KR101229450B1 - Integrated lightweight materials set for hollow core and two way hollow core slab thereby - Google Patents

Abstract

The present invention is a hollow body embedded between a slab upper reinforcing bar and a slab lower reinforcing bar to complete a hollow slab, the integral lightweight assembly that simply completed a plurality of lightweight materials in one aggregate form, and preferably in a two-way hollow slab using the same It is about.
The integrated lightweight assembly according to the present invention is a hollow body embedded between a slab upper reinforcing bar and a slab lower reinforcing bar to complete a hollow slab, the plurality of lightweight bodies having a predetermined three-dimensional shape and disposed parallel to each other in a lattice shape; A side connection piece provided to connect neighboring lightweight bodies with a dance and a narrower width than the lightweight body along a lattice-like arrangement direction of the lightweight body; An upper protrusion piece protruding to a smaller size than the light body on the upper surface of the light body; The side projection piece protruding in a narrow width and the dance lower than the light weight body on the side of the light weight body disposed in the grid-like arrangement of the light body; Consists of the light body, side connection piece, upper projection piece, side projection The piece is characterized in that it is made integrally.

Description

Integrated lightweight materials set for hollow core and two way hollow core slab thereby

The present invention is a hollow body embedded between a slab upper reinforcing bar and a slab lower reinforcing bar to complete a hollow slab, the integral lightweight assembly that simply completed a plurality of lightweight materials in one aggregate form, and preferably in a two-way hollow slab using the same It is about.

Two-way hollow slab (hollow core slab) as shown in Figure 1 is a structure in which a hollow core is formed in two directions in the center, because it has excellent cross-sectional performance compared to its own weight, long span, flat slab ) It is advantageously applied to the structure.

In general, the hollow slab is difficult to work in the field, such as forming a hollow, it is generally adopted as a PC product manufactured in the factory. However, hollow PC slabs are inconvenient to transport and lift, and require construction precautions for integral joining with columns or beams.

In order to solve the problem of the hollow PC slab described above, a method of forming a hollow in the field has been proposed. In other words, after placing the lightweight material in the construction position, the concrete is poured so that the lightweight material is embedded in the concrete. Lightweight material embedded in concrete soon becomes hollow. However, the hollow slab of such a site construction has a disadvantage in that the amount of work is increased because the light weight should be fixedly placed in a lattice at the construction position. In order to solve this disadvantage, the present inventors have developed a patent application for developing a light weight assembly such as FIGS. 2A and 2B. On the other hand, when constructing a hollow slab using the lightweight assembly of Figures 2a and 2b, it is necessary to provide measures for preventing the injury of the lightweight assembly because the lightweight assembly easily rises due to the buoyancy by the concrete.

The light weight assembly of FIG. 2A is a form in which a tie bolt is fastened to an intersection point of a welded wire mesh and the tie bolt is installed through a lightweight material, and then the nut is fastened. The lightweight assembly of FIG. 2A has advantages in that it can be inherently prevented from injuries and can be secured in place because the lightweight assembly is directly attached to the slab formwork or the slab bottom rebar, but the number of parts and the bolts and nuts must be fastened individually. Therefore, there is a disadvantage in that the assembly work is cumbersome and the light material and welded wire mesh of different materials are assembled and completed, thus preparing and preparing the light material and welded wire mesh in different factories.

The light weight assembly of FIG. 2B is divided into two types of light weight material, and the welded wire mesh is assembled therebetween. Although the light weight assembly of FIG. 2B is easy to assemble due to the small number of parts, there is still a disadvantage in that a light material and a welded wire mesh of different materials are prepared. Furthermore, the light weight assembly may be disposed by placing a spacer between the light weight assembly and the upper slab. If there is an injury, the spacer is caught on the upper slab and the injury is prevented. Thus, the uneven injury of the lightweight assembly may prevent the lightweight assembly from being positioned in place.

The present invention has been invented to solve the problem of the conventional two-way hollow slab, the technical problem to provide a one-piece lightweight assembly and a simple two-way hollow slab completed by preferably applying a plurality of lightweight materials in one aggregate form There is.

