KR20240000170U - Embedded waffle slab system with light weight body and a insulator - Google Patents

Abstract

The present invention relates to a buried waffle slab system in which an insulation layer is integrated, comprising a slab formwork, an insulation material disposed on an upper part of the slab formwork, an embedded lightweight body installed on top of the insulation material and having a square shape, and the embedded lightweight body. It includes a floor slab layer formed on the upper part of the, wherein the embedded lightweight body is at least a square large lightweight body and has a central opening penetrating up and down in the center to fill the upper surface of the insulating material with concrete, so as to form the uppermost floor of the building, etc. The slab in contact with the outside air can also be made of a waffle slab to take advantage of the advantages of the waffle slab. When constructing the insulation layer, a lightweight body is installed on top of the insulation material instead of using an external insulation method, but a large square lightweight body is installed, so it is possible to utilize the advantages of the waffle slab. Unlike when installing a bar-shaped lightweight body or a spherical lightweight body on top of an insulating material, not only is it easy to install and fix the lightweight body, but construction is also easy because workers can use a large lightweight body as a support plate when installing a lightweight body. And it can prevent damage to the insulation material.

Description

Embedded waffle slab system with integrated insulation layer {EMBEDDED WAFFLE SLAB SYSTEM WITH LIGHT WEIGHT BODY AND A INSULATOR}

The present invention relates to a buried waffle slab system with an integrated insulating layer. More specifically, it is a method of realizing the structure of a waffle slab with lattice-shaped ribs by installing a large lightweight body while forming an insulating layer on a slab in contact with the outside air, such as the top floor of a building. It is about a buried waffle slab system.

Recently, in order to secure high ceilings or spacious living spaces in buildings, the massless plate structure type is often applied to increase rigidity by increasing the thickness of the slab. The waffle structure type has been used for a long time to reduce the phenomenon of the building's self-weight increasing as the thickness of the slab increases. However, due to the burden of temporary formwork to create a waffle-shaped form, various methods of installing a lightweight body inside the slab to make it hollow have been put into practical use.

These hollow core slabs are structured with a hollow or lightweight body in the center. By reducing the panel weight, the slab's self-weight is reduced and it has relatively excellent cross-sectional performance. These hollow slabs are designed for long spans and In addition to realizing the advantages of a flatslab, it has the advantage of reducing noise between floors.

As a lightweight body installed in such a hollow slab, a spherical lightweight body is proposed. In this case, since the spherical lightweight bodies are arranged in a grid form, concrete is placed on four sides between adjacent lightweight bodies with one lightweight body as the center. Since it is a filled structure, the volume occupied by the lightweight body within the slab is inevitably reduced, and there is a problem in that the porosity decreases accordingly.

In addition, additional factory processing was required, such as efforts to place small lightweight bodies one by one or assembling them using an assembly net to form separate panels.

In addition, cylindrical or bar-shaped lightweight bodies installed in one-way hollow slabs are being proposed. However, one-way hollow slabs have some problems in reducing the floor height because walls or beams must be installed at both ends, and in order to increase the hollowness ratio, there are some problems in reducing the floor height. When the bar shape is elongated, it becomes difficult to construct electrical conduits or facility piping, and when the spacing between lightweight bodies is increased to facilitate concrete pouring or piping, there is a problem in that the porosity of the hollow slab is lowered and the self-weight of the slab increases. Meanwhile, in order to solve the above-mentioned problem, as disclosed in Korean Patent No. 1220128, a connection module connecting a plurality of lightweight bodies and a wire distribution disposed on the upper part of the lightweight body to form a separation space between the upper reinforcing bar and the lightweight body It is equipped with a pipe module, and the wire piping module has a plurality of body parts fastened to the upper part of the cover part that covers the hollow part of the lightweight body, and a connecting leg part connecting the plurality of body parts, and connects the plurality of lightweight bodies using the connection module. A lightweight module is being proposed that can be easily assembled and is designed to facilitate piping of conduits or facility piping.

