KR101601629B1 - Hollow Core Deck Plate with Light Weight Body - Google Patents

Abstract

The present invention relates to a hollow deck plate having lightweight bodies capable of obtaining the integrated movement of rebars and concrete by installing lightweight bodies and the rebars not to be met each other and preventing the strength degradation of a hollow slab wherein the concrete is completely cured. The hollow deck plate comprises: a floor plate (300); truss girders (200) coupled to an upper part of the floor plate (300) at a predetermined interval; and lightweight bodies (100) arranged in spaces between the truss girders (200). The truss girder (200) comprises: an upper rebar (210); lattice members (220) gradually widened downwards from a top, of which inner side comes in contact with and is welded to both sides of the upper rebar (210); and lower rebars (230) coming in contact with and welded to an outer bottom of each lattice member (220). The lightweight body (100) comprises: a lower body (110) in a hollow container shape; an upper body (120) in a hollow lid shape coupled to an upper part of the lower body (110) to form the lightweight body (100); and connection protrusion parts (111) horizontally protruding from a front and a rear surface of the lower body (110). The whole height of the upper body (120) is manufactured in various sizes to allow selection of the size in accordance with the thickness of a slab and the connection protrusion parts of the lightweight bodies close to each other come in contact with each other.

Description

[0001] The present invention relates to a hollow deck plate having a light weight body,

The present invention relates to a hollow deck plate having a lightweight body, which is capable of adjusting the height of the lightweight body, and is capable of integrally forming a concrete covering around the reinforcing steel to be laid, Can be sufficiently secured.

Recently, various methods have been put into practice to increase the strength by increasing the thickness of the slab and to hollow the inside of the slab in order to improve the weight and the sound insulation performance in order to increase the height of the building or to secure a spacious living room space. Such a hollow core slab has a hollow body or a lightweight body disposed at the center to reduce the weight of the slab and has a relatively excellent sectional performance. Such a hollow slab has advantages of long span and flatslab Of course, it is also advantageous in reducing the interlayer noise.

As a lightweight body to be installed in such a hollow slab, there has been proposed a lightweight body installed in a two-direction hollow slab as shown in Fig. 1 (Japanese Patent Laid-Open No. 10-2010-0065245). In the hollow slab shown in FIG. 1, a slab formwork is installed at the site, the formwork is supported by a supporting member such as a horseshoe, a slab bottom reinforcing bar and a lower wire mesh are disposed on the slab formwork, The upper wire mesh and the upper reinforcing bar are laid on the light weight body, and then the slab concrete is laid.

However, since the hollow slab using the lightweight body shown in FIG. 1 has a structure in which the lightweight bodies are spaced apart from each other by a considerable distance and filled with concrete between the adjacent lightweight bodies, the volume occupied by the lightweight body in the slab must be reduced, Thereby, there is a problem that the hollow ratio is lowered. In addition, since the upper and lower reinforcing bars and the upper and lower wire meshes are in contact with the upper and lower surfaces of the lightweight body, the integral behavior of the concrete and the reinforcing bars is not guaranteed, A problem arises.

A conventional deck plate for use with a hollow body or a lightweight body has also been developed. The conventional art disclosed in FIG. 2 (Patent Application No. 10-2011-0053684) includes a truss- And a truss girder central insertion portion 140 is formed at the center of a lower portion of the truss girder 130. The upper main thread D11 of the truss girder is fitted to the truss girder end insertion portion 130 and the center insertion portion 140 Respectively. Therefore, since the concrete covering is not formed properly around the upper major axis (D11), the integral behavior of the concrete and the reinforcing bar is not guaranteed and the strength of the hollow slab is lowered.

In order to solve the above 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 new structure of a lightweight structure capable of preventing the strength of a hollow slab after completion of concrete curing by securing integral behavior of reinforcing bars and concrete, And a deck plate provided with a body.

Technical features of the present invention are as follows.

The present invention relates to a hollow deck plate having a lightweight body, which comprises a bottom plate (300); A truss girder 200 coupled to the top of the bottom plate 300 at regular intervals; And a light weight body (100) disposed in a space between the truss girder (200).