In order to solve the above technical problem, the present invention provides an integrated lightweight aggregate and a two-way hollow slab using the same.

The integrated lightweight assembly according to the present invention is a hollow body embedded between a slab upper reinforcing bar and a slab lower reinforcing bar to complete a hollow slab, the plurality of lightweight bodies having a predetermined three-dimensional shape and disposed parallel to each other in a lattice shape; A side connection piece provided to connect neighboring lightweight bodies with a dance and a narrower width than the lightweight body along a lattice-like arrangement direction of the lightweight body; An upper protrusion piece protruding to a smaller size than the light body on the upper surface of the light body; The side projection piece protruding in a narrow width and the dance lower than the light weight body on the side of the light weight body disposed on the outer side in the grid-like arrangement of the light body; Consisting of the light body, side connection piece, the upper projection piece integrally molded It is characterized by being manufactured.

Two-way hollow slab according to the present invention, the hollow slab using the integrated lightweight assembly, the slab bottom reinforcement lattice; An integrated lightweight assembly installed above the slab lower reinforcement, wherein the light body is disposed in a lattice space of the slab lower rebar; A slab upper reinforcing bar being placed on the upper protrusion piece of the integrated lightweight assembly; Hooks formed on the upper and lower portions of the support shaft, the hook is fixed to the upper hook is fastened to the upper slab and the lower hook is fixed to the slab upper reinforcing bar and the integrated lightweight assembly is installed on the side connection piece of the integrated lightweight assembly; It is characterized in that consisting of; slab lower reinforcing bars and slab upper reinforcing slab concrete is poured into a thickness that is embedded.

According to the present invention, the following effects can be expected.

First, since a plurality of lightweight materials arranged in a lattice form as a single assembly, a plurality of lightweight materials can be easily installed at a time, thereby improving the construction properties of the hollow slab.

Second, because a single material is a plurality of lightweight materials to be completed in one aggregate, it is possible to simply manufacture the aggregates immediately in the manufacturing process of the lightweight materials, thereby economically producing and supplying lightweight materials for the hollow slab.

Third, since the hollow slab can be constructed while placing the slab concrete while fixing the installation position of the lightweight member assembly, the lightweight member can be positioned in place while blocking uneven injuries of the lightweight member at the source. It can be completed with hollow slab.

1 is a cross-sectional view of a two-way hollow slab.
2A and 2B are conventionally proposed lightweight assemblies.
3 shows a first embodiment of an integrated lightweight assembly for a two-way hollow slab according to the present invention.
4a and 4b show the construction of the two-way hollow slab by the integrated lightweight assembly of FIG.
Figure 5 shows a second embodiment of the integrated lightweight assembly for a two-way hollow slab according to the present invention.
Figure 6 shows the construction of the two-way hollow slab by the integrated lightweight assembly of Figure 5;
Figure 7 shows the construction of the two-way hollow slab according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings and preferred embodiments.

3 and 5 show the integrated lightweight assembly 100 for the two-way hollow slab according to the present invention, Figures 4a, 4b, 6 is a construction state of the two-way hollow slab by the integrated lightweight assembly 100 Shows

The integrated lightweight assembly 100 according to the present invention is a hollow body that is embedded between the slab upper reinforcing bar 220 and the slab lower reinforcing bar 210 to complete the hollow slab, the light body 110, the side connecting piece 130 and the upper While the protrusion pieces 120 are essentially included, the side protrusion pieces 140 and the corner connecting pieces 150 are configured to be selectively included, while these components are all formed integrally with the same material. The integrated lightweight assembly 100 may be molded and made smaller than the unit weight of concrete with styrofoam, plastic, steel, carbon fiber, and the like, and furthermore, if it is manufactured in a hollow form, it is more advantageous to secure lightweight.

