KR20120126445A - Insulating meterial for floor and floor structure of building using the same - Google Patents

Abstract

PURPOSE: A buffer material for a floor and a floor structure of a building using the same are provided to reduce vibration by forming a double space between an insulation material and a slab and circulating air to the double space. CONSTITUTION: A buffer material for a floor comprises a support plate(100) and vibration-proof mounts(200). Multiple coupling holes(110) and circulation holes(120) are formed in the support plate at uniform intervals. A coupling protrusion(210) is formed on the top of each vibration-proof mount and is inserted into the coupling holes of the support plate. Legs(220) are formed on the bottom of the each vibration-proof mount and disperse shock transferred from the top. The coupling protrusions have a thicker thickness than the support plate to be protruded to the top of the support plate.

Description

Floor cushioning material and interlayer floor structure using the same {Insulating meterial for floor and floor structure of building using the same}

The present invention relates to a floor cushioning material that is constructed in an interlayer floor structure of an apartment house and an interlayer floor structure using the same.

In general, the floor structure of multi-unit houses such as apartments and villas is attached with a wall finish on the bottom of the wall, and then a floor insulation of about 30 mm is laid on the concrete slab, and light-weight foamed concrete of about 40 mm is placed on the concrete slab, and heating pipes are placed thereon. It is made by laying the finishing mortar of around 40mm in the fixed state.

Initially, the floor insulation was constructed in the form of a single plate having a thickness of 20 to 30 mm, and was constructed for heating purposes. Afterwards, the floor insulation material was formed to have a protrusion on the bottom of the plate to be advanced to have a dustproof function. Furthermore, an independent type of floor cushioning material which is installed under the floor insulation material has been developed to improve the dustproofing function. Recently, in order to further increase the function and function, the support plate and the dustproof mount are assembled in various forms.

Thus, the recently invented bottom cushioning material has a form in which protrusions or grooves are formed at the bottom of the support plate, and the dustproof mount is formed with grooves or protrusions to be fitted to each other. The bottom cushioning material of this type has a structure in which a dustproof mount is coupled to the bottom of the support plate while the top surface of the support plate is flat. In addition, the floor cushioning material is such that the front, rear, left and right of the neighboring support plate overlap each other when the floor cushioning material is completely partitioned.

However, according to such a floor cushioning material, the flat upper surface of the support plate is in contact with the floor insulation material, so when an impact occurs from the upper side, the vibration energy is transmitted to the entire support plate. It was transmitted to the lower layer through, which reduced the interlayer dustproofing and sound insulation.

In addition, the dustproof mount may be viewed as a point contact because there is much less contact surface with the slab than a floor insulation material or a support plate, but when only one dustproof mount is placed, the bottom of the dustproof mount and the slab are formed to face contact with each other. More vibration energy was transferred to the lower layer, which reduced the interlayer dustproofing and sound insulation functions.

In addition, since the support plate is in close contact with the bottom heat insulating material, a sealed space is formed at the lower portion of the lower portion of the mount, so that when an impact occurs from the upper side, the sound energy diffuses into the sealed space through the support plate, thereby generating a resonance phenomenon. As a result, sound energy was transferred to the lower layer, which further deteriorated the interlayer dustproofing and sound insulation.

This resonance phenomenon is because the air in the sealed space can not be escaped, it is trapped, in order to prevent such a resonance phenomenon in the past has also made a space to escape through the wall.

The present invention is to provide a floor cushioning material and an interlayer floor structure using the same to reduce the transmission of vibration energy generated from the upper side through the point contact with the floor insulation.

The present invention seeks to provide a floor cushioning material and an interlayer floor structure using the same for minimizing the transmission of vibration energy through the minimum point contact between the dustproof mount and the concrete slab.

The present invention is to provide a floor buffer material and an interlayer floor structure using the same to form a double space between the floor insulation and the slab, and to reduce the resonance phenomenon by allowing air to communicate in the vertical space.

Bottom cushioning material of the present invention is a support plate formed by passing through the plurality of coupler and communication port at a predetermined interval up and down; And a coupling protrusion for fitting to the coupling hole of the support plate at the upper portion, and a bridge formed at equal intervals so as to disperse the impact transmitted from the upper portion, and the coupling protrusion is formed thicker than the thickness of the support plate. It is configured to include; dust-proof mount formed to protrude above the support plate.

The communication sphere is formed between each coupling sphere or four sides.

A locking jaw is formed on the upper side of the coupling protrusion so as not to protrude from the coupling hole while protruding upward from the coupling hole.

One or more embossed protrusions are formed at the bottom of each leg of the dustproof mount.

