KR101751699B1 - Void slab having mesh for preventing floating and increasing shear strength - Google Patents

Abstract

The present invention is applicable to lightweight re-fire prevention and shear strength enhancement which can increase the shear strength of a slab by preventing a lightweight material from being flushed when a concrete is laid by applying a mesh member, To a hollow slab having a mesh member.
A hollow slab according to a preferred embodiment of the present invention comprises: a prestressing material disposed along a longitudinal direction at a predetermined interval in the width direction at a lower portion of the slab in a height direction thereof to introduce a prestress into the concrete; A lightweight material disposed between neighboring tensions; The slabs are arranged in a continuous wave form over the entire length of the slab in the width direction along the width of the slab and the upper surface of the lightweight material in order to prevent the lightweight material from flying and to reinforce the shear of the concrete, And a mesh member in which the mesh of a predetermined size is closely formed.

Description

[0001] The present invention relates to a hollow slab having a mesh member for preventing lightweight rebuilding and increasing shear strength,

The present invention is applicable to lightweight re-fire prevention and shear strength enhancement which can increase the shear strength of slabs by preventing the lightweight material from being flushed when concrete is laid by applying a mesh member and can be manufactured by only one casting of concrete, To a hollow slab having a mesh member.

In general, reinforced concrete slabs are economical, rigid and rigid, and are used as flooring structures in most buildings, but they are pointed out as being disadvantageous in that their weight is heavy due to the increase of the span and the height of the building. In order to overcome these disadvantages, various types of hollow slabs have been developed and used in which a hollow is formed at the center of the slab in an attempt to reduce its weight while maintaining mechanical performance. In the case of PC products, a hollow hollow slab A slab for forming a hollow part by a machine has been developed and utilized.

The hollow slab has a disadvantage in that the section of concrete is reduced due to the hollow formation, which is light and economical while the cross section of the concrete is reduced, thereby reducing the section rigidity and shear strength. However, factory automation production method which presses concrete with a low slump like a hollow slab is not possible to deploy the stirrup which is the shear reinforcement due to the limitation of the production process, and it is not applicable to the distribution center where large load acts. PC slabs suitable for large loads include various types of double-tee slabs, but the bottom of the slab is not flat and additional finishing is required.

In order to improve each of these disadvantages, a PC hollow slab of a mold production type in which a lightweight material composed of styrofoam or the like is buried in a central portion of a slab and a concrete having a high slump is laid has been developed and in use. This method is advantageous in that it can freely form necessary shear reinforcing bars and cross-sectional shapes, and various forms have been devised and used. These hollow hollow slabs with lightweight materials are light in weight, simple in mold, free from reinforcement, and have various advantages, but lightweight materials are lighter than concrete, resulting in problems when concrete is laid.

Therefore, the construction of hollow slabs (using lightweight materials of plastic materials) on site is very rigid, so that it is possible to prevent the lightweight material from floating by arranging fixing hardware on the lower slab formwork at regular intervals with the steel bars. The way to remove the mold is common. It is also difficult to apply this method because it is difficult to fix the hollow member (lightweight material of Styrofoam material) used in PC hollow slab fabrication because it is small in rigidity and it is difficult to approach the bottom of mold after curing when it is fixed to the bottom of mold.

Therefore, in the PC factory, hollow slabs are usually manufactured by separating concrete two times. In this manufacturing method, since the lightweight material should be disposed in accordance with the height of the primary concrete, it is difficult to arrange lightweight materials at various heights. In addition, since the lightweight material should not float when the secondary concrete is poured, there is a limit to the application of the shape of the lightweight material other than the flat rectangular shape.

Also, it is difficult to control the amount of concrete when the primary concrete is poured, so that the height of the lightweight material varies depending on the skill of the operator. In addition, due to the latency of the primary casting surface, there is a concern that the integral resistance with the secondary casting surface and the continuity of the operation due to the secondary casting after the primary casting are not ensured, A new manufacturing method is required.

As a background of the present invention, Korean Patent No. 10-1175484 proposes a hollow span post tension hollow slab using a buoyancy-preventing hollow module and a tensioner arrangement by bar chair. This includes a hollow module comprising a lightweight material in the concrete, a buoyancy-proof transverse reinforcement, a fixing longitudinal reinforcement, and a barchere; Wherein the bar chair comprises a vertical member and a horizontal member, the vertical bar member being assembled to the concave portion of the buoyancy preventing lateral bar to support the longitudinal tension member; Said longitudinal torsion being longitudinally disposed in association with said bar chair; After the curing of the concrete, the prestress is introduced longitudinally by the post tension of the longitudinal tensional material, so that the lightweight material can be prevented from buoyancy and long span.

However, the background art requires that longitudinal reinforcement and transverse reinforcement be installed to prevent buoyancy of the lightweight material, and a plurality of barches must be installed between the transverse reinforcement and the tension member, thereby complicating the fabrication structure.

