KR102147621B1 - Structure for reduction noise between floors - Google Patents

Abstract

A structure for reducing noises between floors of the present invention includes: a base; first protruding parts protruding from the base toward a first direction; and second protruding parts formed on the base in a different shape and a different position from the first protruding parts and protruding from the base toward a second direction which is an opposite direction of the first direction, wherein a plurality of first protruding parts are formed in positions spaced apart from each other. The inside of each of the first protruding parts is vacant to be filled with filling materials.

Description

Interfloor noise reduction structure {STRUCTURE FOR REDUCTION NOISE BETWEEN FLOORS}

The present invention relates to a structure that is installed on the floor or wall of a building to reduce noise generation or vibration transmission.

In recent years, in recognition of the problem of residential environment, sustainable and perfect inter-floor noise reduction technology is required as a countermeasure against inter-floor noise. In Korea, styrofoam, various elastic materials, and foam concrete are mainly used as construction methods to reduce inter-floor noise, but the reality is that inter-floor noise reduction performance is insignificant. For this reason, damage to the residential environment has emerged and has become a social problem.

Various regulations such as government notices have been prepared for the issue of interfloor noise, and various research papers and patents have been disclosed. For example, Unexamined Patent Publication No. 10-2019-0050305 (2019.05.10.) discloses an interfloor noise reduction material including a vibration-proof member having an uneven shape and a buffer member for buffering between the floors of a building. The vibration isolating member of the above patent document is made of a vibration isolating material, and it is described that it can absorb vibrations firstly and absorb vibrations at the interface between the vibration isolating member and the buffer member.

However, only the structure described in the above patent document lacks the effect of reducing inter-floor noise, and it is necessary to reduce vibration and improve the sound insulation effect of inter-floor noise reduction structures constructed in residential and living spaces.

In particular, interfloor noise is classified into lightweight impact sound and heavy impact sound.Of these, interlayer noise reduction materials that reduce lightweight impact sounds to the performance standard are commercially available, while interlayer noise reduction materials that reduce both lightweight impact sounds and heavy impact sounds to performance standards are commercially available. Not.

The present invention is to propose an interlayer noise reduction structure excellent in vibration reduction and sound insulation effect structurally in order to realize the above-described problems. In particular, the present invention is to provide a structure for reducing noise between floors that can effectively reduce not only light weight impact sound but also weight impact sound.

In addition, the present invention is to provide an interlayer noise reduction structure capable of maximizing vibration reduction and sound insulation/sound absorption effects by filling the interlayer noise reduction structure with a filler.

In addition, the present invention is to provide an inter-floor noise reduction structure capable of further maximizing vibration reduction and sound insulation/absorption effects by being combined with each other.

In order to solve the above problems, the interlayer noise reduction structure of the present invention includes: a base; A first protrusion protruding from the base in a first direction; And a second protrusion formed in a different shape from the base at a position different from the first protrusion, and protruding from the base toward a second direction opposite to the first direction, wherein the first protrusion includes a plurality of The plurality of first protrusions are formed at positions spaced apart from each other, and the interior of each first protrusion is empty to be filled with a filler.

The cross-sectional area of the first protrusion gradually decreases as it approaches the first direction.

The interlayer noise reduction structure is formed to be combined with other interlayer noise reduction structures having the same structure, and the interlayer noise reduction structure includes a first protrusion of the other interlayer noise reduction structure in an area surrounded by a plurality of first protrusions. An acceptable receiving portion is formed.

When the inter-floor noise reduction structure and the other inter-floor noise reduction structure are combined with each other, the first protrusion of any one of the inter-floor noise reduction structure and the other inter-floor noise reduction structure and the other base may be in the first direction or the second Spaced apart from each other in the direction.

Each inlet port for inserting the filler into the first protrusion formed in the interlayer noise reduction structure is formed in a region surrounded by the plurality of second protrusions in the base, and the inlet port is formed in a polygonal shape. In addition, one second protrusion is formed at a position adjacent to the corner of the polygon around the inlet, and the base is formed in a radial direction between two second protrusions at each position adjacent to the vertex of the polygon.

The receiving part (A) is divided into a first type into which the first protrusion of the other interlayer noise reduction structure is inserted: and a second type into which the first protrusion of the other interlayer noise reduction structure is not inserted, and the second The base formed at a position corresponding to the receiving portion of the bell is formed to face each other with the base of the other interlayer noise reduction structure with the receiving portion of the second type disposed therebetween.

The second protrusion may include: a first center recess recessed in a first direction from an end portion of the second protrusion in the second direction; A second center recess further recessed in the first direction from the first center recess and smaller than the first center recess; And a radial recess that is recessed from the first center recess to a side surface of the second protrusion.

The interlayer noise reduction structure further includes a cover covering the second protrusion, a first layer formed of synthetic resin or synthetic fiber, and coupled along an edge of the interlayer noise reduction structure; And a second layer formed of a synthetic resin or synthetic fiber of a different type from the first layer and laminated on the first layer.

The first layer sags in a direction toward the inside of the first protrusion in a region surrounded by the plurality of second protrusions.

The filler, (a) air or water; (b) any one of pearlite, vermiculite, styrofoam powder, aerated concrete, low ash lightweight aggregate, and glass bubble microspheres; (c) (c1) 88 to 98.7 wt.% of water, (c2) 1 to 10 wt.% of cellulose, (c3) 0.1 to 1 wt.% of sodium carbonate, and (c4) 0.1 to 1 wt.% of urethane powder are mixed. One mixture; (d) (d1) 87 to 98.7 wt.% of water, (d2) 1 to 10 wt.% of cellulose, (d3) 0.1 to 1 wt.% of citric acid, (d4) 0.1 to 1 wt.% of sodium carbonate, and (d5) ) A mixture of 0.1 to 1 wt.% of at least one of urethane powder, pearlite, vermiculite, styrofoam powder, aerated concrete, and glass bubble microspheres; And (e) (e1) 89 to 98.9 wt.% of water, (e2) 1 to 10 wt.% of mineral oil or vegetable oil, (e3) at least one of pearlite, vermiculite, styrofoam powder, foam concrete, glass bubble microspheres It is formed in any one of a mixture of 0.1 to 1 wt.%.

