KR101371502B1 - Inter-floor noise prevention module and a building comprising it - Google Patents

Abstract

The present invention relates to a floor noise preventing module and a building including the same, and are disposed on a ceiling partitioning floors in a building and spaced below the slab to define a ceiling space, and in a direction toward the slab. A housing in which an opening is formed; Sound absorbing material provided in the housing; And a membrane sheet installed on an upper side of the housing to shield the opening, wherein the membrane sheet generates vibration to dissipate noise transmitted from an upper side of the slab, and an interlayer noise preventing module is mounted on the ceiling spaced apart from the slab and the slab. It provides a building provided with a plurality of horizontally in the ceiling space formed by.

Description

Inter-floor noise prevention module and a building comprising it

The present invention relates to an inter-floor noise preventing module and a building including the same, and more particularly, a noise generated in an upper floor of a building and transmitted to a lower floor by being provided in a ceiling space defined by a slab and a ceiling partitioning an inter-floor in a building. The present invention relates to an interlayer noise preventing module capable of dissipating and a building including the same.

Floor impact sound is a sound radiated into a lower generation through floor slabs, ceilings, or walls when an impact such as a person walking or falling objects is applied on the upper floor of a multi-family house such as an apartment. In general, when a shock or vibration is directly applied to a concrete structure, it is converted into a solid wave sound, which is hardly attenuated, and is transmitted to another adjacent generation to radiate noise.

Floor impact sound is divided into light impact sound that generates a lot of high frequency components such as falling sounds of bowls, golf balls, and chair movements, and heavy impact sound that generates a lot of low frequency components such as adult walking and children's skipping. do.

However, in a building such as a multi-family house, a townhouse, an apartment building, etc., where walls and floors must be shared with neighboring households, such as a multi-family apartment, when the floor impact sound of the upper floor is transmitted to the lower floor as noise, the life of the lower floor is Not only will the environment get worse. It is the cause of the dispute between upstairs and downstairs.

In order to solve these problems, in order to reduce the interlayer noise between the upper layer and the lower layer, dustproofing, sound insulation and insulation are used. However, these materials not only have a very small amount of interlaminar noise attenuation, but also cause another problem of high layer height when a thicker material is applied to further reduce interlayer noise.

Korea Patent Registration No. 10-1045403

The present invention is provided in the ceiling space formed by the slab and the ceiling spaced apart from the slab to separate the floor between the floor noise prevention module for dissipating the noise to prevent the noise generated from the upper floor of the slab is transmitted to the floor below the ceiling. And it aims to provide a building comprising the same.

The present invention is a slab for partitioning the floor in the building and spaced apart below the slab is disposed on the ceiling defining a ceiling space, the housing having an opening in the direction toward the slab; Sound absorbing material provided in the housing; And a membrane sheet installed on an upper side of the housing to shield the opening, and including a membrane sheet to generate vibration to dissipate noise transmitted from an upper side of the slab.

According to another aspect of the present invention, the present invention provides a building in which a plurality of floor noise prevention modules are horizontally provided in the ceiling space formed by the slab and the ceiling spaced apart from the slab.

Interlayer noise preventing module and a building including the same according to the present invention has the following effects.

It is provided in the ceiling space formed by the slab and the ceiling that divides the floors in the building, so that the noise generated from the upper floor is absorbed or dissipated before being transmitted to the lower floor without being exposed to the outside, thereby preventing the noise from being transmitted to the lower floor. It can have an effect.

In particular, when the noise is transmitted from the upper layer of the membrane sheet of the interlayer noise preventing module, fine vibration is generated in the membrane sheet by the pressure difference between the sound absorbing material provided in the housing and the inside of the housing and the membrane sheet. Is prevented from being dissipated by the fine vibration of the membrane sheet and transferred to the lower layer.

In addition, a plurality of through holes are formed in the side wall of the housing, and the plurality of through holes are not formed in the entire area of the side wall of the housing, but are formed only in an area up to the height covered by the sound absorbing material provided in the housing. Since the through hole is not formed in the side wall area of the housing corresponding to the spaced space formed between the membrane sheets, the pressure in the spaced space may be maintained unchanged.

In addition, noise that is not incident on the membrane sheet may have an effect of being prevented from being transmitted to the lower layer by being absorbed by the sound absorbing material provided in the housing through the plurality of through holes formed in the side wall of the housing.

The interlayer noise prevention module further includes a tension adjusting means on the outside of the housing, so that the tension of the membrane sheet can be restored to its initial state when the membrane sheet sags by gravity when the interlayer noise prevention module is used for a long time. It can have an effect that can be used semi-permanently.

