possible to manufacture a slim headed rib PC slab 100.

In this case, the triangular block body shape shear key 150 basically has a shear key function in a continuous end junction. When the slab concrete is filled in the space between the triangular block bodies, the shear key function is shown in FIG. Compared to the acid form, it is easy to manufacture and improves shear key performance.

Furthermore, the upper plate 110 is formed to have the same height (H1 = H2) as the upper plate, and thus the upper plate 110 is formed to extend in the longitudinal direction. 150 also has a function to be installed to be extended.

That is, by allowing a plurality of vertical flat lattice rebars 200 to be formed on the shear key 150 in the form of a triangular block body, it is possible to effectively increase the connection performance of the continuous end joint vulnerable to the load.

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In addition, the vertical flat lattice reinforcement 200 is a pair of N-shaped reinforcement (200a, 200b) is partially overlapped at the center portion of the headed rib PC slab 100, the shape is changed to the front and rear relative to the center portion that is the central portion It can be seen that the extension is installed so as to symmetrically based on. This can effectively cope with shear cracking caused by the load acting symmetrically with respect to the center portion of the headed rib PC slab 100 can effectively prevent the shear cracking in the continuous end junction.

In addition, it is possible to secure the integrity of the beam and column by connecting reinforcing bar 170 to the continuous end connection portion, and to be connected to the continuous member to enhance the connection performance of the column and beam, in contrast to the installation in the form of a simple beam. do.

[Headed rib PC slab 100 of the present invention]

4A and 4B are top and bottom perspective and cross-sectional views of (100) a completed headed rib PC slab in accordance with the present invention.

Accordingly, it can be seen that the headed rib PC slab 100 is formed so that the upper plate 110 having a rectangular plate shape extends to have a predetermined length.

In addition, both ends of the upper plate 110 is formed to be inclined downward and is formed of an inclined copper plate 120 formed with a shear key 150 of the triangular block body form,

On the bottom of the upper plate 110, it can be seen that two ribs 130 having a vertical plate shape extending in the longitudinal direction of the upper plate are spaced apart from each other.

At this time, the end of the rib is formed in contact with the inner surface of the inclined copper plate, it can be seen that the horizontal hunting portion 140 is formed on the outer surface of the end of the rib.

Generally, two ribs 130 are formed in the headed rib PC slab 100, but the ribs 130 may be formed in a thinner thickness because the reinforcement is possible because the lattice reinforcement described later is embedded. In the case of the present invention, two may be common, but three may be formed to extend the length and width of the headed rib PC slab 100 (shown on the basis of three in the drawing).

At this time, it can be seen that the lattice reinforcement 200 of the present invention as described above is embedded in the shear key 150 and the rib 130 in the form of a triangular block body, and is disposed to protrude upward from the upper plate. .

It can be seen that the ring reinforcement 160 is integrally formed on the outer surface of the shear key 150 of the triangular block body by the vertical flat lattice reinforcement 200.

[Construction method of headed rib PC slab 100 of the present invention]

5A and 5B show a construction front view of the completed headed rib PC slab according to the present invention.

First, construct the column 500 first,

The beam 600 is installed using the steps of the pillar 500.

The bottom surface of the inclined curled plate 120 of the headed rib PC slab 100 of the present invention is disposed on the beam 600.

The ring reinforcement 160 of the headed rib PC slab 100 passes through the connecting reinforcement 170 to secure structural integrity of the headed rib PC slab 100 and the beam.

Next, the slab concrete 400 is poured on top of the headed rib PC slab 100 and the beam to form a slab layer.

Of course, the joints of the pillars, beams, and headed rib PC slabs are also finished with slab concrete.

100: headed rib PC slab
110: top plate
120: tilted copper plate
130: rib
140: horizontal hunt
150: shear key in the form of a triangular block
160: ring rebar
170: connecting rebar
200: vertical flat lattice rebar
200a, 200b: N-shaped rebar
400: slab concrete
500: pillar
600: Bo

Claims (7)

In the headed rib PC slab comprising a top plate 110 formed of an inclined copper plate 120 is formed inclined downward at both ends and a plurality of ribs 130 extending downward on the bottom surface of the top plate, the headed rib PC slab 100
A shear key 150 in the form of a triangular block body formed on the upper surface W of the inclined curled plate 120 corresponding to each formation position of the ribs; And
It includes a vertical plane type lattice reinforcement (200) formed so that the ribs 130 and the upper plate in a vertical plane form, but is protruded upward from the upper surface of the upper plate (110);
The vertical flat lattice reinforcing bar 200 is a vertical flat lattice reinforcing bar 200 is continuous from the shear key 150 formed at both ends of the headed rib PC slab to the rib 130 of the head of the headed rib PC slab in the center portion Is superimposed using two vertical plane type lattice reinforcement 200 is installed to be symmetrical with respect to the center portion,
The upper surface B1 of the upper plate 110 and the upper surface B2 of the triangular block body shear key 150 are formed to have the same height so that the triangular block body shear key extends horizontally from the upper plate 110. Headed rib PC slab, characterized in that formed. The method of claim 1, wherein the vertical planar lattice reinforcement 200
As a vertical plane reinforcing bar in which the N-shaped portion having the inclined portion extending from the lower left vertical portion to the upper right vertical portion is continuously formed in the longitudinal direction,
The pair of N-shaped rebars 200a and 200b are vertically disposed to be spaced apart from each other, and then positioned to be shifted forwards and backwards to each other so that the roughly center portions of the vertical portions are joined so that the roughly central portions of the inclined portions are in contact with each other. Headed rib PC slab characterized by the above-mentioned. The method of claim 2,
Headed rib PC slab characterized in that the triangular block-shaped shear key 150 is formed on the outer surface of the ring reinforcement 160 and the connecting reinforcement 170 through the ring reinforcement 160. The method of claim 2,
The rib 130 is headed rib PC slab, characterized in that the three to be spaced apart from each other in the longitudinal direction on the bottom surface of the top plate (110). Installing a pillar 500;
Installing a beam 600 on the column 500;
Installing the headed rib PC slab of claim 1 between the beam 600 and the beam; And
The beam 600, headed rib PC slab construction method comprising the step of placing the slab concrete 400 on top of the head. 6. The method of claim 5,
The ring reinforcement 160 is formed on the outer surface of the shear key 150 having a triangular block body shape, and the reinforcing bar 160 is connected to the reinforcing bar 170 so that the connecting reinforcement is embedded in the slab concrete 400. Headed rib PC slab construction method characterized in that. 6. The method of claim 5,
The rib 130 is a headed rib PC slab construction method characterized in that the three to be spaced apart from each other in the longitudinal direction on the bottom surface of the top plate (110).

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