KR200404398Y1 - Bottom structure of building - Google Patents

Abstract

The present invention relates to a floor structure of a building. In the present invention, the support protrusions 21 and the anti-vibration rubber 30 are provided at the center and the bottom of the upper surface of the plurality of support members 20 arranged on the upper surface of the concrete slab 10. In addition, seating recesses 41 into which the support protrusions 21 are inserted are formed on the deck plate 40 seated on the upper surface of the support member 20, respectively, between the concrete slab 10 and the deck plate 40. In the buffer space (S) is formed. On the other hand, the upper surface of the deck plate 40 corresponding to the support protrusions 21 of the support member 20 adjacent to each other is provided with a heat insulating material 50 and a reinforcing plate 60, respectively. In addition, a plurality of pipe pipes 70 are arranged on a portion of the top surface of the deck plate 40 corresponding to the seating recess 41 and the top surface of the heat insulating material 50, to fix the pipe pipe 70. An upper layer 80 is provided on the upper surface of the deck plate 40 and the upper surface of the heat insulating material 50. Meanwhile, a mesh net 71 is provided on an upper portion of the pipe pipe 70, and an exterior material 90 is provided on an upper surface of the upper layer 80. According to the floor structure of the building according to the present invention, it is possible to ensure the sound insulation and heat insulation performance and at the same time maintain the strength.

Description

Floor structure of building

The present invention relates to a building, and more particularly to a floor structure of a building partitioned up and down the space inside the building.

The interior of the building is provided with a plurality of spaces, such spaces are partitioned from each other by the wall and floor structure. Such a wall and floor structure is configured to enable insulation and sound insulation to prevent noise or heat from being transferred between each space or between the space and the outside.

Figure 1 shows the floor structure of the building according to the prior art.

As shown therein, the lower portion of the slab is provided with a concrete slab (1). The concrete slab 1 forms a framework of a floor structure to support a load that is substantially loaded. Although not shown, a bottom surface of the concrete slab 1 is provided with an exterior material for forming a ceiling of a lower layer.

And the upper portion of the concrete slab 1 is provided with a sound insulation layer (3). The sound insulation layer (3) serves to block the transmission of noise or heat between the layers through the slab. Therefore, the sound insulation layer 3 is formed of a material having a good performance of blocking the transmission of noise and heat, for example, lightweight foam concrete or heat insulating material may be used.

The upper portion of the sound insulation layer 3 is provided with a pipe 5 such as a boiler tube for heating. In addition, an upper layer 7 is provided on an upper portion of the sound insulation layer 3 in which the pipe pipe 5 is installed. The upper layer 7 is formed of mortar, and at the same time to fix the pipe pipe (5) to form the upper appearance of the bottom structure. Therefore, the surface of the upper layer 7 needs to be precisely finished.

In addition, the exterior material 9 is attached to the surface of the upper layer 7. The exterior material 9 substantially forms the bottom surface of the layer, and the exterior material 9 may be a floor board or a wood board.

However, the floor structure of the building according to the prior art configured as described above has the following problems.

As described above, the sound insulation layer 3 is formed by foaming lightweight foam concrete on the upper surface of the concrete slab 1 or by mounting a heat insulating material. Therefore, since the external force applied to the upper layer 7 is transmitted to the entire concrete slab 1, there may be a disadvantage that the soundproofing is not efficient.

In addition, when the heat insulating material is used as the sound insulation layer 3, it is not easy to secure the strength compared to the case of using lightweight foam concrete. Therefore, the upper layer 7 may not be firmly supported by the sound insulation layer 3, so that the upper layer 7 may be easily damaged by an external impact.

The present invention is to solve such a conventional problem, it is an object of the present invention to provide a floor structure of a building configured to ensure a predetermined sound insulation and insulation performance.

Another object of the present invention is to provide a floor structure of a building configured to minimize the deterioration of strength for securing sound insulation and insulation performance.

According to a feature of the present invention for achieving the above object, the present invention is a slab, a plurality of support members arranged in the longitudinal direction spaced apart by a predetermined interval on the upper surface of the slab, respectively seated on the upper surface of the support member A plurality of deck plates which form a predetermined space between the bottom surface and the slab, a plurality of heat insulators installed on the top of the deck plate, and are arranged long in the longitudinal direction to be spaced apart from the top of the deck plate and the heat insulator by a predetermined distance. It is configured to include a pipe which is provided on the upper surface of the deck plate and the heat insulating material, the upper layer for fixing the pipe pipe, and the outer surface is provided on the upper surface of the upper layer to form a bottom surface.

The support member is provided with a support protrusion formed by protruding upward from a portion of the upper surface thereof, and the mounting plate has a seating recess into which the support protrusion of the support member is inserted.

The heat insulating material is characterized in that it is installed on the upper surface of the deck plate corresponding to the support protrusions of the support member adjacent to each other.

It is characterized in that it further comprises a plurality of anti-vibration rubber is provided on each of the bottom of the support member is in close contact with the upper surface of the slab to absorb vibration.

