KR102573481B1 - Instrument for dividing the area where the mortar is to be placed, floor structure of building that includes the instrument, and construction method of building floor structure that includes the instrument - Google Patents

Abstract

The present invention relates to a segmented body for buffering noise and impact sound between floors, a building floor structure including the segmented body, and a method for constructing the same. Including a sound insulation member to block the impact sound inside, a segmented body that prevents the impact sound generated from the finishing mortar in one area from being transmitted to the finishing mortar in another area, a building floor structure including the segmented body, and the floor structure It's about how to build it. A building floor structure including a segmented body for buffering inter-floor noise and impact sound according to the present invention is installed on a concrete slab layer connected to a wall of a building, on top of the concrete slab layer, and reduces floor impact sound It includes an impact sound reducing layer including a buffer material and a finishing mortar layer poured on top of the impact sound reducing layer, wherein the finishing mortar layer is installed on the upper surface of the impact sound reducing layer, and the upper surface of the impact sound reducing layer segmented into a plurality of zones, including a segmented body including a sound insulation member to block impact sound and a finishing mortar poured into each of the plurality of zones segmented by the segmented body, each of the plurality of zones It is characterized in that the impact sound generated on the poured finishing mortar is not transmitted to other adjacent areas by the sound insulation member.

Description

Inter-floor noise and impact sound buffering, building floor structure including the segment, and its construction method BUILDING FLOOR STRUCTURE THAT INCLUDES THE INSTRUMENT}

The present invention relates to a segmented body for buffering inter-floor noise and impact sound, a building floor structure including the segmented body, and a method for constructing the same. A segmented body that allows the finishing mortar to be poured in each zone and includes a sound insulation member to block the impact sound inside so that the impact sound generated from the finishing mortar in one zone is not transmitted to the finishing mortar in another zone, and the segmented element It relates to a building floor structure and a method for constructing the floor structure.

In recent years, it is a reality that complaints from residents are increasing as floor impact noise is generated between floors of apartment houses due to changes in architectural structures such as the introduction of steel frames and the reduction of slab thickness in accordance with the high-rise construction of houses.

As the inter-floor noise problem emerged seriously in apartment housing, regulations on housing construction standards were further strengthened and revised. The regulations on housing construction standards stipulate that the floor impact sound between each floor should be less than 58 decibels (db) for light impact sound and less than 50 decibel (db) for heavy impact sound, or a standard floor structure determined and announced by the Minister of Construction and Transportation. there is.

Recently, in order to reduce such floor impact sound, an absorption panel capable of absorbing floor impact sound is used during the construction of a building or apartment house, so that floor impact sound is transmitted to a concrete slab by dispersing and absorbing the floor impact sound to transmit noise between floors. is minimizing

Although this absorption panel has not been clearly established until now, it is generally installed between the concrete slab layer and the finishing mortar layer, and includes various types of buffer materials. The buffer included in the absorption panel is provided in a variety of structures, and generally has a structure in which a Styrofoam material having a certain thickness is placed and buffer materials of various shapes and materials are designed in a sandwich form therebetween.

However, there is a problem in that it is not yet possible to completely reduce noise between floors of a building because the absorption panel alone cannot reliably absorb floor impact sound.

As expected, the absorbing panel including the buffer material is to prevent the transmission of the impact sound generated from the floor of the upper residential space to the lower residential space, but the absorbing panel alone does not reduce the transmission of the impact sound in the vertical direction and the vibration caused by the impact sound. judged

Therefore, there is a need for a new idea for reducing the transmission of vibrations caused by the impact sound in the vertical direction and the impact sound.

Republic of Korea Patent Publication No. 10-2009-0113528 (published on November 02, 2009)

The object of the present invention for solving the above-mentioned problems is to divide the area where the finishing mortar is to be poured into a plurality of areas so that the finishing mortar is poured in each area, and the finishing mortar in any one area including a sound insulation member to block the impact sound inside. It is to provide a segmental element for buffering interlayer noise and impact sound so that the impact sound generated in is not transmitted to the finishing mortar in other areas.

Another object of the present invention for solving the above problems is to divide a plurality of areas in which the finishing mortar is to be poured so that the finishing mortar is poured in each area, and to finish any one area, including a sound insulation member that blocks impact sound therein. It is to provide a building floor structure including a segmented body that prevents impact sound generated from the mortar from being transmitted to the finishing mortar in another area and a method of constructing the building floor structure.

