KR101508315B1 - The buoyancy protection device of hollow former using rotation - Google Patents

Abstract

The present invention relates to an apparatus for preventing buoyancy of a hollow slab provided with a hollow body, comprising: a slab former in which a mold hole is formed at regular intervals; A reinforcing bar made of a T-shaped section and covering the upper reinforcing bar of the hollow slab; And a hole formed in the shape of a circular plate and extending downward from the center of the head portion and having the same shape as the mold hole of the slab formwork And an anchor portion formed by a step formed of a thickness and a hook portion formed to extend through the mold hole of the slab former and extending to the lower end of the step portion, wherein the anchor portion has a width smaller than that of the engaging portion And the fastening portion is pierced so that the step portion is positioned in the form hole of the slab former. Thereafter, the reinforcing bar is rotated so that the fastening portion is caught by the lower portion of the slab form and does not fall out.
In addition, the present invention is characterized in that the form hole of the slab formwork is formed in a rectangular shape, and when the anchor part is inserted into the form hole and rotated 90 °, the reinforcing bar is perforated so that both ends of the reinforced-

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an apparatus for preventing buoyancy of a hollow body using rotation,

The present invention relates to an apparatus for preventing floating of a hollow body even when concrete is installed in a hollow slab having a hollow body, and more particularly, to an apparatus for preventing buoyancy by fixing a buoyancy preventing apparatus using rotation of an anchor, To a device for preventing injury to the body.

The hollow core slab as shown in FIG. 1 has a hollow core at its center. As the weight of the panel is reduced, the hollow core slab has a relatively excellent sectional performance as compared with its own weight. Such a hollow core slab has a long span ) And flat slabs, as well as the advantage of reducing noise between layers.

Generally, hollow hollow slabs are generally used as PC products manufactured at factories because it is difficult to work on site such as hollow formation. However, it is pointed out that the hollow slab of the factory is not only required to have separate machinery but also has a complicated manufacturing process for hollow formation. In addition, since the slab structure itself is a complete slab structure, it is natural that it has a weight greater than a certain level, which is inconvenient in terms of conveying and conveying thereof. Further, the problem of complicating the end structure of the hollow slab for integrally joining the column or the beam have. In order to solve such a problem, a method of forming a hollow into a hollow body such as a styrofoam has been proposed. That is, a hollow body is disposed at a position where the hollow is to be formed so as to be embedded in the concrete poured at the site.

However, if such a hollow body is installed on the formwork and the concrete is laid, the hollow body easily floats due to the concrete insertion pressure and the concrete load, so that it is difficult to be embedded in the concrete properly. In order to solve the above problems, the buoyancy anchor of the prior art is formed by perforating a die to secure sufficient strength against buoyancy and fixing the device so that it can not escape from the lower part of the die. Meanwhile, in order to install and dismantle the buoyancy prevention device, the conventional technique needs to be performed at least two times in the lower part of the formwork. Since the height of the slab is usually 2.5 m or more, an auxiliary device such as a ladder should be used. There are many obstacles, such as a problem that the work is inconvenient and dangerous. In addition, the conventional technique requires a separate labor force, which raises the labor cost and increases the construction period.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems of the related art. The purpose is as follows.

First, in the construction of the hollow slab using the apparatus for preventing buoyancy of the hollow body provided in the hollow slab, the position of the hollow body is stably fixed by suppressing the floating of the hollow body even if the concrete is installed, And to provide a device for preventing buoyancy of a hollow body using rotation to secure a precise covering thickness and a position of a reinforcing bar.

Second, the present invention intends to provide a buoyancy prevention device for a hollow body using rotation that can be installed by an inexperienced person simply by installing an apparatus for preventing buoyancy of a hollow body provided in a hollow slab.

Third, the present invention aims to provide a buoyancy prevention device which does not require a separate removal operation from the lower part of the slab formwork by designing the anchor portion excluding the head portion after the concrete curing to be removed together with the form demolding.