Lightweight body 110 is a function mainly as a hollow body has a predetermined three-dimensional shape (spherical, capsule, dice, etc.), a plurality of grids are arranged in parallel spaced apart from each other. The side connection piece 130 is a portion provided to connect the neighboring lightweight body 110 with a narrower width and dance than the light body 110 along the lattice-shaped arrangement direction of the light body 110, such a side connection piece ( By 130, a plurality of lightweight bodies 110 form one aggregate constrained from each other. The upper protrusion piece 120 is formed on the upper surface of the light weight body 110 to protrude to a smaller size than the light body 110, and serves as a base of the slab upper rebar 220, while the light body 110 and the upper slab reinforcement It serves to maintain the separation distance of 220, the upper projection piece 120 may be provided only in part of the plurality of lightweight body.

Side projection piece 140 is a portion formed protruding in a narrow width and lower than the light weight body 110 on the side of the light weight body 110 located in the grid-like arrangement of the light body 110, integral lightweight assembly 100 ) Serves to maintain the spacing between the integrated lightweight assembly 100 in the process of arranging). The corner connecting piece 150 is a lighter body than the four light body 110 in the grid-like arrangement of the light body 110, the lower than the light weight body 110 and at least one of the intersections of the four light body ( 110 is provided to connect at the same time while the through-hole is formed to penetrate, serves to restrain the installation position of the integrated lightweight assembly 100, the detailed description thereof will be described in Figure 4a.

3 is a first embodiment of the integrated lightweight assembly 100 for the two-way hollow slab according to the present invention, the first embodiment is a lightweight body 110, side connection piece 130, the upper projection piece 120, The side protrusion piece 140, the corner connecting piece 150 is an example molded integrally to include all. The first embodiment is provided to have a structure in which the light body 110 is hollow in the shape of a die with a curved surface and separated into an upper body 110a and a lower body 110b. In addition, while the remaining components are all provided in a rectangular shape, the side connecting piece 130, the side protrusion piece 140, and the corner connecting piece 150 are provided on the lower body 10b of the light body and the upper protrusion piece 120 is light. It is provided in the upper main body 10a of a main body. Particularly, in the first embodiment, the corner connecting pieces 150 are provided adjacent to each other at four locations, which are flexibly connected to the connection bolts 253 installed at regular intervals when installing the uniformly-formed integral lightweight molding material 100. Correspondingly, this is to restrain the integrally formed lightweight molding material 100 to the connection bolt 253.

The integrated lightweight assembly 100 of FIG. 3 is applied as in FIGS. 4A and 4B to complete the two-way hollow slab. As you can see, the two-way hollow slab is completed as the integral lightweight assembly 100 is fixedly disposed between the upper and lower reinforcing bars 210 and 220 of the slab and embedded in the slab concrete 240.

Specifically, the two-way hollow slab, the slab lower reinforcing bar 210 is lattice; An integrated lightweight assembly 100 installed above the slab lower reinforcement 210 and disposed such that the light body 110 is positioned in the lattice space of the slab lower reinforcement 210; A slab upper reinforcing bar 220 which is placed on the upper protrusion piece 120 of the integrated lightweight assembly and is disposed in a lattice; Hooks are formed on the upper and lower portions of the support shaft 231, and the upper hooks 232a are hooked to the upper slab 220 and the lower hooks 232b are hooked to the side connecting pieces 130 of the integrated lightweight assembly. A fixed hook 230 for fixing and restraining the upper slab upper reinforcing rod 220 and the integrated lightweight assembly 100; The slab lower reinforcement 210 and the slab upper reinforcement 220 is the slab concrete 240 is poured into a thickness that is embedded; consists of.

Since the fixed hook 230 restrains the slab upper reinforcing bar 220 and the integrated lightweight assembly 100, even when the slab concrete 240 is poured, the rise of the integrated lightweight assembly 100 does not occur, and thus, the integrated lightweight assembly 100 is eventually formed. ) Position is fixed and movement in the vertical direction is suppressed. In FIG. 4A, the lower hook 232b is fixedly mounted to the reverse L on the support shaft 231 while the upper hook 232a is hinge-mounted to be hinge-mounted. The fixed hook 230 is installed to hook the lower hook (232b) to the side connecting piece 130 of the integrated lightweight assembly in the state that the upper hook (232a) unfolded, then folded the upper hook (232a) to the upper slab reinforcement 220 It is used in such a way as to be wildly installed. The fixed hook 230 of FIG. 4A is just an example, and the specific shape of the fixed hook 230 may be variously modified if the slab upper rebar 220 and the integrated lightweight assembly 100 can be restrained.