According to the present invention, since the cross-sectional area of the first protrusion gradually decreases as the cross-sectional area approaches the first direction, vibration can be reduced and noise can be blocked by the structural shape of the first protrusion.

According to the present invention, since the filling space of the first protrusion is filled with water, air, and other fillers having excellent sound insulation/absorption effects, the filler itself has vibration reduction and sound insulation/sound absorption effects, as well as the filler and the first projection. By causing the dissipation of vibration at the boundary, its effect can be maximized.

According to the present invention, since inter-floor noise reduction structures having the same structure are constructed by being combined with each other, one inter-floor noise reduction structure has vibration reduction and sound insulation/sound absorption effects, as well as dissipation of vibration at the boundary of the noise reduction structure between two floors. , The effect can be further maximized.

In particular, according to the present invention, not only the light weight impact sound, but also the weight impact sound can be effectively reduced.

1 is a perspective view showing an embodiment of an interlayer noise reduction structure proposed in the present invention.
FIG. 2 is a perspective view of the inter-floor noise reduction structure shown in FIG. 1 viewed from a different direction.
3 is a plan view of the interlayer noise reduction structure shown in FIG. 1.
4 is a bottom view of the interlayer noise reduction structure shown in FIG. 1.
5 is a real photograph of pearlite, one of the materials of the filler.
6 is a real photograph of vermiculite, which is one of the filler materials.
7 is a photograph of a low ash lightweight aggregate that is one of the materials of the filler.
8 is a schematic diagram of a glass bubble microsphere, which is one of the materials of the filler.
9 is a conceptual diagram showing a process of combining two identical interlayer noise reduction structures.
10 is a conceptual diagram showing a state in which two identical interlayer noise reduction structures are combined.
11 is a side view showing a state in which two identical interlayer noise reduction structures are combined.
12 is a cross-sectional view showing a state in which two identical interlayer noise reduction structures are combined.
13 is a perspective view showing another embodiment of the interlayer noise reduction structure proposed in the present invention.
14 is a perspective view of the interlayer noise reduction structure shown in FIG. 13 viewed from a different direction.
15 is a flow chart showing a method of manufacturing an interlayer noise reduction structure proposed in the present invention.

Hereinafter, an interlayer noise reduction structure according to the present invention will be described in more detail with reference to the drawings. The accompanying drawings are only for making it easier to understand the embodiments disclosed in the present specification, and the technical idea disclosed in the present specification is not limited by the accompanying drawings, and all changes and equivalents included in the spirit and scope of the present invention It should be understood to include water or substitutes.

Singular expressions used in the present specification include plural expressions unless the context clearly indicates otherwise.

In the present specification, when a component is referred to as being "connected" or "connected" to another component, it may be directly connected or connected to the other component, but other components exist in the middle. It should be understood that it may be possible. On the other hand, when a component is referred to as being "directly connected" or "directly connected" to another component, it should be understood that there is no other component in the middle.

In addition, terms such as "comprises" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or combinations thereof described in the specification, but one or more other features or numbers. It is to be understood that the possibility of addition or presence of, steps, actions, components, parts, or combinations thereof is not preliminarily excluded.

1 is a perspective view showing an embodiment of an interlayer noise reduction structure 100 proposed in the present invention.

FIG. 2 is a perspective view of the interlayer noise reduction structure 100 shown in FIG. 1 viewed from a different direction.

3 is a plan view of the interlayer noise reduction structure 100 shown in FIG. 1.

4 is a bottom view of the interlayer noise reduction structure 100 shown in FIG. 1.

The interfloor noise reduction structure 100 of the present invention is embedded in the floor or wall of a building, and is formed to reduce noise generation or vibration transmission. The interlayer noise reduction structure 100 includes a molded product made of a thermoplastic resin or a thermosetting resin, and is made to maximize the effect of reducing noise or vibration by filling a filler material in the inner space of the molded product.

The interlayer noise reduction structure 100 includes a base 101, a first protrusion 110, and a second protrusion 120. A single molded product may have a base 101, a first protrusion 110, and a second protrusion 120, and a thermoplastic resin or a thermosetting resin is injection-molded or vacuum injection-molded to form the base 101 and the first protrusion 110. ), and a molded article having the second protrusion 120 may be manufactured.

The base 101 is a portion that serves as a standard for forming the first and second protrusions 110 and 120. The base 101 may essentially have a flat plate structure. However, if the first protrusion 110 and the second protrusion 120 are formed on the base 101, the boundary between the base 101 and the first protrusion 110, and the base 101 and the second protrusion 120 Burrs 110 ′ and 120 ′ may be formed at the boundary. In addition, when the distances between adjacent burrs 110 ′ and 120 ′ are close, the base 101 may not have a complete flat plate structure, and may have a partially inclined or loud gin structure.

Originally, the burr (110', 120') refers to a thin prickly or fin-shaped excess part generated when processing a metal material. Although the above molded product is not formed of a metal material, it is not possible to completely rule out the occurrence of a shape corresponding to the burrs 110 ′ and 120 ′ as a result of the molding.

The first protrusion 110 and the second protrusion 120 protrude from the base 101 in different directions, and the base 101 is formed to connect the first protrusion 110 and the second protrusion 120 to each other. do. In addition, the base 101 is formed to connect two different first protrusions 110 to each other or to connect two different second protrusions 120 to each other. Therefore, the base 101 is formed between one of the first protrusions 110 and the other first protrusions 110, and between any one second protrusion 120 and the other second protrusion 120 Edo base 101 is formed.