According to an aspect of the present invention, there is provided an apparatus for preventing buoyancy of a hollow slab having a hollow body, the apparatus comprising: a slab die having die holes formed at regular intervals; A reinforcing bar made of a T-shaped section and covering the upper reinforcing bar of the hollow slab; And a hole formed in the shape of a circular plate and extending downward from the center of the head portion and having the same shape as the mold hole of the slab formwork And an anchor portion formed by a step formed of a thickness and a hook portion formed to extend through the mold hole of the slab former and extending to the lower end of the step portion, wherein the anchor portion has a width smaller than that of the engaging portion And the hook portion is rotated so that the hook portion is caught by the lower portion of the slab form so that the hook is not pulled out, thereby preventing buckling of the hollow form body using rotation. do.

Further, in the present invention, the form hole of the slab form is formed in a rectangular shape, and when the anchor portion is inserted into the form hole and rotated 90 °, the reinforcing bar is perforated so that both ends of the reinforcing bar are struck on the adjacent upper reinforcing bar. A device for preventing buoyancy of a hollow body used is provided.

According to the present invention, the following effects are expected.

First, the apparatus for preventing buoyancy of a hollow body using rotation of the present invention secures the position of the hollow body to be stably fixed by suppressing the floating of the hollow body even if the concrete is laid, There is an effect of improving the structural stability by using the buoyancy prevention device.

Secondly, since the installation work of the buoyancy preventing device of the hollow body provided in the hollow slab is easily performed at the upper part of the slab formwork, the workability can be improved and the construction period can be shortened.

Third, the present invention is designed to remove the anchor portion except the head portion after the concrete curing together with the form demolding, so that the labor cost required for the mold demolding and finishing process can be greatly reduced and the construction time can be shortened.

1 is a view showing a conventional hollow slab.
2 is a perspective view showing an apparatus for preventing buoyancy using rotation according to the present invention.
FIGS. 3 and 4 are views showing that a buoyancy preventing apparatus using rotation according to the present invention is installed in a slab formwork.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

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FIG. 2 is a perspective view showing an apparatus for preventing buoyancy using rotation according to the present invention, and FIGS. 3 and 4 are views showing an apparatus for preventing buoyancy using rotation according to the present invention installed in a slab formwork.

The apparatus for preventing buoyancy using rotation according to the present invention is a device for preventing buoyancy of a hollow slab (S) provided with a hollow body (V), comprising: a slab die (F) formed with a die hole (FH) at regular intervals; A reinforcing bar 100 made of a T-shaped section and covering the upper reinforcing bars R of the hollow slab S; And a head 220 connected to the lower end of the reinforcing bar 100 and formed with a hole through which the end of the reinforcing bar 100 is inserted and connected to the center, A step portion 240 extending downward from the center of the step portion 240 and configured to have the same thickness as the form hole FH of the slab form F and a stepped portion 240 extending from the lower end of the step portion 240, The anchor portion 200 is formed such that the step portion 240 has a width smaller than that of the engaging portion 260 And after the engaging portion 260 is pierced so that the step portion 240 is positioned in the form hole FH of the slab form F, the reinforcing bar binding bar 100 is rotated so that the engaging portion 260 is engaged with the slab die The form hole FH of the slab form F is formed in a rectangular shape and the anchor portion 200 is formed in a rectangular shape, The reinforcing bar 100 is inserted into the mold hole FH and then punched so that both ends of the reinforcing bar 100 are extended to the adjacent upper reinforcing bar R.

In particular, when the slab form F is demolded after the concrete curing, the buoyancy preventing apparatus using the rotation of the present invention removes the step portion 240 and the retaining portion 260 together to remove the member from the lower portion of the slab form F No additional work is required. At this time, although not shown in the figure, a predetermined cutting groove is formed on the surface where the head 220 and the step 230 meet, so that the step 230 is more easily removed when the slip form F is demolded .

As shown in FIG. 2, the reinforcing bar 100 is composed of a member having a T-shaped cross section and extends over the upper reinforcing bar R of the hollow slab S to prevent buoyancy of the hollow forming member V It plays a role. The horizontal portion of the reinforcing bar 100 is extended over the upper reinforcing bars R of the hollow slab S and the length thereof is longer than the spacing of the upper reinforcing rods R, And a length corresponding to the height up to the slab formwork (F). The reinforcing bar 100 may be made of the same material as the soft steel bar and may be made of various materials as long as it has strength enough to prevent the buoyant force of the hollow forming body V. [ In addition, the ends of the vertical part of the reinforcing bars 100 may be formed of spiral protrusions, which will be described in more detail in the description of the anchor part 200 to be described later.