Meanwhile, the construction of an insulation layer is necessary in areas that come into contact with the outside air, such as the top floor of the structure. However, when constructing an insulation layer on a slab or waffle slab having a conventional hollow lightweight body, an external insulation method is adopted in which an insulation layer is formed on the upper part of the hollow lightweight body or waffle slab and a finishing layer is formed on the upper part. The internal insulation method is adopted, which involves attaching insulation material first or laying insulation material first and then constructing the slab. However, internal insulation construction is not possible for waffle slabs, and external insulation type waffle slab construction requires waterproofing work on the upper part of the roof slab (structure). The method of constructing insulation and then constructing protective concrete on top of it had the problem that when defects such as water leaks occurred, the insulation had to be repaired, and many defects such as water accumulating in the insulation layer occurred.

In addition, in the case of a hollow slab, a method of installing a hollow lightweight body on top of the insulation material can be adopted. However, when installing a conventional bar-shaped lightweight body or a spherical lightweight body on top of the insulation material, it is difficult to install and secure the lightweight body to prevent buoyancy. In addition, there was a problem that the insulation material was easily damaged when installing the lightweight body, and because the lightweight body installation work had to be done on top of the insulation material, a lot of construction work was required to install the lightweight body.

Korean Patent No. 1220128 (Lightweight module for hollow slab)

The present invention seeks to solve the problems of the prior art described above. The purpose of the present invention is to easily install a large lightweight body on the upper part of the insulation material to form grid-shaped ribs when constructing an insulation layer on a slab in contact with the outside air, such as on the top floor of a building. The aim is to provide a buried waffle slab system that can be easily installed without defects while securing the advantages of a waffle slab by realizing the structure of the waffle slab.

In order to achieve the above-described purpose, the embedded waffle slab system with an integrated insulation layer according to the present invention includes a slab formwork, an insulating material disposed on the upper part of the slab formwork, and a buried lightweight waffle slab system installed on the upper part of the insulating material and having a square shape. It includes a sieve and a floor slab layer formed on top of the buried lightweight body,

The spaced portions between the embedded lightweight bodies form lattice-shaped ribs to form a lightweight waffle slab structure in the shape of a lattice beam, the embedded lightweight body is at least a square large lightweight body, and the embedded lightweight body is made of concrete poured on the slab. Filling the upper surface of the insulation material, supporting the floor slab layer and attaching the insulation material to the concrete, it is characterized in that it is provided with a central opening penetrating up and down in the center of the embedded lightweight body.

Here, the bottom surface of the embedded lightweight body is formed with a concave cut upward, and grooves communicating with the central opening are formed in a lattice shape.

Here, the grooves formed in a grid are filled with cement paste to ensure adhesion between the insulation material and the embedded lightweight body.

Here, the embedded lightweight body is formed of an upper lightweight body and a lower lightweight body that are engaged and fastened to each other, the upper lightweight body and the lower lightweight body are formed in a square plane, and the upper lightweight body has a plurality of upper hollow parts in the portion. wherein the lower lightweight body has a lower hollow portion corresponding to the upper hollow portion therein, and when the upper lightweight body and the lower lightweight body are fastened, the upper hollow portion and the lower hollow portion are connected to the embedded lightweight body. It is characterized in that it forms an internal hollow part of.

According to the embedded waffle slab system according to the present invention having the above-described configuration, the slab in contact with the outside air, such as the top floor of a building, can also be configured as a waffle slab to take advantage of the advantages of the waffle slab.

In addition, when constructing the insulation layer, a lightweight body is installed on the top of the insulation material without using an external insulation method. However, because a square large lightweight body is installed, it is different from the case where a conventional bar-shaped lightweight body or a spherical lightweight body is installed on the top of the insulation material. In addition, it is easy to install and fix lightweight bodies, and when installing lightweight bodies, workers can use large lightweight bodies as support plates, making construction easy and preventing damage to the insulation.

In addition, according to the present invention, concrete can be filled through the central opening while using a large embedded lightweight body, so it is easy to form the insulation located at the bottom of the buried lightweight body integrally with the slab concrete, and the large embedded lightweight body can be By applying it, the construction manpower required for slab installation can be reduced and the void ratio improved, while slab quality can be improved by eliminating the voids in concrete that inevitably occur when installing large lightweight bodies.

In addition, according to the present invention, a concrete layer penetrating the embedded lightweight body is formed by concrete poured through the central opening of the buried lightweight body, so in the case of a large embedded lightweight body, it is easy to cause damage due to external shock. It is designed to prevent damage to the lightweight body and improve the structural safety of the lightweight body so that the lightweight body can be stably supported.