The base 101 may also be formed between the charging space 111 and the second protrusion 120, but it may not be. When the boundary between the base 101 and the filling space 111 is referred to as a first boundary, and the boundary between the base 101 and the second protrusion 120 is referred to as a second boundary, if the first boundary and the second boundary coincide The base 101 may not be formed between the first protrusion 110 and the second protrusion 120.

The first protrusion 110 protrudes from the base 101 in a first direction. The first direction refers to the normal direction of the flat plate on which the base 101 is formed. The interlayer noise reduction structure 100 of the present invention may be constructed by being combined with the other interlayer noise reduction structure 200 having essentially the same structure. The first direction is a direction toward the noise reduction structure 200 between other floors.

The first protrusion 110 is related to support of the base 101 and the second protrusion 120, dissipating noise and vibration, accommodating a filler, and coupling with the noise reduction structure 200 between other floors.

First, the first protrusion 110 supports the base 101 and the second protrusion 120. When the interfloor noise reduction structure 100 is installed on the floor, the first protrusion 110 or the second protrusion 120 is constructed in a state in which the first protrusion 110 or the second protrusion 120 faces the vertical direction (gravity direction), and the inter-floor noise reduction structure 100 In this constructed state, since the first direction corresponds to the same or opposite direction to the vertical direction, the first protrusion 110 connects the base 101 and the second protrusion 120 of the interlayer noise reduction structure 100 in the vertical direction. Support.

Next, the first protrusion 110 dissipates noise and vibration. Since noise and vibration are transmitted through the medium, the transmission of noise and vibration is greatly influenced by the shape and material of the medium. Therefore, it is preferable that the first protrusion 110 has a shape that is advantageous for dissipating noise and vibration.

In the present invention, the cross-sectional area of the first protrusion 110 is formed to gradually decrease as it approaches the first direction. For example, since the outer surface of the first protrusion 110 is formed to be inclined with respect to the first direction, the cross-sectional area of the first protrusion 110 may be continuously decreased as the cross-sectional area of the first protrusion 110 approaches the first direction. In this case, the plurality of outer surfaces provided on the first protrusions 110 are inclined in a direction closer to each other as they approach the first direction.

Referring to the drawings, the first protrusion 110 protrudes from the base 101 along a regular hexagon. The first protrusion 110 may be formed in the shape of a hexagonal column, but if the cross-sectional area of the first protrusion 110 gradually decreases as it approaches the first direction, the first protrusion 110 has a shape of a hexagonal pyramid or a hexagonal pyramid. It can also be formed. If the end of the first protrusion 110 in the first direction is sharp, the first protrusion 110 has a shape of a hexagonal pyramid, and if it is not sharp, the first protrusion 110 has a shape of a hexagonal truncated cone.

However, the first protrusion 110 is not necessarily in the shape of a hexagonal column, a hexagonal pyramid, or a hexagonal truncated cone, and any of a cylinder, a cone, a truncated cone, a polygonal column, a polygonal pyramid, or a polygonal pyramid may be used.

In addition, the first protrusion 110 formed on the edge of the interlayer noise reduction structure 100 may have a structure partially cut in the first direction. According to this structure, when a plurality of interlayer noise reduction structures are installed in close contact with each other along a lateral direction, adjacent interlayer noise reduction structures are in contact with each other. Accordingly, a phenomenon in which the interlayer noise reduction structure 100 deviates from the construction location during or after construction may be prevented.

Meanwhile, as another example of a structure in which the cross-sectional area of the first protrusion 110 gradually decreases as the cross-sectional area approaches the first direction, the first protrusion 110 may be formed to gradually decrease as the cross-sectional area approaches the first direction. . The first protrusion 110 may have one or more steps between the end portion on the first direction side and the base 101 so that the first protrusion 110 may be discontinuously small.

If the cross-sectional area of the first protrusion 110 gradually decreases as it approaches the first direction, the size of the medium gradually decreases as it approaches the first direction, thereby dissipating noise and vibration.

The inside of the first protrusion 110 is empty so that the filler can be filled. The inside of the first protrusion 110 may be referred to as a charging space 111. Since the charging space 111 is formed along the first protrusion 110, if the cross-sectional area of the first protrusion 110 is formed to be smaller as the cross-sectional area of the first protrusion 110 approaches the first direction, the charging space 111 will also become closer to the first direction. The more it gets, the narrower it gets.

The first protrusion 110 may structurally dissipate vibrations, but when a filling material capable of sound insulation or sound absorption is filled therein, the sound insulation or sound absorption effect of the interlayer noise reduction structure 100 is increased. Furthermore, since noise and vibration are dissipated at the boundary of the heterogeneous medium, when the filler is filled in the filling space 111 of the first protrusion 110, the effect of dissipating noise and vibration at the boundary between the filler and the first protrusion 110 will be maximized. I can.

In order to increase the vibration reduction effect resulting from the structure of the first protrusion 110 and to accommodate a sufficient filler, the volume of the filling space 111 must be sufficiently secured. To this end, the protrusion length of the first protrusion 110 must be sufficiently large. In the present invention, the protrusion length of the first protrusion 110 is set to be longer than the protrusion length of the second protrusion 120 to be described later. It is preferable that the protrusion length of the first protrusion 110 is three times or more than the protrusion length of the second protrusion 120.

In addition, the cross-sectional area of the first protrusion 110 in the base 101 is larger than the cross-sectional area of the second protrusion 120. Here, the cross-sectional area of the first protrusion 110 refers to the cross-sectional area of the inlet 102 formed in the base 101 for injecting the filler into the filling space 111. The inlet 102 is formed at a position corresponding to the first protrusion 110, and the shape of the inlet 102 corresponds to the cross-sectional area of the first protrusion 110.