The support plate forms an uneven portion protruding up and down, the coupling portion is formed in the convex portion protruding upward, the communication port is formed in the concave portion protruding downward.

The support plate is press-molded after extrusion molding to a predetermined thickness to form a uniform thickness of the uneven portion.

The present invention is an interlayer floor structure in which a floor cushion is constructed between a concrete slab and a floor insulation, wherein the floor buffer includes a support plate having a plurality of couplers and communication holes penetrated up and down at a predetermined interval; And a dustproof mount formed by protruding the upper and lower legs which are divided at equal intervals so as to disperse the force and the coupling protrusion for fitting the fitting into the coupling hole, wherein the coupling protrusion protrudes above the support plate to support the bottom heat insulating material, The support plate is formed so that the air communicates through the communication port while partitioning the vertical space between the concrete slab and the floor insulation.

The support plate forms a concave-convex portion protruding up and down, and a coupler is formed in the convex portion protruding upward.

The bottom cushioning material and the floor insulation are formed in a thickness ratio of 1: 2.

It is formed to include; pores for entering the air between the concrete slab and the support plate to the outside.

According to the floor cushioning material of the present invention and the interlayer floor structure using the same, the floor insulation material and the support plate are contacted only by the dustproof mount instead of the surface contact, thereby minimizing vibration and sound energy transmitted to the lower layer when an impact occurs from the upper side, thereby improving product performance. The effect is further improved.

According to the floor cushioning material of the present invention and the floor structure using the same, the dust-proof mount and the concrete slab are in point contact by a plurality of embossing protrusions, thereby minimizing the transmission of vibration energy through minimal contact, thereby improving the performance of the product. There is.

According to the floor cushioning material of the present invention and the interlayer floor structure using the same, a double space is formed between the floor insulation material and the concrete slab by the support plate, and the air is communicated to the upper and lower spaces so that the resonance phenomenon is canceled by the upper and lower spaces communicated. The performance of the product is further improved.

Figure 1 is a perspective view of the floor cushioning material to which the present invention is applied.
Figure 2 is a bottom perspective view showing a bottom cushioning material to which the present invention is applied.
Figure 3 is a front view showing a floor cushioning material to which the present invention is applied.
4 is a cross-sectional view taken along the line AA showing the floor cushioning material to which the present invention is applied.
5 is a cross-sectional view taken along the line BB showing the floor cushioning material to which the present invention is applied.
Figure 6 is a plan view showing an installation state of the floor cushioning material to which the present invention is applied.
Figure 7 is a plan view showing a support plate of the floor cushioning material to which the present invention is applied.
Figure 8 is a perspective view showing the mount of the floor cushioning material to which the present invention is applied.
Figure 9 is a plan perspective view showing another embodiment of the floor cushioning material to which the present invention is applied.
10 is a cross-sectional view taken along line CC showing another embodiment of the floor cushioning material to which the present invention is applied.
11 is a cross-sectional view showing an embodiment of an interlayer floor structure using the floor cushioning material to which the present invention is applied.
12 is a cross-sectional view showing another embodiment of an interlayer floor structure using the floor cushioning material to which the present invention is applied.
Figure 13 is a cross-sectional view showing another embodiment of the interlayer floor structure using the floor cushioning material to which the present invention is applied.

Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

The bottom cushioning material of the present invention is composed of a support plate 100 in the form of a thin plate and a plurality of dust mounts 200 coupled to the support plate, as shown in FIGS. 1 to 10.

The support plate 100 is formed in the form of a plate formed in a constant thickness, a plurality of coupling holes 110 and the communication port 120 is formed through the upper and lower at regular intervals on a flat surface. The support plate 100 is for maintaining the gap between the dustproof mount 200 while supporting the dustproof mount 200 so as not to fall, and the space between the concrete slab 10 and the floor insulation 30 up and down The trapped air communicates with each other to prevent resonance.

If the shock plate occurs at any point above the interlayer floor structure, the negative energy causes resonance in the sealed space between the concrete slab 10 and the floor insulation 30. In this case, when a resonance phenomenon occurs in a wide space at the lower side, air is escaped to the upper space through the communication port 120 to prevent the ringing phenomenon. That is, if the support plate 100 and the concrete slab 10 is sealed, when a shock occurs, a large resonance phenomenon occurs as if the drum hits the drum, in which case the communication port 120 is drilled through the support plate 100 and the support plate 100. If the space is formed on the support plate 100 and the concrete slab 10 is like a torn book, even if an impact is applied, the ringing of air does not occur, thereby preventing resonance.

Such a support plate 100 is preferably formed thin in a thickness of about 1 ~ 2mm, for example.