Characterized in that it further comprises a reinforcing plate provided between the deck plate and the heat insulating material.

The upper layer is formed by curing the mortar that is poured on the upper surface of the deck plate and the heat insulating material, characterized in that the mesh net for reinforcing the upper layer is provided above the pipe pipe.

At least one fixing pin is provided on an upper surface of the anti-vibration rubber, and the support member and the anti-vibration rubber are fixed by inserting the fixing pin into the support member.

The upper surface of the anti-vibration rubber is formed with an insertion groove for inserting the lower portion of the support member, characterized in that the support member and the anti-vibration rubber is fixed by inserting the lower portion of the support member in the state that the adhesive material is provided in the insertion groove. .

According to the floor structure of the building according to the present invention, it is possible to secure a predetermined sound insulation and insulation performance, there is an advantage that the strength of the floor structure is not lowered for this purpose.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the floor structure of the building according to the present invention will be described in more detail.

Figure 2 shows a preferred embodiment of the floor structure of the building according to the present invention.

As shown in the drawing, a plurality of support members 20 are arranged on the upper surface of the concrete slab 10 constituting the floor structure partitioning the floor of the building. The support member 20 is to support the upper layer 80 to be described below, it is arranged long in the longitudinal direction to be spaced apart by a predetermined interval on the upper surface of the concrete slab (10).

And support protrusions 21 are provided in the center of the upper surface of the support member 20, respectively. The support protrusion 21 is formed by protruding upward from the central portion of the upper surface of the support member 20, and the support member 20 is formed in an overall shape by the support protrusion 21.

On the other hand, the anti-vibration rubber 30 is provided on the bottom of the support member 20, respectively. The anti-vibration rubber 30 is substantially in close contact with the upper surface of the concrete slab 10, and serves to prevent noise from being transmitted through the concrete slab 10. The fixing pin P provided on the upper surface of the anti-vibration rubber 30 is inserted into the support member 20 so that both are fixed.

In addition, the deck plate 40 is seated on the upper surface of the support member 20, respectively. The deck plate 40 is formed of a metal material, the mounting plate 41 corresponding to the support protrusion 21 of the support member 20 is formed in the deck plate 40, respectively. Therefore, the deck plate 40 is generally formed in a 凹 shape, and the support protrusion 21 is inserted into the seating recess 41.

In the state where the deck plate 40 is seated on the upper surface of the support member 20, the bottom surface of the deck plate 40 is spaced apart from the upper surface of the concrete slab 10 by a predetermined distance, thereby the concrete slab ( A predetermined buffer space S is formed between the 10 and the deck plate 40. The buffer space (S) performs a kind of buffering function to prevent noise or heat from being transmitted through the concrete slab 10.

And the width of the deck plate 40 is deck mounted on the upper surface of the other support member 20 adjacent to the support member 20, both ends thereof in the state seated on the upper surface of any one of the support member 20 It is determined as a value spaced apart from one end of the plate 40 by a predetermined interval, respectively.

On the other hand, the heat insulating material 50 is provided on the upper surface of the deck plate 40 corresponding to the support protrusions 21 of the support member 20 adjacent to each other. The heat insulating material 50 is for preventing heat from being transferred through the concrete slab 10, and the thickness thereof is determined so that its upper surface is located on the same plane as the seating recess 41 of the deck plate 40. .

Reinforcement plate 60 is provided between the deck plate 40 and the heat insulating material 50, respectively. The reinforcement plate 60 is provided in the remaining portion except for the mounting recess 41 of the deck plate 40, so that both ends of the deck plate 40 adjacent to each other to perform a waterproof function at the same time It may be formed of wood that is waterproofed.

In addition, a plurality of pipe pipes 70 are arranged on the upper surface of the heat insulating material 50 and the portion corresponding to the seating recess 41 of the upper surface of the deck plate 40. The pipe pipe 70 is generally a place where hot water for heating flows, and is arranged in the longitudinal direction to be spaced apart from each other by a predetermined interval.

In addition, an upper layer 80 is provided on an upper surface of the deck plate 40 and an upper surface of the heat insulating material 50 to fix the pipe pipe 70. The upper layer 80 is formed by curing the mortar is poured on the upper surface of the deck plate 40 and the heat insulating material 50, and forms the top appearance of the bottom structure.

Meanwhile, a mesh net 71 is provided on the pipe pipe 70. The mesh net 71 serves to reinforce the upper layer 80 formed by curing the mortar.

The exterior material 90 is provided on the upper surface of the upper layer 80. The sheathing material 90 forms the bottom surface of the layer partitioned by the bottom structure.

3 shows another embodiment of a floor structure of a building according to the present invention.

In the embodiment shown in Figure 3, the insertion groove 31 is formed on the upper surface of the anti-vibration rubber (30). In addition, the support member 20 and the anti-vibration rubber 30 are fixed by inserting a lower portion of the support member 20 in a state where an adhesive is provided in the insertion groove 31.

Hereinafter will be described with reference to the accompanying drawings the process of constructing a preferred embodiment of the floor structure of the building according to the present invention.