The state of the filler may be solid, liquid, or gas. In order to keep the filler material stored in the filling space 111, the end of the first protrusion 110 in the first direction is blocked. The detailed material of the filler will be described later.

The first protrusion 110 is formed in plural. The plurality of first protrusions 110 are regularly formed at positions spaced apart from each other. The plurality of first protrusions 110 may be regularly arranged. For example, the first protrusions 110 may be spaced apart by the same distance as other adjacent first protrusions 110. A second protrusion 120 is formed in a region between the plurality of first protrusions 110 that are generated by being spaced apart from each other.

The first protrusion 210 of the other interlayer noise reduction structure 200 (refer to FIGS. 9 and 10) coupled with the interlayer noise reduction structure 100 is inserted into the area enclosed by the plurality of first protrusions 110. In this case, an area enclosed by the plurality of first protrusions 110 may be referred to as a receiving portion A.

Referring to the drawings, the receiving portion A corresponds to an area surrounded by the three first protrusions 110. The accommodation part A is formed to receive the first protrusion 210 of the noise reduction structure 200 between other floors.

A groove 112 is formed at an end portion of the first protrusion 110 in the first direction. The groove 112 is recessed in the second direction. When the inter-floor noise reduction structure 100 is combined with the other inter-floor noise reduction structure 200 (see FIGS. 9 and 10), the first protrusion 110 is spaced apart from the base and the groove 225 of the other inter-floor noise reduction structure. A vibration dissipation space is formed, and the vibration dissipation space has a smaller volume than the filling space 111. Therefore, when the groove 112 is formed, a small volume can be supplemented.

A groove 113 is formed on the outer circumferential surface of the first protrusion 110. The groove 113 is recessed in the shape of a semicircular cross section from the outer circumferential surface of the first protrusion 110, and extends to the end of the first protrusion 110 in the first direction along the inclined outer circumferential surface of the first protrusion 110. Form a structure

When the inter-floor noise reduction structure 100 is combined with another inter-floor noise reduction structure 200 (see FIGS. 9 and 10) having the same structure, the groove 113 is the first of the other inter-floor noise reduction structure 200. 1 It is formed on each surface abutting the protrusion 210. When the groove 113 is formed on each of the abutting surfaces, a cylindrical hole is formed along the inclined outer peripheral surface between the two first protrusions 110 and 210 that abut each other. This hole forms an interface and exhibits the effect of reducing vibration.

The second protrusion 120 is formed in a different shape in a position different from the first protrusion 110 on the base 101. The second protrusion 120 protrudes from the base 101 in a second direction, where the second direction is a direction opposite to the first direction.

The second protrusion 120 protrudes in the shape of a cylinder or polygonal column. Here, the concept of a cylinder includes a cone or a truncated cone, and the concept of a polygonal column includes a polygonal pyramid or a pyramid.

A first center recess 121, a second center recess 122, and a radial recess 123 are formed in the second protrusion 120.

The first center recess 121 is formed at an end portion of the second protrusion 120 in the second direction. The first center recess 121 is recessed in the first direction. For example, the first center recess 121 may be recessed in a hemispherical shape at the center of the end in the second direction. The hemispherical recess is formed at a position spaced apart from the corner of the cylinder or polygonal column corresponding to the shape of the second protrusion 120.

In addition, the second center recess 122 is additionally recessed in the first direction from the center of the first center recess 121. The second center recess 122 may be formed in a hemispherical shape smaller than that of the first center recess 121.

The radial recess 123 is recessed in the radial direction from the first center recess 121 to the side surface of the second protrusion 120. As the radial recess 123 is recessed to the side of the second protrusion 120, the second protrusion 120 may be understood as a structure in which a groove is formed on the side.

The radial recess 123 may be formed in plural. For example, a radial recess 123 may be formed in each direction toward the corner of the polygon defining the shape of the second protrusion 120.

When looking at the second protrusion 120 along the first direction from a position spaced apart from the second protrusion 120, the surface formed at the end of the second protrusion 120 on the second direction side is called the protrusion surface 124. I can name it. As the first center recess 121 and the radial recess 123 are formed at the end of the second protrusion 120 in the second direction, the protrusion surface 124 is divided into a plurality. The cover 130 to be described later is coupled to the protruding surface 124 divided into a plurality.

In order for the cover 130 to be fixed, the cover 130 must be coupled to the rim of the interlayer noise reduction structure 100 and the protrusion surface 124 of the second protrusion 120. However, unlike the cover 130 must be tightly coupled to the edge of the interlayer noise reduction structure 100 for sealing, the cover 130 must be the first center recess 121 and the radial recess 123 It does not have to be coupled to the entire protruding surface 124 without.

Since the sealing state can be maintained even if the cover 130 is coupled only to the protruding surface 124 divided into a plurality, the cover 130 is a position spaced apart from the first center recess 121 and the radial recess 123 Is coupled to the plurality of divided protruding surfaces 124.

When the first center recess 121, the second center recess 122, and the radial recess 123 of the second protrusion 120 are formed, between the cover 130 and the second protrusion 120 In addition, an interface is formed. Since the vibration is dissipated at the interface of the medium, when the recesses 121, 122, and 123 are formed, the vibration dissipation effect increases with the addition of the interface.

In particular, the second center recess 122 further separates the distance between the interface and the interface by adding a space equal to the second center recess 122 to the space between the cover 130 and the first center recess 121 Will be ordered. In this case, vibrations between the interface and the interface naturally dissipate as they flow along the medium. Here, the interface and the interface refer to the interface of the second protrusion 120 and the cover 130 formed on both sides with a space between the second protrusion 120 and the cover 130.

As described above, the interlayer noise reduction structure 100 is constructed by being combined with another interlayer noise reduction structure 200 (see FIGS. 9 and 10) having the same structure. The second protrusion 120 forms a groove 125 to be spaced apart from the counterpart first protrusion 210 when the two interlayer noise reduction structures 100 and 200 having the same structure are coupled to each other.