In addition, in FIGS. 4A and 4B, slab upper and lower reinforcing bars 210 and 220 are formed by using a reinforcing bar spacer 250 configured to connect the lower reinforcing bar 251 and the upper reinforcing bar 252 to the connection bolt 253. I'm back. The reinforcement spacer 250 is fixed to the slab formwork (F, deck, etc.) with a fixing nail (F1), such as fixing the lower reinforcing bar 251, seating the lower slab reinforcement 210 to the lower reinforcing bar 251 In addition, the connecting bolt 253 is installed to pass through the through hole 151 of the corner connecting piece of the integrated lightweight assembly 100, and is used in the manner of seating the upper reinforcing bar 220 to the upper reinforcing bar 252. . According to this installation, the integrated lightweight assembly 100 is constrained to the connecting bolt 253 of the reinforcement spacer, and thus the movement of the integrated lightweight assembly 100 is fixed while the position of the integrated lightweight assembly 100 is fixed.

5 is a second embodiment of the integrated lightweight assembly 100 for the two-way hollow slab according to the present invention, the second embodiment is the light body 110, the side connecting piece 130, the upper projection piece 120 It is an example molded integrally to constitute. In the second embodiment, the side connecting piece 130 and the upper protrusion piece 120 are connected to each other to form a lattice shape on the light body 110. Although not shown in the second embodiment, the lightweight body 110 may be provided in an assembly structure. In this case, the side connection piece 130 and the upper protrusion piece 120 may be provided in the lower body of the lightweight body.

FIG. 6 illustrates a construction state of a two-way hollow slab completed by applying the integrated lightweight assembly 100 of FIG. 5. As shown, the fixed hook 230 is installed to restrain the side connection piece 130 and the slab upper reinforcing bar 220 of the integrated lightweight assembly, and the slab concrete 240 is poured.

Figure 7 shows the construction of the two-way hollow slab according to the present invention. First, the lower reinforcing bar 251 is fixed to the slab formwork (F) by fixing nails (F1), etc., and the lower slab lower bar 210 is seated on the lower reinforcing bar 251. If the slab formwork (F) adopts a formwork such as deck plate, the lower reinforcing bar (F1) simply need to be bonded to the slab formwork (F). Subsequently, the integrated lightweight assembly 100 is disposed on the slab formwork F, while connecting and connecting the connection bolt 253 and the upper reinforcing bar 252 to the lower reinforcing bar 251. In the case of using the light weight assembly 100 provided with the corner connecting piece 150 as shown in FIG. 3, the connecting bolt 253 is fitted into the through hole 151 of the corner connecting piece to connect the integrated lightweight assembly 100 to the connecting bolt 253. To be bound. Thereafter, the slab upper reinforcing bar 220 is placed on the upper reinforcing bar 252 while being positioned on the upper protrusion piece 120 of the integrated lightweight assembly, and the fixed hook 230 is integrated with the integrated lightweight assembly 100 and the slab upper rebar 220. ) And at the same time to bind. In this case, the slab upper reinforcing bar 220 may be fixed to the upper reinforcing bar 252 while tying the binding line 221. Finally, the slab concrete 240 is poured.

The integrated lightweight assembly 100 does not injure even when the slab concrete 240 is placed because the installation position is fixed by the fixing hook 230, whereby the integrated lightweight assembly 100 is the upper slab reinforcement 220 It is embedded in the slab concrete 240 while being fixed in place. Two-way hollow slab is completed by curing slab concrete (240), and when slab formwork (F) adopts demolding formwork such as plywood, the slab formwork (F) is to be demoulded, and slab formwork (F) is used as a deck. If the formwork is adopted, the slab formwork (F) is left as it is.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, the present invention is not limited to the above-described exemplary embodiments, and various modifications, additions and substitutions may be made without departing from the scope of the present invention. And the scope of the present invention is defined by the appended claims.