2, the anchor portion 200 includes a head portion 220, a step portion 240, and a latch portion 260. The anchor portion 200 is preferably made of a plastic material, since it is easy to remove the slab form F when it is demolded. In addition, the plastic is excellent in moldability, which makes it easier to produce an anchor portion 200 having a shape corresponding to the size of the form hole FH of the slab form F.

The head part 220 serves to connect the reinforcing bar 100 and the anchor part 200. In other words, the head 220 is formed in the shape of a circular plate as a whole, a hole is formed at the center, and an end of the reinforcing bar binding bar 100 is inserted into the hole to connect the reinforcing bar binding bar 100 and the anchor portion 200 . The head portion 220 is threaded on the inner surface of the hole formed at the center and the end of the reinforcing bar binding bar 100 is formed of a spiral protrusion so that the end of the reinforcing bar binding bar 100 is formed at the center of the head portion 220 It is preferably inserted into the hole by bolting. 2, the end portion of the reinforcing bar binding bar 100 is more stably connected to the head portion 220 (see FIG. 2), and the head portion 220 is formed with a protrusion 230 on the circular plate, However, the present invention is not limited thereto as long as the head 220 and the reinforcing bar 100 can be stably connected.

The step portion 240 is formed to protrude downward from the center of the head portion 220 and has the same thickness as the form hole FH of the slab form F. The width of the step portion 240 is the same as the width of the reinforcing bar binding bar 100, And it is desirable to rotate in the form hole FH.

The latching portion 260 extends from the lower end of the step portion 240 and is formed to have the same width as the formwork FH of the slab formwork F and penetrate the formwork FH. The anchor 200 is also rotated so that the engaging portion 260 is caught by the lower portion of the slab form F so as not to fall into the form hole FH when the reinforcing bar 100 is rotated. The latching part 260 may be formed to have a width smaller than that of the formwork FH as long as it does not fall into the formwork FH after being caught by the lower part of the slab formwork F, The shape is also possible.

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While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

It is therefore intended that the appended claims cover such modifications and variations as fall within the true scope of the invention.

S: hollow slab
V: hollow body
F: Slab formwork
FH: Form hole
R: Upper reinforcing bar
100: Reinforcing bar
200: anchor portion
220: Head
230: protrusion
240:
260:
280: elastic part
290:

Claims (11)

An apparatus for preventing buoyancy of a hollow slab (S) provided with a hollow body (V)
A slab form F in which a form hole FH is formed at regular intervals;
A reinforcing bar 100 made of a T-shaped section and covering the upper reinforcing bars R of the hollow slab S; And
A head 220 connected to the lower end of the reinforcing bar 100 and having a hole through which the end of the reinforcing bar 100 is inserted and formed in the shape of a circular plate, A step 234 extending downward from the center of the slab form F and configured to have the same thickness as the form hole FH of the slab form F, An anchor part 200 made up of an engaging part 260 configured to pass through a form hole FH of the anchor part 200;
, ≪ / RTI >
The anchor portion 200 may have a width smaller than that of the engaging portion 260 so that the step portion 240 is positioned in the form hole FH of the slab form F, The engaging portion 260 rotates the reinforcing bar 100 so that the engaging portion 260 is not caught by the lower portion of the slab form F,
The form hole FH of the slab form F is formed in a rectangular shape so that when the anchor part 200 is inserted into the form hole FH and then rotated 90 degrees, (R). The apparatus for preventing buoyancy of a hollow body using rotation according to claim 1, delete delete The method of claim 1,
Wherein the anchor part (200) is made of a plastic material. The method of claim 1,
The head part 220 of the anchor part 200 is threaded on the inner surface of the hole formed at the center and the end of the reinforcing bar binding bar 100 is formed of a spiral protrusion so that the end of the reinforcing bar binding bar 100 Is inserted into the hole formed at the center of the head part (220) by bolting. The method of claim 1,
Wherein the step portion (240) and the engaging portion (260) of the anchor portion (200) are simultaneously removed when the slab formwork (F) is demolded. delete The method of claim 1,
Wherein the head part (220) of the anchor part (200) is formed in a cap shape having a rounded brim with a protrusion (230) formed on a circular plate.
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