Like the first protrusion 110, the second protrusion 120 is formed in plural. The plurality of second protrusions 120 are formed at positions spaced apart from each other. The plurality of second protrusions 120 may be regularly arranged. For example, the second protrusions 120 may be spaced apart by the same distance as other adjacent second protrusions 120.

Each of the first protrusions 110 based on the base 101 is formed in an area surrounded by the plurality of second protrusions 120. Since the base 101 is formed with an inlet 102 for inserting the filler into the filling space 111 of the first protrusion 110, each inlet 102 is wrapped by a plurality of second protrusions 120 Formed in the area.

When looking at the interlayer noise reduction structure 100 along the first direction from a position spaced apart from the second protrusion 120, the inlet 102 is formed in a polygonal shape such as a hexagon. In addition, one second protrusion 120 is formed at each position adjacent to the corner of the hexagon around the inlet 102. In addition, the base 101 is formed in the radial direction at each position adjacent to the vertex of the hexagon. A burr 120 ′ corresponding to a boundary between the base 101 and the second protrusion 120 may also be formed together with the base 101.

The base 101 formed in the radial direction at each position adjacent to the vertex of the hexagon or the burrs 120 ′ on both sides thereof are formed between the two second protrusions 120. Accordingly, six second protrusions 120 and base 101 are alternately formed around each inlet 102 along the periphery of the inlet 102.

Each second protrusion 120 based on the base 101 is formed in an area surrounded by the plurality of first protrusions 110. When looking at the interlayer noise reduction structure 100 along the second direction from a position spaced apart from the first protrusion 110, the inlet 103 of the groove 125 formed by the second protrusion 120 on the base 101 ) Is formed. The inlet of each groove 125 is formed in a region surrounded by the plurality of first protrusions 110.

When looking at the interlayer noise reduction structure 100 along the second direction from a position spaced apart from the first protrusion 110, the entrance 103 of the groove 125 is formed in a polygonal shape. In addition, a first protrusion 110 or a base 101 is formed around the inlet 103 for each position adjacent to the corner of the polygon. The burr 110 ′ corresponding to the boundary between the base 101 and the first protrusion 110 may be formed at a position corresponding to a vertex of a polygon.

The base 101 or the burr 110 ′ is formed between the two first protrusions 110. Therefore, around the inlet 103 of each groove 125, three first protrusions 110 and the base 101 are alternately formed along the periphery of the inlet 103.

The second protrusion 120 protrudes in the shape of a hollow cylinder or a hollow polygonal pillar. Accordingly, a groove 125 is formed on the opposite side of the protruding direction of the second protrusion 120. The groove 125 is formed at a position corresponding to the second protrusion 120, and the shape of the inlet 103 of the groove 125 corresponds to the cross section of the second protrusion 120.

Here, the concept of a cylinder includes a cone or a truncated cone, and the concept of a polygonal column includes a polygonal pyramid and a polygonal frustum. Also, the corners of a polygonal column, a polygonal pyramid, and a polygonal pyramid may not necessarily be uniform, and the vertices may be angled or rounded. In addition, a cross section of the second protrusion 120 may have a shape of a Reuleaux triangle or spherical triangles.

Hereinafter, a material of a filler that can be filled in the charging space 111 will be described.

A typical filling material is air. Air has the advantage that it does not require a separate cost for preparing materials, and when air is used as a filler, the process of manufacturing the interlayer noise reduction structure 100 is also simpler than when using other fillers.

Other fillers include water. Water should be water that is not polluted, such as tap water or groundwater. Water is similar to air in that it does not require a large cost to prepare the material.

As another filler, any one of pearlite, vermiculite, styrofoam powder, aerated concrete, low ash lightweight aggregate, and glass bubble microspheres may be used.

Here, perlite is an ultra-light, porous pure inorganic material that is excellent in sound insulation and sound absorption. Pearlite is obtained by pulverizing the amorphous mineral generated by the concentration of volatiles inside as magma flows into the surface lake or sea and rapidly cooling, and then expanding it by rapid heating at a high temperature of 1,100℃ or higher. 5 is a real photograph of pearlite, one of the materials of the filler.

In addition, vermiculite is typically produced by the metamorphism of biotite, and is produced as a large pseudomorph that alternates between biotite, or as small particles in soil and old sediments. Vermiculite is also formed in the contact between acidic intrusive rocks, pyroxene and dunite. When rapidly heated to about 300°C, vermiculite can expand up to 20 times its original thickness, has a light specific gravity, and has excellent sound absorption function. 6 is a real photograph of vermiculite, which is one of the filler materials.

Strofoam powder is a type of plastic hardened by adding a foaming agent to a polystyrene resin to make it like a sponge. It has a light specific gravity and a stable sound insulation effect.

Foamed concrete is porous concrete that contains a lot of air bubbles inside by mixing cement paste with a foaming agent or by mixing stable foam and cement paint. Foamed concrete is lightweight and has excellent sound absorption and heat barrier properties.

Low-ash lightweight aggregate is an eco-friendly recycled aggregate produced by firing bottom ash and sedimentary soil as by-products from thermal power plants at 1,000°C or higher for each particle size. Because it is a porous material, it has excellent sound absorption function. 7 is a photograph of a low ash lightweight aggregate that is one of the materials of the filler.

Glass bubble microspheres are in the shape of a bead having a diameter in micrometers, and the shape of the bead is hollow. Glass bubble microspheres have strong strength, high density, and excellent water resistance and sound insulation effects based on sodium carbonate (Na2CO3). Fig. 8 is a schematic diagram of glass bubble microspheres that are one of the materials of the filler.

Pearlite, vermiculite, styrofoam powder, low ash lightweight aggregate, and glass bubble microspheres preferably have a particle size of 3 mm or less.