The truss girder 200 includes an upper reinforcing bar 210; A lattice material 220 welded on both sides of the upper reinforcing bar 210 and welded to the lower end of the upper reinforcing bar 210; And a lower reinforcing bar 230 welded to the outside of the lower end of each of the lattice materials 220 to be welded.

The light weight body (100) comprises a lower body (110) in the form of a container having an empty interior; An upper body 120 coupled to an upper portion of the lower body 110 to form a lightweight body 100 as a lid shape having an inner space therein; And a connection protrusion 111 protruding horizontally from the front and rear surfaces of the lower body 110, respectively.

Here, the overall height of the upper body 120 may be varied according to the thickness of the slab, and the connection protrusions 111 of the adjacent lightweight body 100 are in contact with each other.

Technical effects of the configuration of the present invention are as follows.

First, the lightweight body 100 and the reinforcing bars (the upper reinforcing bars 210, the lower reinforcing bars 230, the upper reinforcing rods 520, or the lower reinforcing rods 510) can be installed so as not to touch each other, And the strength of the hollow slab can be effectively prevented by securing the integral behavior of the reinforcing bars and the concrete through the coating.

Secondly, the connecting protrusions 111 of the adjacent lightweight bodies 100 are combined so as to be in contact with each other, and a lightweight It is possible to quickly and conveniently install the lightweight body 100 in the space between the truss girders 200 of the deck plate by preventing separation and disconnection of the body 100 and facilitating the handling.

Third, the height of the light weight body 100 can be freely adjusted by appropriately selecting the upper body 120 having a different standard according to the height of the truss girder 200 of the deck plate.

Fourthly, an engaging piece (not shown) is mounted on the upper portion of the upper iron wire 132 while being interposed with the upper iron wire 132 to be fitted to the lower portion of the upper iron core 210 of each of the adjacent truss girders 200 to press the lightweight body 100 firmly The lightweight body 100 can be effectively prevented from floating when the concrete is poured.

Figures 1 and 2 illustrate the prior art.
FIG. 3 is a perspective view of a deck plate provided with a light weight body 100 as a concrete embodiment of the present invention. Respectively.
Fig. 4 shows the structure of the lightweight body 100. Fig.
5 shows that the height of the light weight body 100 can be adjusted by selecting the upper body 120 having a different height.
6 shows a state in which the lightweight bodies 100 are joined in a line.
Fig. 7 shows a structure in which the light weight body 100 is installed and coupled to a space between the truss girders 200. Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

The present invention relates to a hollow deck plate having a lightweight body as shown in Fig.

The bottom plate 300 functions to stably support the overall load during the concrete pouring and curing process and may be formed of any one of plate materials such as plywood, synthetic resin, steel plate, etc. having a predetermined standard (width, length, thickness) However, it may be a simple plate-like shape or a plate-like shape in which protrusions bent at regular intervals are formed. That is, various types of deck plates that are applied to various deck plates that are currently installed or marketed can be freely selected and used.

When the bottom plate 300 is manufactured from plywood or synthetic resin, a separate spacer 400 may be provided between the truss girder 200 and the bottom plate 300.

The spacer 400 may be coupled to the lower reinforcing bar 230 of the truss girder 200 and the lower surface of the spacer 400 may be removably mounted on the upper surface of the bottom plate 300 by bolts or fins , Various kinds of spacers which are applied to various deck plates currently installed or marketed can be freely selected and used.

The spacer 400 can be used when the bottom plate 300 is made of a steel plate and the truss girder 200 can be directly attached to the upper surface of the bottom plate 300 without using a separate spacer 400 Welding may be combined.

The truss girder 200 is coupled to the upper part of the bottom plate 300 at regular intervals.

The truss girder 200 includes upper and lower reinforcing bars 210 and 210. The upper and lower reinforcing bars 210 and 210 are welded to each other at both ends of the upper reinforcing bar 210. The lattice material 220 and the lattice material 220, And a lower reinforcing bar 230 to be welded to each other. The truss girder 200 has the same or similar structure as that of a typical truss girder 200 used for a deck plate, and a detailed description thereof will be omitted.