In order to achieve the above object, a building floor structure including a segment member for buffering inter-floor noise and impact sound according to an embodiment of the present invention includes a concrete slab layer connected to a wall of a building, and a concrete slab layer of the concrete slab layer. It is installed on the top and includes an impact sound reduction layer including a buffer material for reducing floor impact sound and a finishing mortar layer poured on top of the impact sound reduction layer, wherein the finishing mortar layer comprises the impact sound reduction layer. It is installed on the upper surface of the impact sound reduction layer, and the upper surface of the impact sound reduction layer is segmented into a plurality of zones, and the segment body including a sound insulation member for blocking impact sound and the segment body are respectively cast in the plurality of zones segmented by the segment element. Including the finishing mortar, it is characterized in that the impact sound generated on the finishing mortar poured into each of the plurality of zones is not transmitted to other adjacent zones by the sound insulating member.

The segmentation element includes a horizontal segmentation element and a vertical segmentation element that segment an upper surface of the impact sound reducing layer in a grid shape having a plurality of regions.

The segmental body further includes a pair of fixing members formed so that cross sections are symmetrical to each other in a 'b' shape and spaced apart from each other by a predetermined distance and installed on the impact sound reducing layer, and the sound insulating member is fixed to the pair of fixing members. installed between members.

In order to achieve the above object, a method for constructing a building floor structure including a segmented body for buffering inter-floor noise and impact sound according to an embodiment of the present invention reduces impact sound on the upper surface of a concrete slab layer connected to a wall of a building Installing an impact sound reducing layer including a buffer material and placing a finishing mortar layer on the upper surface of the impact sound reducing layer, and placing a finishing mortar layer on the upper surface of the impact sound reducing layer. Installing a segmentation member including a sound insulating member for blocking impact sound on the upper surface of the impact sound reduction layer to segment the upper surface of the impact sound reduction layer into a plurality of zones, and each of the plurality of zones segmented by the segmentation element Including the step of pouring the finishing mortar, it is characterized in that the impact sound generated on the finishing mortar poured in each of the plurality of zones is not transmitted to other adjacent zones by the sound insulation member.

In order to achieve the above object, the segmental element for buffering inter-floor noise and impact sound according to an embodiment of the present invention is installed on the upper surface of the impact sound reduction layer, and the upper surface of the impact sound reduction layer is segmented into a plurality of zones, Including a sound insulation member that allows finishing mortar to be poured in each of the plurality of zones and blocks impact sound, the impact sound generated from the finishing mortar cast in any one of the plurality of zones is transferred to the finishing mortar placed in another adjacent zone. It is characterized by not transmitting.

According to the present inventors, a segmented body for buffering noise and impact sound between floors, a plurality of areas where finishing mortar is to be poured are divided into a plurality of areas so that finishing mortar is poured in each area, and a sound insulation member for blocking impact sound is included in any one area. There is an effect that the impact sound generated from the finishing mortar is not transmitted to the finishing mortar in other areas.

According to the present invention, a building floor structure including a segmented element for buffering inter-floor noise and impact sound, and a method for constructing the building floor structure, the segmental element is installed on the upper surface of an impact sound reducing layer including a buffer material to reduce impact sound, thereby reducing impact sound The upper surface of the layer is divided into a plurality of zones, and as the finishing mortar is poured into each of the divided zones, the impact sound generated on the finishing mortar is prevented from being transmitted to different zones on the impact sound-reducing layer, and the impact sound transmitted in the transverse direction is prevented. It has a blocking effect.