Pearlite, vermiculite, and glass bubble microspheres can enhance the interlayer noise prevention function with perfect sound insulation when used at a ratio of 100wt.%, but high raw material prices may lead to an increase in manufacturing cost.

On the other hand, foamed concrete and low-ash lightweight aggregate are inexpensive recycled materials and are desirable materials that show economical cost savings and high sound insulation effects even when used in a ratio of 100 wt.%. Styrofoam powder is also a low-cost material, so even if it is used in a ratio of 100 wt.

It is also possible to mix and use several materials for the filler.

For example, a mixture of 88 to 98.7 wt.% of water, 1 to 10 wt.% of cellulose, 0.1 to 1 wt.% of sodium carbonate, and 0.1 to 1 wt.% of urethane powder may be used as a filler.

As another example, water 87 to 98.7 wt.%, cellulose 1 to 10 wt.%, citric acid 0.1 to 1 wt.%, sodium carbonate 0.1 to 1 wt.%, and urethane powder, pearlite, vermiculite, styrofoam powder, foam concrete, glass A mixture of 0.1 to 1 wt.% of at least one of the bubble microspheres may be used as a filler.

When water, cellulose, citric acid, and sodium carbonate are mixed, the viscosity is higher than 2,000 mPa·s due to the reaction, improving the sound insulation function.

As another example, water 89-98.9 wt.%, mineral oil or vegetable oil 1-10 wt.%, pearlite, vermiculite, styrofoam powder, aerated concrete, glass bubble microspheres at least one of 0.1-1 wt. Mixtures can be used as fillers.

Here, sodium carbonate causes a lot of bubble generation, and the sound insulation effect by the bubble is excellent.

In addition, urethane powder is obtained by subjecting urethane foam to powder treatment.

Mineral oil is a general industrial oil. Vegetable oil is an edible oil extracted from soybeans. When mineral oil or vegetable oil is used less than 1 wt.%, the interlayer membrane due to the specific gravity with water is thin, and the function of sound-isolating early vibration noise is poor. If mineral oil or vegetable oil is used in excess of 10 wt.%, the sound insulation effect may be saturated or the cost may increase as an expensive raw material.

Pearlite, vermiculite, and styrofoam powder are preferably used in an amount of 0.1 to 1 wt.% with a particle size of 3 mm or less. When perlite, vermiculite, styrofoam powder, aerated concrete, and glass bubble microspheres are used less than 0.1 wt.%, the interlayer membrane is thin due to the specific gravity of water and the function of sound-isolating the initial vibration noise is poor. If pearlite, vermiculite, and glass bubble microspheres are used in excess of 1 wt.%, the sound insulation effect will be saturated or the cost will increase as an expensive raw material.

Among the materials of the above-described filler, air, water, oil, and glass bubble microspheres are materials with excellent sound insulation effect, and styrofoam powder, foam concrete, pearlite, vermiculite, and low ash lightweight aggregate are materials with excellent sound absorption effect.

The description of other overlapping materials is replaced with the previous description.

In order to keep the interlayer noise reduction structure 100 in a state stored in the entire space, a cover 130 for sealing should be provided. The interlayer noise reduction structure 100 includes a cover 130 covering the second protrusion 120.

The cover 130 is coupled along the edge of the interlayer noise reduction structure 100 to prevent separation of the filler filled in the filling space 111 of the first protrusion 110. In order to seal the filling space 111, the coupling portion between the cover 130 and the first protrusion 110 forms a closed curve.

In addition, the cover 130 is also coupled to an end portion of the second protrusion 120 in the second direction. It has been described above that the cover 130 is coupled to the protrusion surface 124 divided into a plurality of the second protrusion 120.

The cover 130 may be adhered to the rim of the interlayer noise reduction structure 100 or the protrusion surface 124 divided into a plurality of the second protrusion 120 using an adhesive. Alternatively, the cover 130 may be attached to the rim of the interlayer noise reduction structure 100 or the protrusion surface 124 divided into a plurality of the second protrusion 120 by a heating method such as thermal compression.

The cover 130 may include multiple layers. The first layer 131 is bonded to the edge of the interlayer noise reduction structure 100 by using an adhesive or thermocompression bonding, and the second layer 132 is laminated on the first layer 131. Here, the first layer 131 is formed of synthetic resin or synthetic fiber, and the second layer 132 is formed of a synthetic resin or synthetic fiber different from the first layer 131. For example, the first layer 131 may be formed of plastic such as a silver foil-coated polyethylene foam paper or vinyl, and the second layer 132 may be formed of a thin Styrofoam.

When the cover 130 is coupled to the rim of the inter-floor noise reduction structure 100 to seal the filling space 111, the inter-floor noise reduction structure 100 is filled with a filling material in the filling space 111 and the other inter-floor noise reduction structure ( 200) can be combined and can be constructed regardless of the direction.

Hereinafter, the combination of the two interlayer noise reduction structures 100 and 200 having the same structure will be described.

9 is a conceptual diagram showing a process in which two identical interlayer noise reduction structures 100 and 200 are combined.

10 is a conceptual diagram showing a state in which two identical interlayer noise reduction structures 100 and 200 are combined with each other.

11 is a side view showing a state in which two identical interlayer noise reduction structures 100 and 200 are combined with each other.

12 is a cross-sectional view showing a state in which two identical interlayer noise reduction structures 100 and 200 are combined with each other.

The interlayer noise reduction structure 100 of the present invention is combined with the other interlayer noise reduction structure 200 having essentially the same structure. Since the first protrusion 110 and the second protrusion 120 have regularity and are formed on the base 101, respectively, the noise reduction structures 100 and 200 between the two layers can be combined.

When the two interlayer noise reduction structures 100 and 200 are arranged to face in opposite directions and approach each other in the first direction or the second direction, each of the first Each of the protrusions 110 is inserted into some of the plurality of accommodating portions A formed in the noise reduction structure 200 between the other floors.