4A to 4D illustrate a process of constructing the embodiment shown in FIG. 2.

First, as shown in Figure 4a, the support member 20 is arranged on the upper surface of the concrete slab (10). At this time, the support member 20 is arranged on the upper surface of the concrete slab 10 a plurality of long spaced apart from each other by a predetermined interval, the anti-vibration rubber 30 is provided on the bottom surface of the concrete slab 10 It is in close contact with the upper surface of the.

4B, the deck plate 40 is seated on the upper surface of the support member 20. At this time, the support protrusion 21 of the support member 20 is inserted into the seating recess 41 of the deck plate 40, the buffer space (S) between the concrete slab 10 and the deck plate 40 Is formed.

In this state, as shown in FIG. 4C, the deck corresponding to the portion of the upper surface of the deck plate 40 except for the mounting recess 41, that is, between the support protrusions 21 of the support member 20. Reinforcing plates 60 are respectively installed on the upper surface of the plate 40. And the heat insulating material 50 is installed in the upper part of the said reinforcement board 60, respectively.

Next, as shown in Figure 4d, a plurality of pipe pipes 70 are arranged on the upper surface of the deck plate 40 and the heat insulating material 50, the mesh net 71 on the upper portion of the pipe pipe 70 Install. And mortar is poured on the upper surface of the deck plate 40 and the heat insulating material 50. The pipe pipe 70 is fixed by the upper layer 80 formed by hardening the mortar thus poured, and as shown in FIG. 2, the exterior material 90 is installed on the upper surface of the upper layer 80. Construction is completed.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and various changes and modifications can be made by those skilled in the art to which the present invention pertains within the scope of the claims. It is self-evident.

According to the floor structure of the building according to the present invention, the following effects are expected.

An anti-vibration rubber provided on the bottom surface of the support member supporting the upper layer forming the bottom surface of the layer is in close contact with the upper surface of the slab, and a buffer space for sound insulation and insulation is provided between the slab and the deck plate. Therefore, the sound insulation and heat insulation by the floor structure can be made efficiently, and in particular, it is possible to more effectively block the transmission of noise due to vibration.

The upper layer is supported by the support member arranged on the upper surface of the slab. Accordingly, since the slab is loaded and supported by the upper channel and the supporting member to support the slab, the damage of the floor structure can be minimized.

1 is a cross-sectional view showing a floor structure of a building according to the prior art.

Figure 2 is a cross-sectional view showing a preferred embodiment of the floor structure of the building according to the present invention.

Figure 3 is a cross-sectional view showing another embodiment of the floor structure of the building according to the present invention.

Figures 4a to 4d is a working state showing the process of constructing the embodiment shown in FIG.

Explanation of symbols on the main parts of the drawings

10: concrete slab 20: support member

21: support protrusion 30: dustproof rubber

40: deck plate 41: seating groove

50: insulation 60: reinforcing plate

70: piping pipe 71: mesh net

80: upper layer 90: exterior material

P: fixed pin S: buffer space

Claims (8)

Slab, A plurality of support members arranged on the upper surface of the slab in the longitudinal direction to be spaced apart by a predetermined interval; A plurality of deck plates seated on an upper surface of the support member to form a predetermined space between the bottom surface and the slab, A plurality of heat insulators installed on the deck plate, Pipe pipes arranged in the longitudinal direction to be spaced apart from the upper surface of the deck plate and the heat insulating material by a predetermined interval, An upper layer provided on an upper surface of the deck plate and the heat insulating material to fix the pipe pipe, and The floor structure of the building comprising an exterior material provided on the upper surface of the upper layer to form a bottom surface. The method of claim 1, The support member is provided with a support protrusion formed by protruding a portion of the upper surface upwards, The deck plate is a floor structure of the building, characterized in that the mounting recess is formed is inserted into the support protrusion of the support member. The method of claim 2, The heat insulating material is a floor structure of a building, characterized in that installed on the upper surface of the deck plate corresponding to between the support protrusions of the support member adjacent to each other. The method according to any one of claims 1 to 3, The floor structure of the building, characterized in that it further comprises a plurality of dustproof rubber is provided on each of the bottom surface of the support member in close contact with the upper surface of the slab to absorb vibration. The method of claim 4, wherein The floor structure of the building, characterized in that it further comprises a reinforcing plate provided between the deck plate and the heat insulating material. The method of claim 5, The upper layer is formed by curing the mortar is poured on the upper surface of the deck plate and the heat insulating material, The floor structure of the building, characterized in that the mesh pipe for reinforcing the upper layer above the pipe pipe. The method of claim 6, At least one fixing pin is provided on an upper surface of the anti-vibration rubber, The bottom structure of the building, characterized in that the support member and the anti-vibration rubber is fixed by the fixing pin is inserted into the support member. The method of claim 6, The upper surface of the anti-vibration rubber is formed with an insertion groove for inserting the lower portion of the support member, The bottom structure of the building, characterized in that the support member and the anti-vibration rubber is fixed by inserting the lower portion of the support member in the state that the adhesive material is provided in the insertion groove.