1 is a cross-sectional view showing a state in which a building between the floor noise prevention module according to the present invention is provided.
2 is a perspective view illustrating a state in which the membrane sheet is omitted in the interlayer noise preventing module according to FIG. 1.

1 is a cross-sectional view illustrating a state in which an interlayer noise preventing module according to the present invention is provided in a building, and FIG. 2 is a perspective view illustrating a state in which a membrane sheet is omitted from the interlayer noise preventing module according to FIG. 1. Prior to the detailed description for carrying out the present invention, the term 'building' described below is a concept that includes all of the multi-story structure, such as apartments, schools, malls.

1 and 2, the interlayer noise preventing module 100 according to the present invention includes a housing 110, a sound absorbing material 130, and a membrane sheet 150. In the building, the slab S is provided to partition the floor, and the ceiling space is formed by the ceiling 1 spaced apart from the slab S. The skylight space is provided with wiring such as an electrical facility necessary for the interior of a building. The upper side of the slab S becomes the upper layer, and the lower side of the ceiling 1 spaced below the slab S becomes the lower layer. The noise generated from the upper floor may be dissipated by the spaced ceiling space between the slab S and the ceiling 1, but the noise is dissipated because only a part of the noise is dissipated unless a condition that dissipates the noise is formed. Passed down to (1) to cause damage.

In order to prevent such a problem from occurring, an interlayer noise preventing module 100 according to the present invention is provided between the slab S and the ceiling 1. First, the housing 110 is placed on the ceiling 1. Posted in The housing 110 is formed of four side surfaces 111 to have a shape in the form of 'ㅁ' when viewed from the top. The housing 110 has an opening formed in a direction toward the slab S, and a lower surface 113 of the housing 110 disposed on the ceiling 1 may be closed by forming a bottom surface 113. It may be formed by opening. When the lower portion of the housing 110 is opened, when the housing 110 is disposed on the ceiling 1, the lower portion of the housing 110 may be closed by the ceiling 1. In the following detailed description, as shown in FIG. 1, the housing 110 having the bottom surface 113 will be described as an example.

The housing 110 may be formed of any one of metal, plastic-based material, gypsum board, and plywood. In general, the housing 110 may be manufactured using metal or plastic-based material. The thicknesses of the four side walls 111 forming the housing 110 are formed within a range of 0.5 to 2 mm.

As shown in FIGS. 1 and 2, the sidewalls 111 are provided with a plurality of through holes 115 spaced apart from each other. The plurality of through-holes 115 is the housing 110 before the noise is transmitted to the lower floor of the ceiling (1) when the noise generated in the upper floor, the upper side of the slab (S) is transmitted to the ceiling space. It is formed to be delivered to the sound absorbing material 130 provided inside. One sidewall 111 of the four sidewalls 111 of the housing 110 is such that the porosity by the plurality of through holes 115 is in the range of 0.5 to 2.0%. And the size of one of the through holes 115 of the plurality of through holes so that the diameter of the through hole 115 is in the range of 0.05 to 0.5mm.

The plurality of through holes 115 formed in the side wall 111 of the housing 110 correspond to an upper surface of the sound absorbing material 130 provided in the housing 110 from the lower portion of the housing 110. Allow it to form between heights. That is, the plurality of through holes 115 are generated only within a limited area that can be covered by the sound absorbing material 130. This is because the plurality of through-holes 115 are formed so that the noise generated from the upper layer of the slab (S) is transmitted to the sound absorbing material 130, the side wall of the housing 110 of the height that the sound absorbing material 130 is not filled The through hole 115 does not need to be formed.

The sound absorbing material 130 is provided inside the housing 110 to absorb the noise generated from the upper layer of the slab (S) to prevent the noise from being transmitted to the lower layer of the ceiling (1). The sound absorbing material 130 is somewhat high in density, preferably made of a fiber material. In the present invention, the sound absorbing material 130 is provided with a porous sound absorbing material such as glass wool or microfiber sound absorbing material having a density of 0.5 kg / m ³ or more as the sound absorbing material 130 in consideration of sound absorption in the high frequency band. That is, fine holes are formed in the sound absorbing material 130 so that when noise is absorbed into the sound absorbing material 130 through the micro holes, the noise may be dissipated by friction or the like inside the sound absorbing material 130.

The sound absorbing material 130 may be coated. Referring to FIG. 1, an upper side surface of the sound absorbing material 130 may be coated. A glass cloth may be used as a coating material for covering the sound absorbing material 130. When the sound absorbing material 130 is provided inside the housing 110, the sound absorbing material 130 may be spaced apart from the opening of the housing 110 so as not to disturb the vibration of the membrane sheet 150 to be described later installed in the housing 110. Equipped. In general, the sound absorbing material 130 is provided to come up to a height of 75% or less with respect to the height of the side wall 111 of the housing 110, for example, the height of the side wall 111 of the housing 110 is 100mm In this case, the sound absorbing material 130 provided in the housing 110 may be provided to a height of up to 75 mm from the bottom surface 113 of the housing 110.