The lightweight body 100 is disposed in a space between the truss girders 200 and includes a lower body 110 and an upper body 120.

As shown in FIG. 4, the lower body 110 has a hollow container shape, and the hollow space inside the hollow body 110 is filled with a light material such as a lightweight foam or left as an empty space.

A lower end cutout 113 is chamfered in a direction orthogonal to the lower iron roll groove 112 so that the lower reinforcement rods 510 to be laid down do not come in contact with the front and rear lower ends of the lower body 110, .

The upper body 120 is coupled to the upper part of the lower body 110 as a lid shape having an inner space as shown in FIG. 4, and forms the light body 100 together with the lower body 110.

An upper cutout portion 123 chamfered in a direction orthogonal to the upper iron roll groove 122 is provided on the front and rear upper end portions of the upper body 120 so as to prevent the upper boom lift roots 520 from being brought into contact with each other, The surface is processed.

In addition, a top surface cutting groove 124 is formed in the upper surface of the upper body 120 so as not to abut the upper laying roots 520, which are arranged in a direction orthogonal to the upper rope groove 122.

The overall height of the upper body 120 is variously sized as shown in FIG. 5, and the height of the light weight body 100 can be adjusted by freely selecting a standard according to the thickness of the slab.

The connecting protrusions 111 project horizontally on the front and rear surfaces of the lower body 110. When the lightweight bodies 100 are arranged in a row, the connecting protrusions 111 of the adjacent lightweight bodies 100 And the connection protrusions 111, which are in contact with each other, are joined together using an adhesive or the like as necessary.

A lower iron member groove 112 is formed to receive the lower wire 131 along the longitudinal center of the lower body 110 and the upper wire 132 is received along the longitudinal center of the upper body 120 (Not shown).

As shown in FIG. 6, the bottom wire 131 is disposed along the bottoms of the plurality of lightweight bodies 100 arranged in a row and is coupled to the bottom wire 125 for the bottom wire, and the top wire 132 is arranged in a row Is disposed along the upper portion of the plurality of lightweight bodies (100) and is coupled to the upper iron player groove (122).

The lower wire 131 and the upper wire 132 are connected to each other by a connecting piece 133. The connecting piece 133 is shaped like a whole and the upper end of the connecting piece 133 is caught by the upper wire 132, The upper wire 132 and the lower wire 131 are pulled together to be connected to each other while being caught by the lower wire 131.

By using the lower wire 131, the upper wire 132, and the connecting piece 133, it is possible to stably maintain the coupled state of the lightweight bodies 100 arranged in a row, The lightweight body 100 can be quickly and conveniently installed in the space.

As shown in FIG. 3, the connecting pieces 133 may be provided continuously at predetermined intervals for each of the portions where the coupling protrusions 111 are present, or may be intermittently provided (not shown). The connecting piece 133 can be manufactured using a rod or a plate.

3 and 7, a plurality of lightweight bodies 100 joined in a line by the upper wire 132, the lower wire 131 and the connecting piece 133 are arranged in a space between the truss girders 200 Respectively.

The upper reinforcement rope 520 is laid on the upper portion of the upper reinforcing bar 210 in the direction intersecting the upper reinforcing bar 210 of the truss girder 200 and the lower reinforcing rope 510 is routed to the lower portion of the truss girder 200 And is disposed at an upper portion of the lower reinforcing bar 230 in a direction crossing the reinforcing bars 230.

The lower wire 131 coupled to the lower iron player groove 112 formed along the lower surface of the lightweight body 100 is mounted on the upper portion of the lower reinforcement frame 510.

The connecting pieces 240 are mounted on the upper portion of the upper wire 132 while intersecting the upper wire 132. Both ends of the connecting piece 240 are connected to the lower portion of the upper reinforcing bar 210 of each of the adjacent truss girders 200 The lightweight body 100 is firmly pressed to prevent the lightweight body 100 from moving. That is, the engagement piece 240 serves to prevent floating of the lightweight body 100 when the concrete is poured.

