KR101553181B1 - Lamination structure for the diminution of noises and vibrations from the floor - Google Patents

Abstract

The present invention relates to an interlaminar noise and vibration reduction laminate. The main panel includes: a main panel on which a plurality of ball grooves are formed; A soft ball having a physical characteristic different from that of the main panel, which is received in a state of being inserted into the ball receiving groove of the main panel and receives vibration energy transmitted from the outside; And a base panel contacting the bottom surface of the main panel at a lower portion of the main panel and supporting the soft ball inside the ball receiving groove.
In the present invention as described above, since a plurality of heterogeneous soft balls are inserted in a predetermined pattern in a main panel made of synthetic rubber, vibration of almost all frequencies coming down to the main panel can be absorbed or attenuated And the thickness of the portion where the soft ball is located in the main panel is made thicker than the thickness of the other portion so that most of the load from the upper portion is guided to be transmitted through the soft ball to maximize the function of the main panel, The ball is provided with the non-woven fabric layer containing air, and the wave energy passing through the main panel passes through the nonwoven fabric layer and causes destructive interference. Thereby realizing a more reliable effect of interlayer noise cancellation.

Description

[0001] The present invention relates to a laminate structure for vibration isolation,

The present invention relates to an interlaminar noise and vibration reduction laminate.

Most of the apartments and some office buildings in Korea are being built with floor heating, unlike apartment houses in Europe and North America. That is, a hot water pipe is arranged on the floor, hot water heated in the boiler is circulated to heat the floor, and the floor is heated by radiant heat from the heated floor.

This type of heating is characterized by relatively heavy floor finishing thickness, which is advantageous for controlling the noise and vibration of the floor. However, since most of the apartment houses in Korea are designed and constructed in the form of a wall type structure, It is easy to transmit the upper and lower layers of the generated noise and vibration.

In other words, the generated living noise is transmitted through the floor and the wall to the adjacent floor in the form of a solid sound transmission, and this is converted to air transmission sound. In this process, Korean house with wall type structure is rather weak will be.

The noise transmitted to the adjacent layer is a lightweight impact sound caused by the impact of a relatively light and hard object such as when the object is dropped or when the furniture is turned off and the weight generated when a heavy and soft impact is applied to the floor, It can be divided into impact sound.

Lightweight impact sound is high frequency sound but weak impact and short duration. On the other hand, heavy impact sound has relatively low sound quality, impact force and long sound duration.

In addition, the size of the lightweight impact sound is greatly influenced by the flexibility of the surface finishing material, while the size of the heavy impact sound is greatly influenced by the stiffness, density, area and fixing conditions of the vehicle or floor or wall.

Considering these characteristics, it is effective to provide a finishing material of a soft material such as a carpet or a rubber mat on the floor adjacent to the noise source in order to control the light weight impact sound. However, in the case of a heavy impact sound, It will be effective to control it. Accordingly, in Korea, the Ministry of Construction and Transportation is regulating construction to be more than a certain slab thickness according to the structure type of apartment house.

It is most effective to block noise or vibration near the source, that is, the place where it occurs, but it is almost impossible due to various constraints in the condition of the apartment in Korea. As a result, many social problems such as the conflict between neighbors are caused by the recent interlayer noise.

On the other hand, the interlayer noise preventing member of a multi-story building disclosed in Korean Patent Registration No. 10-1435993 is characterized in that a buffer panel and a support portion supporting the buffer panel are provided between the foundation bottom layer and the lightweight foamed concrete layer, .

However, the above-mentioned conventional interlayer-noise-preventing member has a problem that the buffer panel made of synthetic resin is supported by the receiving portion and floated from the bottom floor layer, so that the buffer panel is gradually staggered downward over time.

That is, the buffer panel may become fatigued by repeated loads (fluctuating loads or repetitive loads pressed by the occupant's weight), gradually elongate downward, and in some cases, be completely destroyed.

When the cushioning panel is pulled down or broken down, the lightweight foamed concrete layer laid on it is cracked or dented and the hot water piping can be cut off.