Similarly, each of the first protrusions 210 formed in the noise reduction structure 200 between the other floors is inserted into a portion of the plurality of receiving portions A formed in the noise reduction structure 100 between the floors, one by one.

When the noise reduction structures 100 and 200 between the two floors of the same structure are combined with each other, it exhibits a supporting effect when constructed on the floor or wall of a building, as well as an effect of reducing inter-floor noise such as sound insulation and sound absorption. In particular, vibration is dissipated at the boundary between the noise reduction structures 100 and 200 between the two floors.

When the inter-floor noise reduction structure 100 and the other inter-floor noise reduction structure 200 are combined with each other, the first protrusion 110 of the inter-floor noise reduction structure 100 and the base 201 of the other inter-floor noise reduction structure 200 In addition, the inlet 203 of the groove 225 formed on the opposite side of the second protrusion (not shown) is spaced apart from each other in the first direction or the second direction. Similarly, the first protrusion 210 of the noise reduction structure 200 between the other floors, the base 101 of the noise reduction structure 100 and the inlet 103 of the groove 125 are spaced apart from each other in the first direction or the second direction. do.

For example, when the inter-floor noise reduction structure 100 and the other inter-floor noise reduction structure 200 are combined, the first protrusion 110 of the inter-floor noise reduction structure 100 and the first protrusion 210 of the other inter-floor noise reduction structure It is in close contact, but between the first protrusions 110 and 210 and the counterpart base 201 and 101, and between the first protrusions 110 and 210 and the inlet 203 and 103 of the counterpart grooves 225 and 125 There is a gap (C) is formed.

When the gap C is formed in this way, since a space in which vibration can be dissipated is formed, the space between the first protrusion 110 and 210 and the counterpart base 201 and 101, the first protrusion 110 The vibration is dissipated in the space between 210 and the counterpart grooves 225 and 125.

Meanwhile, referring to FIG. 12, the first layer 131 of the cover 130 sags in a direction toward the inside of the first protrusion 110 in a region surrounded by the plurality of second protrusions 120. Sagging means that the first layer 131 is axially stretched from top to bottom in advance, and when the first layer 131 is coupled to the protruding surface 124 which is the end of the second protruding part 120 in the second direction, the second protruding part 120 ) Is fixed at the coupling position, but does not form a plane in the area enclosed by the plurality of second protrusions 120, but is stretched in the same shape as the cross section of the catenary line in the first direction.

Accordingly, an empty space B is formed between the first layer 131 and the second layer 132. Similarly, vibrations are also dissipated in this empty space B.

If the charging space 111 is filled with air, a space (B) due to a gap C and a sagging shape of the first layer 131 are also formed on both sides of the charging space 111 in the first direction or the second direction. ), a number of spaces where vibration can be dissipated are secured.

On the other hand, when the filling material is not filled in the filling space 111, the two interlayer noise reduction structures 100 and 200 having the same structure overlap each other due to the regularity of the first protrusion 110 and the filling space 111. Can be stacked. For example, when two interlayer noise reduction structures 100 and 200 are arranged to face the same direction and approach each other toward each other, a plurality of first protrusions 110 formed on one interlayer noise reduction structure 100 may cause the noise between the other floors. It is inserted one by one into a plurality of charging spaces formed in the reduction structure 200.

In this way, if a plurality of inter-floor noise reduction structures 100 and 200 can be stacked in multiple layers, it is possible to save storage space or space required for transport when storing or transporting the inter-floor noise reduction structures 100 and 200 after mass production There is an advantage to be able to.

Next, another embodiment of the present invention will be described.

13 is a perspective view showing another embodiment of the interlayer noise reduction structure 300 proposed in the present invention.

14 is a perspective view of the interlayer noise reduction structure 300 shown in FIG. 13 viewed from a different direction.

In the above-described embodiment, the second protrusions 120 are formed in each area surrounded by the plurality of inlet ports 102. However, in the embodiments described in FIGS. 13 and 14, the second protrusion 320 or the base 301 is formed in the area surrounded by the plurality of inlet ports 302.

In addition, unlike the previous embodiment in which the inlet 303 of the groove 325 is formed for each area enclosed by the first protrusion 310, in the embodiments described in FIGS. 13 and 14, a plurality of first protrusions 310 The inlet 303 of the groove 325 is formed or the base 301 is formed in the area surrounded by ).

Compared with the above-described embodiment, the second protrusion 120 and the groove 125 are not formed in some of the positions where the second protrusion 120 and the groove 125 on the opposite side were formed, and the base 301 Is formed.

The second protrusion 320 and the groove 325 are not formed, and the position where the base 301 is formed is the first protrusion (not shown) of the other interlayer noise reduction structure (not shown) having the same structure. This is the location corresponding to the receiving part (A). If the receiving portion (A) is divided into a first type (A') into which the first protrusion of the other floor noise reduction structure is inserted and a second type (A") that is not inserted, the location is the receiving portion of the second type ( A”).

The base 301 formed at this position faces the base of the noise structure between the other floors with the second type of receiving portion A” therebetween. The accommodating part (A) is a space that is actually empty, and the first protrusion of the noise reduction structure between other floors is not inserted into the accommodating part of the second type. Can be understood.

Such a structure has an advantage of securing an empty space in which vibration can be dissipated in the second direction between the cover 330 and the cover 330 at the position where the base 301 is formed. In particular, in the interlayer noise reduction structure of the present invention, since the protrusion length of the second protrusion 320 is shorter than the protrusion length of the first protrusion 310, the space for dissipating vibration may be insufficient. Disadvantages can be compensated.