1 is a cross-sectional structure view between floors of a building in which a building floor structure including a segmented body for buffering inter-floor noise and impact sound according to the present invention is constructed.
2 is a view showing a state in which segmentation elements are installed on the upper surface of the impact sound reducing layer according to the present invention.
3 is a view showing the shape of a segmented body according to the present invention.
4 is a view showing a state of another embodiment in which segmentation elements are installed on the upper surface of the impact sound reducing layer according to the present invention.
5 is a view showing the flow of a construction method for a building floor structure including a segmented body for buffering inter-floor noise and impact sound according to the present invention.
6 is a view showing an example of on-site construction of a building floor structure construction method including a segmented body for buffering inter-floor noise and impact sound according to the present invention.
7 is a view showing a segmented body according to another embodiment of the present invention.
8 is a cross-sectional view of a sound insulating member according to another embodiment of the present invention.
9 is a view showing a segmented body according to another embodiment of the present invention.
10 is a cross-sectional structure view between floors of a building in which a building floor structure including a segment member for buffering inter-floor noise and impact sound according to another embodiment of the present invention is constructed.
11 is a view showing appearances of a second impact sound reducing layer according to the present invention and a segmental body according to another embodiment of the present invention.
12 is a cross-sectional structure view between floors of a building in which a building floor structure including a segment member for buffering inter-floor noise and impact sound according to another embodiment of the present invention is constructed.
13 is a cross-sectional structure view between floors of a building in which a building floor structure including a segmented body for buffering inter-floor noise and impact sound according to another embodiment of the present invention is constructed.
14 is a view showing an embodiment of a segmented body constructed together with an impact sound reducing layer according to the present invention.

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to components of each drawing, it should be noted that the same components have the same numerals as much as possible, even if they are displayed on different drawings.

And, in describing the embodiments of the present invention, if it is determined that a detailed description of a related known configuration or function hinders understanding of the embodiments of the present invention, the detailed description will be omitted.

Also, terms such as first, second, A, B, (a), and (b) may be used to describe components of an embodiment of the present invention. These terms are only used to distinguish the component from other components, and the nature, order, or order of the corresponding component is not limited by the term.

In this specification, the singular form also includes the plural form unless otherwise specified in the phrase. The terms "comprising" and/or "comprising" used in the specification do not exclude the presence or addition of one or more other components other than the recited components.

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

1 is a cross-sectional structure view between floors of a building in which a building floor structure including a segment 310 for buffering inter-floor noise and impact sound according to the present invention is constructed.

Referring to FIG. 1, a building floor structure (hereinafter referred to as a 'floor structure') including a segment 310 for buffering inter-floor noise and impact sound according to the present invention is a concrete slab connected to the wall 10 of the building It includes a slab layer 100, an impact sound reduction layer 200 installed on top of the concrete slab layer 100, and a finishing mortar layer 300 poured on top of the impact sound reduction layer 200. In addition, on the concrete slab layer 100, the impact sound reduction layer 200 may further include a side cushioning material 220 constructed at each edge position to be installed.

The concrete slab layer 100 according to the present invention is manufactured integrally with the wall 10 of the building or is manufactured separately and then firmly coupled to the wall 10. An impact sound reduction layer 200 is installed on the upper surface of the concrete slab layer 100 connected to the wall 10 of the building.

The impact sound reduction layer 200 according to the present invention reduces the floor impact sound generated and transmitted from the finishing mortar layer 300. To this end, the impact sound reducing layer 200 includes a buffer material for reducing impact sound on the floor. Any buffering material included in the impact sound reduction layer 200 may be used to have insulation-buffering and soundproofing functions and to block, suppress, and reduce impact energy. As such materials for insulation, buffering, and floor impact sound reduction In general, glass fiber (rock wool plate-like structure, glass wool, rock wool) or synthetic rubber, waste tire pulverized chips, cross-linked 5-40 times foamed PE sheet, moisture- and waterproof-coated glass wool, moisture- and waterproof-coated rock wool, moisture- and waterproof-coated PET fiber Sheets, EVA foam panels, EPS panels, urethane panels, binder-coated waste tire chips, anti-vibration rubber, asphalt-coated sheets, and polymer foams may be selected and used.

The finishing mortar layer 300 according to the present invention is formed by pouring on top of the impact sound reducing layer 200. The finishing mortar layer 300 is divided into a plurality of zones by segmenting the upper surface of the impact sound reduction layer 200, and a segment 310, and a finishing mortar that is poured into a plurality of zones divided by the segment 310, respectively. (320).

FIG. 2 is a view showing the shape of the segmentation element 310 installed on the upper surface of the impact sound reducing layer 200 according to the present invention, and FIG. 3 is a view showing the shape of the segmentation element 310 according to the present invention.