The coupler 110 is for fitting the dustproof mount 200 to be coupled. Preferably, the spacing between neighboring couplers 110 is formed to be, for example, about 150 mm.

The communication port 120 is to allow the air to flow up and down, and thus the support plate 100 should be formed so that the shape can be safely maintained without tearing. An embodiment of the communication port 120 may be formed between four coupling holes 110 or four sides as shown in FIGS. 6 and 7.

As another example, the support plate 100 forms concave-convex portions 130a and 130b that protrude upward and downward, as shown in FIGS. 9 and 10, but the coupling hole 110 is formed in the convex portion 130b that protrudes upward. The communication port 120 is formed in the recess 130a protruding downward. At this time, when the coupler 110 is formed in the recessed portion 130a protruding downward, it is an object of the present invention, because the upper end of the anti-vibration mount 200 does not support the bottom heat insulating material 30 to necessarily protrude upwards. To be formed on the convex portion 130b. When the uneven parts 130a and 130b are formed in the support plate 100, the dustproof mount 200 supports the same between the concrete slab 10 and the floor insulation 30, but is spaced vertically by the support plate 100. Concave-convex portions 130a and 130b formed in the portion cancel the resonance phenomenon.

On the other hand, the support plate 100 on which the uneven parts 130a and 130b are formed is press-molded after extrusion molding to a predetermined thickness so that the uneven parts 130a and 130b have a constant thickness. That is, the uneven parts 130a and 130b do not make the thickness of the support plate 100 thicker or thinner, but are formed in the same thickness by press molding. In Figure 9, the hatching is for distinguishing the uneven portion.

The anti-vibration mount 200 has a coupling protrusion 210 formed at an upper portion thereof and a leg 220 formed at a lower portion thereof, and the coupling protrusion 210 is fitted to the coupling hole 110 of the support plate 100. The legs 220 are formed to be divided at equal intervals in order to disperse the shock transmitted from the upper portion. At this time, the coupling protrusion 110 is formed to be thicker than the thickness of the support plate 110 is formed to protrude to the upper support plate 100, the upper end is in close contact with the bottom heat insulating material 30 while supporting the support plate 100 Is to be spaced apart from the floor insulation (30). The anti-vibration mount 200 is, for example, is formed in a height of about 10mm, the diameter is formed of about 20mm. At this time, in order to protrude upward when the coupling protrusion 210 is inserted into the coupling sphere 110 as described above, for example, the coupling protrusion 210 has a thickness of 2 to 3 mm with respect to the thickness of the support plate 100. It is desirable to form.

A locking jaw 210a is formed at an upper portion of the coupling protrusion 210 to protrude upward from the coupling hole 110 of the support plate 100 so as not to fall out of the coupling hole 110. That is, the diameter of the locking jaw (210a) is formed larger than the diameter of the coupler 110, and is fitted when fitted, so as not to fall out once fitted. At this time, the coupling of the support plate 100 and the vibration mount 200 is preferably to be made automatically by using a mechanical device.

One or more embossing protrusions 230 are formed at the bottom of each leg 210 of the dustproof mount 200. The embossing protrusion 230 is for minimizing the transmission of vibration energy by allowing the lower end of the anti-vibration mount 200 to be in point contact without being in surface contact with the concrete slab 10.

Looking at the interlayer floor structure to which the floor cushioning material is applied as follows.

First, the interlayer floor structure to which the present invention is applied has a structure in which a floor cushioning material is constructed between the concrete slab 10 and the floor insulation 30, and the wall 10 as illustrated in FIGS. 11 to 13, for example. ') Wall finishing material 20 is attached to the lower portion, the lightweight foam concrete 40, the heating pipe 50 and the heating pipe 50 laid on the lightweight foam concrete 40 is placed on the floor insulation 30 The cover includes an interlayer floor structure including a finishing mortar 60 that is poured onto the lightweight foamed concrete 40.

In such a structure, the bottom cushioning material is coupled to the fitting plate 110 and the coupler 110 through which the plurality of coupler 110 and the communication hole 120 are vertically penetrated as shown in FIG. 11. In order to disperse the force with the protrusions 210, the legs 220, which are divided at equal intervals, are constituted by the dustproof mount 200 protruding upward and downward, and the coupling protrusion 210 protrudes upwards from the support plate 100 to the bottom heat insulating material. Supporting the 30, the support plate 100 is characterized in that the air is communicated through the communication port 120 while partitioning the upper and lower spaces between the concrete slab 10 and the bottom insulation (30).