The membrane sheet 150 is installed in the housing 110, and is installed to shield an opening formed toward the slab S in the housing 110. The membrane sheet 150 is installed to shield the opening of the housing 110, and when the sound absorbing material 130 is provided inside the housing 110, the pressure of the space between the membrane sheets 150 ( P ') is different from the pressure (P) of the outside of the housing 110. Therefore, when noise is transmitted from the upper floor to the ceiling space, the membrane sheet 150 vibrates finely due to the difference between the pressure P outside the housing 110 and the pressure P ′ of the space apart from the interior of the housing 110. It can dissipate the noise.

The plurality of through holes 115 formed in the side wall 111 of the housing 110 are not formed in the entire area of the side wall 111 of the housing 110, but are provided inside the housing 110. It is formed only in the region up to the height covered by the sound absorbing material 130, the side wall 111 region of the housing 110 corresponding to the separation space formed between the sound absorbing material 130 and the membrane sheet 150 Since the through-hole 115 is not formed, the pressure in the separation space may be maintained to be unchanged.

Like the housing 110, the membrane sheet 150 may be formed of a metal or a plastic-based material such as acrylic. In addition, as described above, the membrane sheet 150 may be formed to have a flexible structure in order to vibrate. In addition, the membrane sheet 150 has a surface density of the membrane sheet 150, a thickness of the membrane sheet 150, and between the membrane sheet 150 and the sound absorbing material 130 according to the noise of a frequency to be dissipated. The separation distance can also be adjusted.

The membrane sheet 150 may be overpowered by gravity over time. When the membrane sheet 150 is struck, the effect of dissipating noise due to vibration of the membrane sheet 150 is reduced, and thus a means for adjusting the tension of the membrane sheet 150 is required. Accordingly, as shown in FIGS. 1 and 2, the tension adjusting means 170 may adjust the tension of the membrane sheet 150 outside the housing 110.

The tension adjusting means 170 shown in FIGS. 1 and 2 is merely an example according to one embodiment, and the tension adjusting means 170 need not be limited thereto and may be provided in various forms. The tension adjusting means 170 illustrated in FIGS. 1 and 2 includes a bracket 171, a lever 173, and a rotation shaft 175.

The bracket 171 is provided with a pair facing each other on the outer side of the side wall of the housing 110. The lever 173 is hinged to the outside of each of the pair of brackets 171 facing each other, and the rotating shaft 175 is hinged between the pair of brackets 171 facing each other. When the lever 173 and the hinge shaft 175 are connected to each other, and the lever 173 and the hinge shaft 175 are hinged, when the user or worker rotates the lever 173, the lever The hinge shaft 175 may be rotated in conjunction with rotation of the 173.

The membrane sheet 150 may be connected to the rotating shaft 175 of the tension adjusting means 170. Therefore, when the vibration effect of the membrane sheet 150 is reduced by the deflection of the membrane sheet 150, the tension of the membrane sheet 150 may be adjusted to an initial state by turning the lever 173. In addition, although the rotation shaft 175 is rotated by manually operating the lever 173 in the above description, the rotation shaft 175 may be automatically rotated by connecting a motor to the rotation shaft 175.

On the other hand, the interlayer noise prevention module 100 as described above is not provided with only one in the ceiling space defined by the slab (S) and the ceiling (1) is provided with a plurality of spaced apart in the horizontal direction. Therefore, it is possible to prevent noise from being transmitted to the lower floor by dissipating the noise more effectively than when the interlayer noise preventing module 100 is provided with only one.

Hereinafter, the operation of the interlayer noise preventing module will be described.

Noise (or vibration) is transmitted from the upper layer through the slab S which is an interlayer structure. At this time, the pressure P of the outside of the housing 110 of the impact noise prevention module 100 is spaced apart between the sound absorbing material 130 provided in the housing 110 and the membrane sheet 150. Since the pressure (P ') is different from the membrane sheet 150 by the transmitted noise to make a fine vibration.

A part of the transmitted noise (or vibration) is incident on the membrane sheet 150 which performs fine vibration, and noise is inputted by the micro vibration of the membrane sheet 150 to be converted into vibration energy and attenuated. Dissipated.