In addition, the base made of viscoelastic material can be hardened over time. When the pedestal is cured, the pedestal itself acts as a passage through which vibration and noise pass. That is, the vibration applied to the floor is transmitted to the foundation floor layer in a concentrated state through the support portion. It means that the interlayer noise preventing material does not block the transmission of noise but rather acts as a passage for transmitting noise.

The present invention has been made to overcome the above-described problem, and is intended to replace a heat insulating material layer applied between a concrete slab and a lightweight foamed concrete layer when the ondol layer is installed on the floor of a multi-family house or the like. Therefore, the part except for the layer corresponding to the present invention is the same as the existing construction method.

That is, according to the present invention, a plurality of heterogeneous soft balls are inserted in a predetermined pattern inside a main panel made of synthetic rubber, which is installed in place of the existing heat insulating material in the above-mentioned heat insulating material layer, The vibration of almost all frequencies can be absorbed or attenuated and the thickness of the portion where the soft ball is located in the main panel is made thicker than the thickness of the other portions so that most of the load from the upper portion is transmitted through the soft ball, The present invention aims to provide a layered noise and vibration reduction laminate which is configured to increase the function of the panel to the maximum as well as to allow the soft ball to meet more vibration waves.

Further, according to the present invention, by providing the non-woven fabric layer containing air on the lower part of the main panel, it is possible to induce destructive interference in the process of passing the wave energy passing through the nonwoven fabric layer through the main panel, The present invention has been made in view of the above problems,

In order to attain the above object, the present invention provides an interlayer noise and vibration reduction laminate having a plate shape, a plurality of ball receiving grooves opened in a thickness direction lower portion thereof, and disposed in an upper portion of a concrete slab of a building A main panel having a top surface formed with a protrusion that is deformed by a load applied from the outside and transmits a load to the soft ball; A soft ball having a physical characteristic different from that of the main panel, the dynamic ball being adapted to receive vibration energy transmitted from the outside in a state of being inserted into a ball groove of the main panel; And a base panel contacting the bottom surface of the main panel at a lower portion of the main panel and supporting the soft ball inside the ball receiving groove.

The base panel further includes a nonwoven fabric layer for attenuating vibrational energy passing through the main panel and the base panel.

In addition, the soft ball may include: And a gelatin core which is filled in the inside of the silicon ball and provides a damping force to the outside.

It is also possible that the protrusion is in the form of a quadrangular pyramid.

In addition, the material of the main panel is any one of polychloroprene, butadiene, nitrile, ethylene-propylene, and chlorosulfonated polyethylene.

In addition, the present invention is further characterized in that a side buffering means is provided between the laminate and the wall of the building to block transmission of the vibrations entered through the laminate to the wall.

In the above-described interlaminar noise and vibration reduction laminate of the present invention, a plurality of heterogeneous soft balls are inserted in a predetermined pattern inside a main panel made of synthetic rubber, so that almost all frequencies And the upper portion of the portion where the soft ball is positioned in the main panel is formed into a quadrangular pyramid shape so that most of the load from the upper portion is transmitted to allow the soft ball to meet with more vibration waves Thereby maximizing the noise and vibration blocking effect.

In addition, by providing the non-woven fabric layer containing air on the lower part of the main panel, wave energy passing through the main panel is induced to cause destructive interference in passing through the nonwoven fabric layer, do.

1 is a cross-sectional view illustrating an overall structure of an interlayer noise and vibration reduction laminate according to an embodiment of the present invention.
2 is a cross-sectional view showing another example of the laminate shown in Fig.
FIG. 3 is a view for explaining a coupling structure of the main panel and the soft ball shown in FIG. 1. FIG.
4 is a partially exploded exploded perspective view of the interlayer noise and vibration reduction laminate shown in FIG.

Hereinafter, one embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

Basically, the interlaminar noise and vibration reduction laminate 15 according to the present embodiment is used in a construction such as a multi-story apartment house, a concrete slab at the bottom, It is applied between the foamed concrete layers. This has the ability to resolve the interlayer noise problem by attenuating the vibration energy transmitted through the concrete structure that forms the skeleton of the building.