That is, the vibration energy transmitted from the upper side of the floor structure to the floor insulation 30 is distributed and transmitted to each of the vibration mounts 200, and thus the vibration energy distributed to each of the vibration mounts 200 is each leg It is possible to prevent the transfer to the lower layer while being dispersed again through the 220, and if a resonance phenomenon occurs between the support plate 100 and the concrete slab 10 by the negative energy through the communication hole 120 through the upper space As it is offset by the air escape it will be prevented from being transferred to the lower layer.

As another embodiment of the present invention, as shown in FIG. 12, the support plate 100 forms concave-convex portions 130a and 130b protruding up and down, and the coupling part 110 is formed in the convex portion 130b protruding upward. The communication port 120 is formed in the recess 130a protruding downward. According to such a structure, the resonance phenomenon can be more effectively canceled by the uneven parts 130a and 130b formed in the upper and lower parts while maintaining the same thickness of the entire support plate 100.

At this time, the bottom cushioning material and the bottom heat insulating material 30 including the support plate 100 and the anti-vibration mount 200 is preferably formed in a thickness ratio of 1: 2. On the other hand, the bottom heat insulating material 30 is preferably to increase the heat insulating effect by using an elastic neopole heat insulating material.

As another embodiment of the present invention, as shown in FIG. 13, an air gap between the concrete slab 10 and the support plate 100 may be provided with an interlayer bottom structure including a pore 300 for accessing the outside. have. For example, the pores 300 have a plurality of holes formed at a lower end thereof while vertically penetrating an interlayer floor structure in close proximity to a wall, as shown in the drawing. To get out of the room and block it from going downstairs.

According to the configuration of the present invention as described above so that the bottom insulation 30 and the support plate 100 is in point contact only through the dust-proof mount 200 without the surface contact, thereby minimizing vibration and sound energy transmitted to the lower layer when an impact from the upper side occurs. The performance of the product is further improved.

In addition, the point between the dust-proof mount 200 and the concrete slab 10 by a plurality of embossing protrusions 230, it is possible to minimize the transmission of vibration energy through a minimum contact.

In addition, by forming a double space between the floor insulation 30 and the concrete slab 10 by the support plate 100, and by forming the air to communicate in the vertical space, the resonance phenomenon is canceled by the vertical space to the product performance This is further improved.

100: support plate 110: coupler
120: communication port 130a, 130b: irregularities
200: dust mount 210: engaging projection
210a: Jaw 220: Legs
230: embossing
300: pore

Claims (10)

Support plates formed by passing through the plurality of couplers and communication ports at a predetermined interval up and down; And
A coupling protrusion is formed at an upper portion to engage the coupling hole of the support plate, and a lower leg is formed at equal intervals to disperse an impact transmitted from the upper portion, and the coupling protrusion is formed to be thicker than the thickness of the support plate. Floor cushioning material comprising a; dustproof mount protruding upward.
The floor cushioning material according to claim 1, wherein the communication port is formed between each coupling port or at four sides.
The bottom cushioning material of claim 1, wherein a locking jaw is formed on an upper portion of the coupling protrusion to protrude upward from the coupling hole so as not to fall out of the coupling hole.
The floor cushioning material of claim 1, wherein at least one embossing protrusion is formed at each lower end of the dustproof mount.
The bottom cushioning material of claim 1, wherein the support plate forms an uneven portion protruding upward and downward, and a coupling hole is formed in the convex portion protruding upward, and a communication port is formed in the uneven portion protruding downward.
The bottom cushioning material according to claim 5, wherein the support plate is press-molded after extrusion molding to a predetermined thickness to form a uniform thickness of the uneven portion.
In the interlayer floor structure in which a floor cushion is constructed between the concrete slab and the floor insulation,
The bottom cushioning material includes a support plate through which a plurality of couplers and communication ports penetrate the upper and lower sides at regular intervals; And a dustproof mount protruding up and down the legs divided at equal intervals in order to distribute the coupling protrusion and force for fitting to the coupler,
The coupling protrusion protrudes above the support plate to support the bottom heat insulating material, and the support plate is formed to allow the air to communicate through a communication hole while partitioning an upper and lower space between the concrete slab and the bottom heat insulating material. Interlayer floor structure used.
The interlayer floor structure of claim 7, wherein the support plate forms an uneven part protruding upward and downward, and a coupling hole is formed in the convex part protruding upward, and a communication port is formed in the uneven part protruding downward. .
The interlayer floor structure of claim 7 or 8, wherein the floor cushion and the floor insulation are formed at a thickness ratio of 1: 2.
The interlayer floor structure according to claim 7 or 8, wherein the air between the concrete slab and the support plate is formed with pores for entering and exiting to the outside.

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