Korean Patent Registration No. 10-1175484

The present invention provides a hollow slab having a mesh member capable of increasing the rigidity and shear strength of a hollow slab, preventing slippage of a lightweight member by applying a mesh member, and manufacturing the hollow slab with only one casting of concrete to improve productivity. There is a purpose.

A hollow slab according to a preferred embodiment of the present invention comprises: a prestressing material disposed along a longitudinal direction at a predetermined interval in the width direction at a lower portion of the slab in a height direction thereof to introduce a prestress into the concrete; A lightweight material disposed between neighboring tensions; The slabs are arranged in a continuous wave form over the entire length of the slab in the width direction along the width of the slab and the upper surface of the lightweight material in order to prevent the lightweight material from flying and to reinforce the shear of the concrete, And a mesh member in which the mesh of a predetermined size is closely formed.

In addition, the mesh member is composed of a single body corresponding to the length of the lightweight material.

In addition, the mesh members are provided in a plurality of lengths shorter than the length of the lightweight material, and are arranged densely toward the both ends from the center of the lightweight material.

Further, the present invention is characterized by further comprising compression reinforcing bars arranged in the longitudinal direction on the upper portions of the lightweight materials.

Further, the upper and lower transverse ties are arranged in the width direction on the upper and lower sides of the lightweight material, and a vertical reinforcement rope connected between the upper and lower transverse ties is further constructed.

The mesh member may be formed of any one of wire, nylon, and carbon fiber.

In addition, the lightweight material may further include a cylindrical net surrounded by an outer circumferential surface.

According to the hollow slab having the mesh member of the present invention, since the lightweight member is fixed by the mesh member connected to the tension member side, the lifting of the lightweight member is effectively prevented and the concrete between the lightweight members is reinforced by the mesh member. Strength is increased.

In addition, since it can be manufactured by only one casting of concrete, there is no need to adjust the amount of concrete, and generation of the latency disappears, so that unity and productivity are improved.

In addition, the compressive strength can be increased by the additionally installed compression reinforcement, and the shear strength can be further improved by the vertical reinforcement rope connected between the transverse torsion and the torsion.

In addition, when the cylindrical net is further wrapped around the lightweight member, it is possible to suppress the crack generated at the periphery of the hollow section or to control the expansion of the crack.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention, Shall not be construed as limiting.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view of a hollow slab according to an embodiment of the present invention; FIG.
Figure 2a is a front view of Figure 1;
FIG. 2B is a state in which a compression reinforcement is further installed in the hollow slab of FIG. 1; FIG.
Figure 3 is a perspective view of the mesh member applied to Figure 1;
4A and 4B are various structural views of a mesh member applied to the present invention.
5A is a schematic view of a hollow slab according to another embodiment of the present invention.
Figure 5b is a front view of Figure 5a.
Figure 5c is a side view of Figure 5a.
6 is another structural view of a lightweight material applied to the present invention.
FIG. 7 is a flowchart illustrating a manufacturing process of a hollow slab according to an embodiment of the present invention; FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

In the present specification, the term 'hollow slab' is used to mean a precast prestressed concrete slab in which a lightweight material is installed in a longitudinal direction at a predetermined interval in the width direction, in a longitudinally-extending concrete having a rectangular cross- .

1 to 3, the hollow slabs 10 according to the present invention are arranged in the longitudinal direction at a predetermined interval along the width direction at a lower portion in the height direction, and a tension member 12 for introducing the prestress into the concrete 30 Is installed. The tensile member 12 is disposed below the neutral axis to prevent tensile cracking of the concrete 30. FIG. A PC steel bar, a PC steel bar or a PC strand can be used as the tension member 12.

Lightweight material 14 is arranged in the longitudinal direction between adjacent tension members 12 and 12. The lightweight material 14 may be made of a lightweight material such as styrofoam, rubber, plastic or the like, which has a relatively lower specific gravity than concrete. The present embodiment illustrates that the lightweight member 14 has a circular cross section, but it is not limited thereto, and may be modified into various shapes such as an ellipse or the like.

A mesh member 16 is provided to prevent the lightweight material 14 from flying and to reinforce the shear of the concrete. The mesh member 16 fixes the lightweight member 14 on the side of the tensile member 12 to prevent the lightweight member 14 from being injured when the concrete is laid. For this purpose, the mesh member 16 is arranged in the form of a waveform along the width direction of the hollow slab 10 while sequentially covering the lower portion of the tensile member 12 and the upper portion of the lightweight member 14. [

As shown in FIG. 3, the mesh member 16 is composed of a horizontal wire 16a and a vertical wire 16b, and has a net having a predetermined size. In this case, the horizontal wire and the vertical wire may be wire, nylon, carbon fiber, or the like. As a method of connecting the mesh member 16 to the tensile member 12, a wire used to bind the reinforcing bars can be used.