100: integrated lightweight assembly
110: lightweight body
120: upper protrusion piece
130: side connection piece
140: side projection
150: corner connecting piece
210: slab bottom rebar
220: upper slab
221: tie
230: fixed hook
240: slab concrete
250: Rebar spacer
251: bottom reinforcing bar
252: upper reinforcing bar
253: connecting bolt

Claims (7)

As a hollow body buried between the upper slab reinforcement 220 and the slab lower reinforcement 210 to complete the hollow slab,
A plurality of lightweight bodies 110 having a predetermined three-dimensional shape and disposed in parallel to be spaced apart from each other in a lattice shape;
Side connection piece 130 provided to connect the neighboring lightweight body 110 with a narrower width and dance than the lightweight body 110 along the lattice-shaped arrangement direction of the lightweight body 110;
An upper protrusion piece 120 protruding to a smaller size than the lightweight body 110 on an upper surface of at least one of the plurality of lightweight bodies 110;
A side projection piece 140 protruding in a narrower width than the light weight body 110 at a side of the light weight body 110 located at the outer side in the grid-like arrangement of the light weight body 110;
In the grid-like arrangement of the light body 110, the four light body 110 is connected to the four light body 110 at the same time at least one of the intersections of the light body 110 and narrower than the light body 110 at a narrower width at the same time. And a corner connecting piece 150 which is provided to be formed to penetrate the upper and lower through-holes.
The light weight body 110, side connection piece 130, the upper projection piece 120, side projection piece 140, corner connecting piece 150, integrally lightweight for two-way hollow slab, characterized in that the molding is made integrally Aggregate 100. In claim 1,
The lightweight body 110 is a one-piece lightweight assembly 100 for the two-way hollow slab, characterized in that the hollow form is produced. In claim 2,
The lightweight body 110 has a structure that is separated and assembled into an upper body (110a) and a lower body (110b),
The side connection piece 130 is provided in the upper body (110a) or the lower body (110b) of the lightweight body, the upper projection piece 120 is provided in two directions characterized in that provided in the upper body (110a) of the lightweight body Integral lightweight assembly 100 for hollow slabs. 4. The method according to any one of claims 1 to 3,
The side connecting piece 130 and the upper projection piece 120 is connected to each other, integral lightweight assembly for a two-way hollow slab, characterized in that to form a lattice on the light body 110. As a hollow slab using the integrated lightweight assembly according to any one of claims 1 to 3,
Slab lower reinforcing bar 210 is lattice;
An integrated lightweight assembly 100 installed above the slab lower reinforcement 210 and disposed such that the light body 110 is positioned inside the lattice space of the slab lower reinforcement 210;
A slab upper reinforcing bar 220 which is placed on the upper projection piece 120 of the integrated lightweight assembly and lattice-reinforced;
Hooks are formed on the upper and lower portions of the support shaft 231, and the upper hooks 232a are hooked to the upper slab 220 and the lower hooks 232b are hooked to the side connecting pieces 130 of the integrated lightweight assembly. A fixed hook 230 for fixing and restraining the upper slab upper reinforcing rod 220 and the integrated lightweight assembly 100;
Slab concrete 240 which is cured to a thickness in which the slab lower reinforcement 210 and the slab upper reinforcement 220 are embedded;
The lower reinforcing bar 251 and the upper reinforcing bar 252 is a reinforcing spacer 250 configured to be assembled and connected to the connecting bolt 253;
The reinforcing spacer 250 is installed so that the connecting bolt 253 passes through the through hole 151 of the corner connecting piece of the integrated lightweight assembly,
The slab lower reinforcement 210 is seated on the lower reinforcing bar 251 of the reinforcement spacer,
The slab upper reinforcing bar 220, the two-way hollow slab, characterized in that seated in the upper reinforcing bar 252 of the reinforcement spacer. delete delete

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