In addition, grid-shaped grooves are formed on the bottom of the buried lightweight body so that the cement paste can further attach the lightweight body and the insulation material.

Figure 1 is a cross-sectional view of a buried waffle slab system with an integrated insulation layer according to the present invention.
Figure 2 is a view showing the embedded lightweight body of the present invention, Figure 2a is a perspective view, and Figure 2b is a cross-sectional view along the longitudinal direction of the central opening.
Figure 3a is a view showing the bottom of the embedded lightweight body of the present invention, and Figure 3b is a cross-sectional view of the embedded lightweight body.
Figure 4a is a perspective view of the upper lightweight body of the embedded lightweight body of the present invention viewed from the bottom, and Figure 4b is a perspective view of the lower lightweight body viewed from the top.

Hereinafter, with reference to the attached drawings, a buried waffle slab system with an integrated heat insulating layer according to the present invention will be described in detail as an example.

As shown in Figures 1 to 4b, the embedded waffle slab system (1) with an integrated insulation layer according to the present invention includes a slab formwork (2), an insulation material (4), an embedded lightweight body (10), and a finishing layer ( 20).

The slab formwork 2 is formed of a formwork plate supported by supports 2a. For example, the slab form may be formed of a form plate supported by joists and yoke members, or may be formed of euroform or system form. The form plate is formed as a flat plate and may be made of various materials such as a panel, plywood, or steel plate.

An insulating material (4) is installed on the top of the slab formwork (2). The insulation material may be formed as a unit cut to a certain size and placed on top of the slab formwork.

An embedded lightweight body 10 is disposed on top of the insulating material.

The embedded lightweight body 10 is formed as a large lightweight body. For example, the embedded lightweight body 10 may be formed as a square large lightweight body with a size of approximately 640 * 640 mm.

A central opening 13 is formed in the center of the embedded lightweight body 10. As shown in FIG. 2B, the central opening 13 is formed to penetrate vertically through the embedded lightweight body 10 in the thickness direction.

The central opening 13 is formed by being cut long along the longitudinal direction of the embedded lightweight body. For example, if the embedded lightweight body 10 has a size of approximately 640 * 640 mm, the length of the central opening 13 is formed in a range of approximately 230 to 440 mm, and as shown in Figure 2b, slab concrete When pouring, it is configured so that the concrete flowing in through the central opening 13 can be tightly filled with the insulation material located at the bottom of the embedded lightweight body without any gaps.

When installing a hollow lightweight body on top of an insulating material, it is difficult to faithfully pour concrete between the insulating material and the lightweight body, so only small lightweight bodies have to be used. However, according to the present invention, a large embedded type can be installed while installing a hollow slab. By forming a waffle slab using a lightweight body, the advantage of forming a waffle-shaped ribbed slab can be applied to the slab.

According to the present invention, concrete can be filled through the central opening while using a large embedded lightweight body instead of a small lightweight body, so that the concrete is tightly sealed without any gaps between the insulating material located at the bottom of the embedded lightweight body. It can be filled with

In addition, since the concrete poured through the central opening of the embedded lightweight body forms a concrete layer penetrating the embedded lightweight body, damage to the lightweight body is likely to occur due to external impact in the case of large embedded lightweight bodies. It is designed to prevent and improve the structural safety of the lightweight body so that the lightweight body can be stably supported.

Meanwhile, grid-shaped grooves 122 and 123 are formed on the bottom of the embedded lightweight body 10. The grid-shaped grooves 122 and 123 are formed by cutting concavely from the bottom surface 121 of the embedded lightweight body toward the upper side.

The groove 122 is formed to be perpendicular to the longitudinal direction of the central opening 13. In addition, horizontal grooves 123 are further formed on the bottom surface 121 in a direction perpendicular to the grooves 122 to form grid-shaped grooves.

A second groove (not shown) may be further formed on the bottom of the embedded lightweight body. The second groove is formed in a direction perpendicular to the groove 122, but is deeper than the groove, so that when slab concrete is poured, the concrete can be tightly filled through the gap between the second groove and the insulation material. Slab concrete can be poured more tightly.

In this embodiment, the embedded lightweight body 10 is formed in a square shape and is applied to a two-directional hollow slab arranged at regular intervals in four directions, front, rear, left and right.