The spacing of the engaging pieces 240 can be appropriately adjusted and arranged continuously or intermittently, and can be manufactured using a rod or a plate.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, It will be clear that the present invention falls under the scope of protection of the present invention even in the case of adding or deleting known technology or simply limiting the numerical value.

100: Lightweight body
110: Lower body
111:
112: groove for bottom iron player
113: lower end incision
120: upper body
122: groove for upper iron player
123: upper incision
124: upper surface incision groove
131: bottom wire
132: Upper wire
133: Connection
200: Truss girder
210: Upper reinforcing bar
220: Lattice material
230:
240: Coupling piece
300: bottom plate
400: spacer
510: Lower power train
520: upper booster force

Claims (7)

The present invention relates to a hollow deck plate provided with a light weight body,
A bottom plate 300;
A truss girder 200 coupled to the top of the bottom plate 300 at regular intervals; And
A lightweight body (100) disposed in a space between the truss girders (200);
, ≪ / RTI >
The truss girder (200)
An upper reinforcing bar 210;
A lattice material 220 welded on both sides of the upper reinforcing bar 210 and welded to the lower end of the upper reinforcing bar 210; And
A lower reinforcing bar 230 welded to and welded to the lower end of each of the lattice materials 220;
Lt; / RTI >
The light weight body (100)
A lower body 110 in the form of a container having an empty interior;
An upper body 120 coupled to an upper portion of the lower body 110 to form a lightweight body 100 as a lid shape having an inner space therein;
A connection protrusion 111 protruding in the horizontal direction on the front and rear surfaces of the lower body 110;
A lower iron player groove 112 cut along the longitudinal center of the lower body 110;
An upper iron player groove (122) cut along the longitudinal center of the upper body (120);
A lower wire (131) disposed along the lower portion of the plurality of lightweight bodies (100) arranged in a row and coupled to the lower ironer groove (112);
An upper wire (132) disposed along the upper portion of the plurality of lightweight bodies (100) arranged in a row and coupled to the upper iron slot (122);
And the upper end is hooked on the upper wire 132 and the lower end is hooked on the lower wire 131 to pull the upper wire 132 and the lower wire 131 together to form a connecting piece 133 ); And
The truss girder 200 is mounted on an upper portion of the upper wire 132 while intersecting with the upper wire 132 and is fitted under the upper reinforcement 210 of each of the adjacent truss girders 200, A joining piece 240 for preventing the joining member 240 from being bent;
And,
The overall height of the upper body 120 may be varied according to the thickness of the slab,
A lower end cut-out portion 113 is chamfered in a direction orthogonal to the lower steel bar groove 112 so that the lower reinforcement rods 510 to be laid are not in contact with the front and rear lower ends of the lower body 110,
An upper cutout 123 is chamfered in a direction orthogonal to the upper steel bar groove 122 to prevent the upper reinforcement rods 520 from coming into contact with the front and rear upper ends of the upper body 120,
The lower wire 131 is inserted into the lower ironer groove 112 in a state in which a plurality of lightweight bodies 100 are arranged in a row so that the connecting protrusions 111 of the adjacent lightweight body 100 are in contact with each other And the upper wire 132 and the lower wire 131 are pulled together by the connecting piece 133 after the upper wire 132 is inserted into the upper wire 122 for the upper wire, The engagement state of the body 100 is maintained,
Wherein the lower wire (131) is mounted on an upper portion of a lower reinforcement rope (510) arranged so as to intersect with a lower reinforcing bar (230) of the truss girder (200). The method of claim 1,
A top surface cutout groove 124 cut in a direction orthogonal to the upper steel bar groove 122 is provided at the center of the upper surface of the upper body 120 so as to prevent the upper reinforcement rope 520, The hollow deck plate having a lightweight body. 3. The method according to claim 1 or 2,
A spacer 400 coupled to the lower reinforcing bar 230 of the truss girder 200 and detachably installed on the upper surface of the bottom plate 300;
Wherein the hollow deck plate further comprises a lightweight body. delete delete delete delete

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