One form of the mesh member 16 may be constructed as a single body having a length corresponding to the length of the lightweight material 14 as shown in FIG. Other shapes of the mesh member 16 may be provided in a plurality of shapes having a length shorter than the length of the lightweight material 14 as shown in FIG. 4A. 4 (b), the mesh member 16 is densely arranged from the center of the lightweight material 14 toward both ends thereof. In this case, the hollow slab 10 can effectively cope with the shear force increasing from the center to the end side.

In order to increase the resistance against the compressive force of the hollow slab 10, as shown in FIG. 2B, the compression reinforcement rods 18 may be further provided in the longitudinal direction on the upper portions of the lightweight materials 14. [

As shown in FIGS. 5A to 5C, the upper and lower transverse ties 20a and 20b are arranged in the width direction at regular intervals along the longitudinal direction of the lightweight material 14 at the upper and lower portions of the lightweight material 14 A vertical reinforcing bar 22 connecting the upper and lower transverse ties 20a and 20b may be further provided between the lightweight materials 14. [ The vertical reinforcement rope 22 may be a lattice shape in which the mountain-like shape is repeated in the longitudinal direction continuously. The upper and lower transverse reinforcement rods 20a and 20b reinforce the concrete in the transverse direction and the vertical reinforcement rods 22 improve the shear strength of the hollow slab.

On the other hand, as shown in FIG. 6, the light weight material 14 may be formed by further surrounding the cylindrical net 15 on the outer circumferential surface. In this case, the cylindrical net 15 serves to suppress the occurrence of cracks in the concrete surrounding the lightweight material 14. [

A manufacturing method of the hollow slab 10 constructed as above will be described.

First, in order to introduce a prestress into concrete to be placed in the mold 5 as shown in Fig. 7 (A), the tension members 12 are stretched and arranged at regular intervals along the width direction of the hollow slab 10. [

Next, the lightweight material 14 is disposed between the neighboring tension members 12 and 12 as shown in FIG. 7 (B). At this time, the lightweight material 14 is placed at the set position by providing the spacer 15 on the bottom of the mold 5.

Next, a mesh member 16 for fixing the lightweight material 14 to the side of the tensile member 12 is provided for preventing the lightweight material 14 from being floated and for reinforcing the shear.

Next, as shown in FIG. 7 (C), the concrete 30 is poured into the mold 5, and then is cured and demoulded. The lightweight material 14 is fixed to the side of the tensile member 12 via the mesh member 16 to prevent the lightweight member 14 from being injured when the concrete 30 is laid.

According to the present invention, since the lightweight material 14 is fixed by the mesh member 16, the concrete 30 can be manufactured by only one casting, thereby improving the productivity. In addition, since the concrete 30 is not laid in the first or second order as in the prior art, there is no need to separately adjust the amount of installation, and an advantage that the skill of the operator is not required can be obtained. In addition, the mesh member 16 also serves as a reinforcing material for improving the shear strength of the concrete, thereby effectively reinforcing the shear strength of the hollow slab.

In order to introduce a prestress into concrete, the present invention is also applied to a hollow beam in which a lightweight material 14 is fixed by a mesh member 16 arranged in the form of a waveform in the width direction using a tension member 12 arranged in the longitudinal direction Can be applied.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

12: Tension material
14: Lightweight material
16: mesh member
18: Compression bar
20a: Upper transverse torsion
20b: Lower transverse torsion

Claims (7)

A prestressing material 12 disposed at a lower portion of the slab in the height direction at a predetermined interval in the width direction to introduce a prestress into the concrete 30;
A lightweight material 14 disposed between neighboring tensions 12 and 12;
The lower surface of the tensile material 12 and the upper surface of the lightweight material 14 are sequentially laid over the entire length in the width direction along the width direction of the slab in order to prevent the lightweight material 14 from floating and to reinforce the concrete 30 And a mesh member (16) arranged in a continuous wave form with the horizontal wire (16a) and the vertical wire (16b) arranged in a lattice form and having a mesh of a predetermined size densely formed thereon. A hollow slab having a mesh member for preventing and increasing shear strength. The method according to claim 1,
Wherein the mesh member (16) is composed of a single body corresponding to the length of the lightweight material (14). The method according to claim 1,
Characterized in that the mesh members (16) are provided in a plurality of lengths shorter than the length of the lightweight material (14) and arranged densely toward the both ends from the center of the lightweight material (14) Hollow slab with incremental mesh member. The method according to claim 1,
Further comprising a compressive reinforcement rope (18) arranged in the longitudinal direction on each of the lightweight members (14). The method according to claim 1,
Upper and lower transverse reinforcement ropes 20a and 20b are disposed on the upper and lower sides of the lightweight material 14 and vertical reinforcement rods 22 connected between the upper transverse reinforcement 20a and the lower transverse reinforcement 20b, Wherein the reinforcing member is further provided with a mesh member for lightweight rebound prevention and shear strength increasing. The method according to claim 1,
Wherein the mesh member (16) is made of any one of wire, nylon, and carbon fiber. The method according to claim 1,
Wherein the lightweight material (14) further comprises a cylindrical net (15) wrapped around the outer periphery.

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