As described above, the noise generated in the upper floor and transmitted to the ceiling space is not all incident on the membrane sheet 150. Noise not incident on the membrane sheet 150 may be transmitted to the inside of the housing 110 through a plurality of through holes 115 formed in the sidewall 111 of the housing 110. Since the sound absorbing material 130 that absorbs noise is provided inside the housing 110, the noise transmitted through the plurality of through holes 115 formed on the sidewall of the housing 110 is absorbed by the sound absorbing material 130. Absorbed by and dissipated without returning to the outside of the housing 110.

On the other hand, when the interlayer noise prevention module 100 is used for a long time, the membrane sheet 150 is sag due to gravity. When the membrane sheet 150 sags, the number of fine vibrations decreases from the initial stage, and thus the effect of dissipating noise may be reduced. Therefore, when the deflection of the membrane sheet 150 occurs, the tension of the membrane sheet 150 is restored to an initial state by using the tension adjusting means 170 provided outside the side wall 111 of the housing 110. Adjust

On the other hand, when applying the interlayer noise prevention module according to the present invention as described above, before the noise generated in the upper floor is dissipated in the ceiling space formed by the slab and the ceiling between the upper floor and the lower floor, the noise of the upper floor to the lower floor. Can be prevented from being delivered.

In particular, the pressure difference between the sound absorbing material provided inside the housing and the membrane sheet causes the pressure difference between the inside of the housing and the outside of the housing to cause the membrane sheet to vibrate finely, and the noise energy transmitted from the upper layer to the membrane sheet. As it enters, the noise energy is converted into vibration energy and dissipated to prevent the noise from being transferred to the lower floor.

A plurality of through holes are formed in the side wall of the housing. If a part of the noise that is not incident to the membrane sheet is in the ceiling space, the plurality of through holes are absorbed by the sound absorbing material provided in the housing and are not emitted to the ceiling space again. Noise can be prevented from passing downstairs.

The interlayer noise preventing module further includes a tension adjusting means, so that even if the membrane sheet is sag due to long-term use of the interlayer noise preventing module, the tension of the membrane sheet can be restored to its initial state by using the tension adjusting means. It can have the effect that the noise prevention module can be used semi-permanently.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

110: housing 111: through hole
130: sound absorbing material 150: membrane sheet
170: tension control means

Claims (9)

A slab partitioning the floors in the building and spaced apart below the slab and disposed on a ceiling defining a ceiling space, the housing having an opening in a direction toward the slab;
Sound absorbing material provided in the housing; And
A membrane sheet installed on an upper side of the housing to shield the opening and generating vibration to dissipate noise transmitted from an upper side of the slab; And
Interlayer noise preventing module including a tension control means for adjusting the tension of the membrane sheet installed in the housing on the outside of the housing. A slab partitioning the floors in the building and spaced apart below the slab and disposed on a ceiling defining a ceiling space, the housing having an opening in a direction toward the slab;
Sound absorbing material provided in the housing; And
It is installed on the upper side of the housing to shield the opening, and includes a membrane sheet for generating vibration to dissipate the noise transmitted from the upper side of the slab,
The side wall of the housing is formed with a plurality of through holes for transmitting the noise transmitted from the upper side of the slab to the sound absorbing material,
The side wall of the housing has a porosity of 0.5 to 2.0% by the plurality of through holes,
The size of one of the through holes of the plurality of through holes is an interlayer noise preventing module is formed in the range of 0.05 to 0.5 mm in diameter. The method according to claim 1,
Interlayer noise preventing module is formed on the side wall of the housing a plurality of through holes for transmitting the noise transmitted from the upper side of the slab to the sound absorbing material. The method of claim 3,
The side wall of the housing has a porosity of 0.5 to 2.0% by the plurality of through holes,
The size of one of the through holes of the plurality of through holes is an interlayer noise preventing module is formed in the range of 0.05 to 0.5 mm in diameter. The method according to claim 2 or 3,
The plurality of through holes are interlayer noise preventing module is formed between the height corresponding to the upper surface of the sound absorbing material provided in the interior of the housing from the lower side of the housing. The method according to claim 1 or 2,
The side wall of the housing is formed of one of metal, plastic based material, gypsum board and plywood,
The thickness of the side wall of the housing is an interlayer noise preventing module is formed in the range of 0.5 to 2mm. The method according to claim 1 or 2,
The sound absorbing material is an interlayer noise preventing module comprising a glass wool or microfiber sound absorbing material. The method according to claim 1 or 2,
The sound absorbing material is coated,
The cladding material covering the sound absorbing material includes a glass cloth. The interlayer noise preventing module according to claim 1 or 2 is provided with a plurality of horizontally in the ceiling space formed by the slab and the ceiling spaced apart from the slab.

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