1 and 2 are sectional views for explaining the overall structure of the interlaminar noise and vibration reduction laminate 15 according to one embodiment of the present invention, Fig. 8 is a view for explaining a coupling structure of a ball.

As will be described later, the main panel 25 in this embodiment has two shapes. One is a protrusion 25d protruding from the rim, and the other is formed with a protrusion receiving recess 25e at the rim. The fitting projections 25d and the projection receiving grooves 25e correspond to each other and engage with each other.

1 is an example in which the main panel 25 having the fitting protrusions 25d is disposed close to the wall 13 and FIG. 2 is an example in which the main panel 25 in which the projection receiving grooves 25e are formed, ).

It is needless to say that whether the fitting projection 25d is close to the wall 13 or the projection receiving groove 25e is close to the wall 13 may vary depending on the construction environment.

As shown in the drawing, the interlayer noise and vibration reduction laminate 15 according to the present embodiment includes a nonwoven fabric 27 laid on an upper surface of a concrete slab 11 forming the bottom of each layer in a building, A main panel 25 stacked on the top of the base panel 29 and a plurality of soft hands 25 inserted and fixed in the main panel 25, And a side cushioning member 31a and 31b which is in contact with the cushioning member 33 installed on the wall 13 at the outermost side of the main panel 25.

The buffer member 33 is a building material surrounding the rim of the laminate 15 according to the present embodiment and has the same height as the height of the laminate 15. The material of the buffer member 33 may be the same as the side buffer members 31a and 31b.

A lightweight foamed concrete layer 21 is laid on the upper part of the main panel 25 and an ondol layer 17 is placed on the lightweight foamed concrete layer 21 in the laminated body 15 having the above- . The ondol layer (17) is a layer having a hot water pipe (19) therein. The surface is smoothly finished, and a top board or other floor material is installed on the top surface.

4, the main panel 25 is formed by a synthetic rubber and has a shape of a square plate having a predetermined thickness. A plurality of projections 25a are formed on the top surface 25b of the main panel 25, And has a ball receiving groove 25c at a lower portion of each protruding portion 25a, that is, at a lower portion in the thickness direction. In the present embodiment, the projecting portion 25a takes the shape of a quadrangular pyramid. In addition, the shape of the projecting portion 25a may have a truncated cone, a triangular pyramid or a pyramidal cone in addition to the pyramidal pyramid.

The ball receiving groove 25c is a spherical groove that opens downward through an inlet 25f and receives the flexible ball 23 therein. Particularly, the inner diameter of the inlet portion 25f is smaller than the maximum inner diameter of the ball receiving groove 25c.

The ball receiving grooves 25c are spaced apart from the neighboring ball receiving grooves 25c and are arranged in parallel to one side of the main panel 25. That is, imaginary straight lines connecting the ball receiving grooves 25c are parallel or orthogonal to each other, and parallel straight lines form a constant gap. The sizes of the respective ball receiving grooves 25c are all the same.

The projecting portion 25a receives a vertical load from the upper portion and is slightly deformed to guide the load to the soft ball 23 side. This is possible because the rectangular rim of the projecting portion 25a is inclined downward, so that the vertical load can be guided to the soft ball 23 side.

A large amount of the load lowered through the ondol layer 17 does not meet with the soft balls 23 and passes through between the soft balls 23 to reach the base panel 29 immediately do.

In any case, the soft ball 23 is instantaneously deformed in the form of an elliptical shape due to the load lowered through the projecting portion 25a, and induces the impact energy from the top to be transmitted in the horizontal direction. Thus, the impact energy transmitted in the horizontal direction from each soft ball 23 collides with each other, for example, between the soft balls 23 and cancel each other out.

In this way, the horizontal force from the four neighboring soft balls 23 acts as a side compressive force on the vertical portion of the main panel 25, so that the vertical axial force due to the confinement effect can be increased.

The load in the present description is a concept including a fixed load and a light / heavy impact load on the main panel 25.

A plurality of main panels 25 are horizontally disposed on the concrete slabs 11 so as to be in close contact with the neighboring main panels 25 to cover the upper surface of the concrete slabs 11 with no gaps, So that the lightweight foamed concrete layer 21 can be laminated thereon.