The embedded lightweight body 10 may be formed of a solid foam plastic material, or may be formed of a single lightweight body having a certain thickness as a foam plastic material or a plastic material, as shown in FIGS. 3A to 4B. It may be formed of an upper lightweight body 11 and a lower lightweight body 12 that are engaged and fastened to each other.

The upper lightweight body 11 and the lower lightweight body 12 are formed in a square plane, and steps are formed at the lower and upper ends, respectively, so that they can be connected by forming a step surface at the cut surface.

As shown in FIG. 4A, the upper lightweight body 11 has a plurality of upper hollow portions 115 therein. The central opening 13 is formed in the upper lightweight body 11.

As shown in Figure 4b, the lower lightweight body 12 has a lower hollow portion 125 corresponding to the upper hollow portion therein, and the central opening 13 is formed in the lower lightweight body 12. do.

When the upper lightweight body and the lower lightweight body are fastened, the upper hollow portion and the lower hollow portion form an inner hollow portion of the embedded lightweight body, and the central opening 13 opens the embedded lightweight body 10. It is formed by penetrating upward and downward.

Since the area where the lower surface of the lightweight body contacts the insulation material is large, buoyancy does not occur significantly. Therefore, it is possible to fix the lightweight body to the insulation material by applying a simple adhesive to the lower surface of the lightweight body. The adhesive plays a role in fixing the material during construction, and cement paste is filled in the central hole and the grid-shaped groove of the lightweight body to permanently fix the insulation material.

As described above, according to the present invention, the slab in contact with the outside air, such as the top floor of a building, can also be composed of a waffle slab to take advantage of the advantages of the waffle slab, and when constructing the insulation layer, a lightweight material is placed on top of the insulation material instead of using an external insulation method. While installing, since a large square lightweight body is installed, unlike when installing a conventional bar-shaped lightweight body or a spherical lightweight body on top of the insulation material, not only is it easy to install and fix the lightweight body, but the worker is also required to install the lightweight body when installing the lightweight body. Because a large, lightweight body can be used as a support plate, construction is easy and damage to the insulation material can be prevented.

In addition, since concrete can be filled through the central opening while using a large embedded lightweight body instead of using a small lightweight body as in the past, the concrete is sealed tightly without any gaps between the insulation material located at the bottom of the embedded lightweight body. It can be filled with concrete, and structural safety can be improved by forming the insulation material integrally with the slab concrete layer by concrete poured into the central opening.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications and changes are possible without departing from the technical spirit of the present invention, as is commonly known in the technical field to which the present invention belongs. It will be clear to those who have the knowledge of.

1: Hollow slab system
2: Slab formwork
4: Insulation
10: Buried lightweight body
13: central opening
122, 123: Grid grooves

Claims (4)

slab formwork,
An insulation material disposed on the upper part of the slab formwork,
An embedded lightweight body installed on top of the insulation material and having a square shape,
It includes a floor slab layer formed on top of the buried lightweight body,
The spaced portions between the embedded lightweight bodies form lattice-shaped ribs to form a lightweight waffle slab structure in the shape of a lattice beam,
The embedded lightweight body is at least a square large lightweight body,
The embedded lightweight body fills the upper surface of the insulation material with concrete poured into the slab, supports the floor slab layer, and has a central opening penetrating upward and downward through the center of the embedded lightweight body so that the insulation material is attached to the concrete. A buried waffle slab system with an integrated insulation layer.
According to claim 1,
A buried waffle slab system with an integrated heat insulation layer, characterized in that the bottom surface of the buried lightweight body is cut concavely upward and grooves communicating with the central opening are formed in a lattice shape.
The method of claim 1 or 2,
A buried waffle slab system with an integrated insulation layer, characterized in that the grooves formed in a grid are filled with cement paste to ensure adhesion between the insulation material and the embedded lightweight body.
According to claim 1,
The embedded lightweight body is formed of an upper lightweight body and a lower lightweight body that are engaged and fastened to each other,
The upper lightweight body and the lower lightweight body are formed in a square plane,
The upper lightweight body has a plurality of upper hollow portions therein, and the lower lightweight body has a lower hollow portion therein corresponding to the upper hollow portion,
A buried waffle slab system with an integrated heat insulation layer, characterized in that when the upper lightweight body and the lower lightweight body are fastened, the upper hollow portion and the lower hollow portion form an internal hollow portion of the embedded lightweight body.