Reference numerals 310' and 320', which are not described in FIGS. 13 and 14, are burrs, 311 is a filling space, 312 is a groove, 313 is a groove, 321 is a first center recess, 322 is a second center recess, and 323 is Radial recess, 324 designates a protruding surface, and 325 designates a groove. These configurations will be replaced with the description of the above-described embodiment.

Next, a method of manufacturing the interlayer noise reduction structure described above will be described.

15 is a flow chart showing a method of manufacturing an interlayer noise reduction structure proposed in the present invention.

First, a molded article is manufactured using a thermoplastic resin or a thermosetting resin (S100). The molded article refers to an article having a structure in which a plurality of first protrusions and a plurality of second protrusions protrude from the base toward opposite directions at different positions of the base.

For example, a molded product can be manufactured using polyvinyl chloride (PVC), a thermoplastic resin, and plasticizers DOP (Dioctyl phthalate), DOTP (Dioctyl terephthalate), and DOA (Dioctyl adipate), which have excellent compatibility with the polyvinyl chloride. . An injection or vacuum injection method may be used for a method of manufacturing a molded article.

Next, the filling material is filled in the filling space formed on the first protrusion of the manufactured molded article (S200). For the material of the filler, refer to the description of FIGS. 1 to 4 above.

Subsequently, the cover is coupled to the rim of the molded article on which the filling is completed and sealed (S300). The cover may be made of a synthetic resin or synthetic fiber including a thermoplastic resin and a thermosetting resin, and the cover may be bonded to the edge of the molded article or the protrusion of the second protrusion by using an adhesive or by thermocompression.

Two interlayer noise reduction structures having the same structure among the several interlayer noise reduction structures produced in this way are coupled by approaching them in opposite directions (S400). Combining two inter-floor noise reduction structures can be used as inter-floor noise reduction materials for multi-storey buildings.

The interlayer noise reduction structure described above is not limited to the configuration and method of the above-described embodiments, and the embodiments may be configured by selectively combining all or part of each of the embodiments so that various modifications can be made. .

Claims (10)

Base;
A first protrusion protruding from the base in a first direction;
A second protrusion formed in a different shape on the base from the first protrusion, and protruding from the base in a second direction opposite to the first direction; And
Including a cover covering the second protrusion,
The first protrusions are formed in plural, the plurality of first protrusions are formed at positions spaced apart from each other, and the inside of each first protrusion is empty to be filled with a filler,
The cover,
A first layer formed of synthetic resin or synthetic fibers and joined along the rim of the interlayer noise reduction structure; And
And a second layer formed of a synthetic resin or synthetic fiber different from the first layer and laminated on the first layer,
The interlayer noise reduction structure, wherein the first layer sags in a direction toward the inside of the first protrusion in a region surrounded by the plurality of second protrusions. The method of claim 1,
The interlayer noise reduction structure, characterized in that the cross-sectional area of the first protrusion gradually decreases as it approaches the first direction. The method of claim 1,
The interlayer noise reduction structure is formed to be combined with other interlayer noise reduction structures having the same structure,
The interlayer noise reduction structure, wherein the interlayer noise reduction structure is provided with a receiving portion capable of receiving the first protrusion of the other interlayer noise reduction structure in an area surrounded by a plurality of first protrusions. The method of claim 3,
When the inter-floor noise reduction structure and the other inter-floor noise reduction structure are coupled to each other, the first protrusion of any one of the inter-floor noise reduction structure and the other inter-floor noise reduction structure and the other base may be in the first direction or the second Floor noise reduction structure, characterized in that spaced apart from each other in the direction. The method of claim 3,
Each inlet port for introducing the filler into the first protrusion formed in the interlayer noise reduction structure is formed in a region surrounded by the plurality of second protrusions in the base,
The inlet is formed in a polygonal shape,
An interlayer, characterized in that one second protrusion is formed at a position adjacent to the edge of the polygon around the inlet, and the base is formed in a radial direction between two second protrusions at each position adjacent to the vertex of the polygon. Noise reduction structure. The method of claim 3,
The receiving part,
The first type into which the first protrusion of the noise reduction structure between the other floors is inserted: and
It is divided into a second type in which the first protrusion of the noise reduction structure between the other floors is not inserted,
The interlayer noise reduction structure, characterized in that the base formed at a position corresponding to the second type of receiving portion is formed to face each other with the base of the other interlayer noise reduction structure with the second type of receiving portion therebetween. The method of claim 1,
On the second protrusion,
A first center recess recessed in a first direction from an end portion of the second protrusion in the second direction;
A second center recess further recessed in the first direction from the first center recess and smaller than the first center recess; And
An interlayer noise reduction structure, characterized in that a radial recess that is recessed from the first center recess to a side surface of the second protrusion is formed. delete delete The method of claim 1,
The filler,
(a) air or water;
(b) any one of pearlite, vermiculite, styrofoam powder, aerated concrete, low ash lightweight aggregate, and glass bubble microspheres;
(c) (c1) 88 to 98.7 wt.% of water, (c2) 1 to 10 wt.% of cellulose, (c3) 0.1 to 1 wt.% of sodium carbonate, and (c4) 0.1 to 1 wt.% of urethane powder are mixed. One mixture;
(d) (d1) 87 to 98.7 wt.% of water, (d2) 1 to 10 wt.% of cellulose, (d3) 0.1 to 1 wt.% of citric acid, (d4) 0.1 to 1 wt.% of sodium carbonate, and (d5) ) A mixture of 0.1 to 1 wt.% of at least one of urethane powder, pearlite, vermiculite, styrofoam powder, aerated concrete, and glass bubble microspheres; And
(e) (e1) 89~98.9 wt.% of water, (e2) 1~10 wt.% of mineral oil or vegetable oil, (e3) at least one of pearlite, vermiculite, styrofoam powder, foam concrete, glass bubble microsphere 0.1 A mixture of ~1 wt.%,
Interlayer noise reduction structure, characterized in that formed in any one of.

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