To this end, the main panel 25 is provided with a fitting protrusion 25d or a protrusion receiving groove 25e on a side surface thereof. As described above, the fitting protrusions 25d are projections formed to protrude from the four sides of the main panel 25. The projection receiving grooves 25e correspond to the fitting projections 25d and are formed on the four sides of the main panel 25. [

Fitting projections 25d are formed in the main panel 25 of about half of the main panels 25 and the projection receiving grooves 25e are applied to the remaining main panels 25. [

Therefore, as shown in Figs. 1 and 2, the main panel 25 having the projection receiving grooves 25e formed on the side surface of the main panel 25 having the fitting projections 25d is disposed, The main panel layer composed of a plurality of main panels 25 is obtained.

As described above, since the fitting protrusions 25d and the protrusion receiving grooves 25e are formed and mutually engaged with each other, the vibration energy entering the boundary portion of the main panel 25 , It can not pass directly through the main panel layer. This is because the transmitted noise and vibration (vibration energy) are blocked inside the projection accommodating groove 25e.

The main panel 25 having the above structure is formed by molding polychloroprene gum or synthetic rubber having butadiene, nitrile, ethylene-propylene, chlorosulfonated polyethylene, and similar physical properties to absorb externally applied vibration .

Meanwhile, the soft ball 23 is a relatively soft soft spherical member than the main panel 25. That is, it is more flexible than the main panel 25.

The soft ball 23 includes a silicon ball 23b having an empty interior and a gelatin core 23a sealingly accommodated in the silicone ball 23b. The volume of the inner space provided by the silicon spheres 23b may vary widely according to the embodiment.

The silicone sphere 23b has elasticity, and the gelatin core 23a to be filled therein is fired as ordinary gelatin. However, when the ball receiving groove 25c of the main panel 25 is deformed by an external load, the shape of the silicon sphere 23b is deformed according to the shape thereof, and the inner gelatin core 23a is a sintered material, The shape of the silicon ball 23b as shown in FIG.

That is, the gelatin core 23a is a sintered body which functions to absorb vibration, but the deformation behavior is an elastic behavior according to the characteristics of the silicon sphere 23b.

The above-described soft ball having a double structure has excellent performance in absorbing vibrational energy from the outside through vibration phenomenon of the molecules themselves in the polymer possessed by silicon or gelatin, and has a function of significantly reducing interlayer noise and vibration .

Particularly, since the gelatin core 23a is sealed inside the silicon sphere 23b, even if vibrations and impact sounds are transmitted, the vibration shock spreads only inside the silicone sphere 23a, so that the gelatin core 23a is not resonant to the outside. It is effective for blocking.

In addition, the soft ball 23 is manufactured to be completely inserted into the ball receiving groove 23c as shown in FIG. Preferably, there is a clearance of about 1 mm between the soft ball 23 and the inward surface of the ball catch groove 23c.

A base panel 29 is positioned below the main panel 25. The base panel 29 is a rectangular plate having a predetermined thickness and is made of the same size as the bottom surface of the main panel 25 and is attached to the lower portion of the main panel 25 with the soft ball 23 inserted therein . Preferably, the main panel 25 is made of synthetic rubber.

Thus, since the base panel 29 is also made of synthetic rubber, even if the vibration passes downwardly through the main panel 25, it is attenuated again by the base panel 29. [

A nonwoven fabric (27) is laid under the base panel (29). The nonwoven fabric 27 forms a single layer and can prevent a rubbing noise that can be issued between the base panel 29 and the concrete slab 11. Particularly, since the concrete slab 11 has good adhesion to uneven surfaces at the time of construction, the workability is also excellent

Since the nonwoven fabric layer made of the nonwoven fabric 27 has a porous property, it has sound absorption, soundproofing, and heat insulating functions. Since the air is contained as mentioned above, the main panel 25 and the base panel 29 The destructive interference of the wave energy passing through the waveguide can be expected to be more reliably prevented.

The cushioning members 33a and 33b and the base panel 29 are provided between the cushioning member 33 and the main panel 25. The cushioning member 33 and the base panel 29 To prevent transmission of vibration energy. Particularly, the side cushioning materials 31a and 31b are manufactured and installed in two forms so as to be combined with the shape of the side portion of the main panel 25, that is, with the fitting protrusion 25d and the projection receiving groove 25e.

The side cushioning materials 31a and 31b may be made of synthetic rubber similar to or similar to the main panel 25.

Fig. 4 is a partially cut away exploded perspective view of the interlayer noise-and-vibration reduction laminate 15 shown in Fig.

As shown in the figure, a plurality of base panels 29 are placed on top of the nonwoven fabric 27, and the main panel 25 is laminated and attached to each base panel 29. It goes without saying that the soft ball 23 is inserted into each of the ball receiving grooves 25c of the main panel 25 at this time. The soft ball 23 is in a flimsy state and the diameter of the inlet 25f of the ball receiving groove 25c is made smaller than the diameter of the soft ball 23 by compressing the soft ball 23 by hand This is because it can be easily fitted into the ball receiving groove 25c.

As a result, the interlayer noise and vibration reduction laminate 15 according to the present embodiment configured as described above has a multi-layered structure with the panels 25 and 29, A plurality of soft balls 23 are embedded in the inside of the flexible ball 23 to absorb the vibration and the nonwoven fabric causing the destructive interference is laid out so that the respective components work together to very effectively reduce the flow of the interlayer noise and vibration .

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 exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

11: concrete slab 13: wall
15: laminate 17: ondol layer
19: hot water piping 21: lightweight foamed concrete layer
23: soft ball 23a: gelatin core
23b: silicon sphere 25: main panel
25a: projecting portion 25b: upper surface
25c: ball receiving groove 25d: fitting projection
25e: projection receiving groove 25f:
25 g: bottom 27: nonwoven fabric
29: base panel 31a, 31b: side cushioning material
33: buffer member

Claims (7)

A plurality of ball receiving grooves opened in a thickness direction lower portion are formed in the upper portion of the concrete slab, and the upper surface is deformed by a load externally applied to the upper surface, A main panel having protrusions for transmitting the protrusions;
A soft ball having a physical characteristic different from that of the main panel to receive and damp vibration energy transmitted from the outside in a state of being completely inserted into the ball groove of the main panel; And
And a base panel contacting the bottom surface of the main panel at a lower portion of the main panel and supporting the soft ball inside the ball receiving groove,
The diameter of the inlet of the ball receiving groove is designed to be smaller than the diameter of the soft ball so that the ball can be easily inserted into the ball receiving groove in a compressed state,
A nonwoven fabric layer for attenuating vibration energy that has passed through the main panel and the base panel is provided at a lower portion of the base panel,
The soft ball comprises:
A silicon ball which is hollow and made of elastic material and takes the form of a sphere,
Wherein the elastic body is made of a gelatin core which is elastically deformed according to a characteristic of the silicone sphere containing the silicone sphere and which provides a damping force to the outside. Noise and Vibration Reduction Laminate. delete delete The apparatus according to claim 1,
Characterized in that it is in the form of a quadrangular pyramid. The method according to claim 1,
The material of the main panel is,
Wherein the polymer is any one of polychloroprene, butadiene, nitrile, ethylene-propylene, and chlorosulfonated polyethylene. The method according to any one of claims 1, 4, or 5,
Wherein the main panel has a protrusion formed on the rim portion or a protrusion receiving groove formed therein so that the main protrusions and the protrusion receiving recesses of the adjacent main panels are fitted to each other so that the main panel having the fitting protrusion And the main panel having the projection receiving recesses can be selectively installed close to the wall. The method according to claim 6,
Like member having a predetermined width is formed between the laminate and the buffer member installed in the wall and is manufactured in a state of being raised in the width direction and is manufactured corresponding to the shape of the rim of the main panel, Further comprising side buffering means coupled to the groove for blocking transmission of vibration energy between the buffer member and the main panel and between the buffer member and the base panel.

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