Referring to FIG. 2, a plurality of segments 310 according to the present invention are installed on the upper surface of the impact sound reducing layer 200, and the upper surface of the impact sound reducing layer 200 is divided into a plurality of zones 201, 202, and 203. segment Referring to FIG. 3, the segmental body 310 has a certain height in the upward direction (z direction in FIG. 3) and, as an embodiment, is formed to extend in the vertical direction (y direction in FIGS. 2 and 3), The upper surface of the impact sound reducing layer 200 may be segmented into a plurality of regions 201, 202, and 203 having a long shape in a vertical direction (y direction in FIG. 2). Finishing mortar 320 is poured into each section 201, 202, 203 segmented by the segmental body 310, respectively.

On the other hand, referring to FIG. 3 again, the segmental body 310 is a fixing member 313 having a 'b' shape in cross section in FIG. 3 and a symmetrical 'b' shape (z axis symmetry in FIG. 3). It includes fixing parts 311 and 313 including the member 311 . Bottom surfaces of each of the fixing members 311 and 313 are installed in contact with the upper surface of the impact sound reducing layer 200 .

The fixing parts 311 and 313, that is, the pair of fixing members 311 and 313 are positioned to be spaced apart from each other, and the sound insulating member 315 is positioned where the pair of fixing members 311 and 313 are spaced apart from each other. . The sound insulation member 315 transmits the impact sound generated from the finishing mortar 320 placed in one area (eg, 202) to the finishing mortar 320 placed in another area (eg, 201, 203). block the That is, a sound insulating member 315 is included in the center of the segment 310 to absorb and block impact sound. Therefore, the impact sound generated on the finishing mortar 320 poured in each of the plurality of zones and proceeding in the horizontal direction (x direction in FIG. 2) is blocked by the sound insulation member 315 of the segment 310 to finish the adjacent zones. It is not transmitted to the mortar 320 to reduce the range in which interfloor noise occurs.

The segmental body 310 according to the present invention can divide the area where the finishing mortar 320 is to be poured, with the effect of reducing the range in which interfloor noise occurs by preventing transmission of impact sound to other areas adjacent to the area where the impact sound occurs, It also has the effect of making the casting of the finishing mortar 320 easier.

In summary, the segmental element 310 according to the present invention includes a sound insulation member 315 that blocks impact sound. The segmentation element 310 is installed on the upper surface of the impact sound reducing layer 200 and segments the upper surface of the impact sound reducing layer 200 into a plurality of regions 201 , 202 , and 203 . At this time, the finishing mortar 320 is poured into each of the plurality of segments 201, 202, and 203. The segmental body 310 is a plurality of zones (201, 202, 203) of any one zone (201, 202, 203) of the impact sound generated from the finishing mortar (320) placed in the adjacent other zone (201, 202, 203) It is possible to prevent delivery to the finished mortar 320 poured in.

On the other hand, as the sound insulation member 315 of the segment 310, any one may be used that has insulation-buffering and soundproofing functions and is intended to block, suppress, and reduce impact energy, and these types of insulation, buffering, and floor impact sound As reducing materials, in general, glass fiber (rock wool plate-like structure, glass wool, rock wool), synthetic rubber, scrap tire pulverized chips, cross-linked 5-40 times foamed PE sheet, moisture-proof and waterproof coated glass wool, moisture-proof and waterproof coated rock wool, moisture-proof and waterproof coating PET fiber sheet, EVA foam panel, EPS panel, urethane panel, binder-coated waste tire chips, anti-vibration rubber, asphalt-coated sheet, polymer foam, and the like.

4 is a view showing a state of another embodiment in which the segment 310 is installed on the upper surface of the impact sound reducing layer 200 according to the present invention.

Referring to FIG. 4, the segment 310 according to the present invention includes a plurality of horizontal segment segments ( 310a) and a plurality of longitudinal segments 310b.

The horizontal segment 310a is installed in the horizontal direction (x direction in FIG. 4 ) on the upper surface of the impact sound reducing layer 200, and the vertical segment 310b is installed in the vertical direction on the upper surface of the impact sound reducing layer 200 ( y direction in FIG. 4). The horizontal segment 310a and the vertical segment 310b form a plurality of rectangular regions 211 to 219 having each intersection point as a vertex on the upper surface of the impact sound reducing layer 200 . The finishing mortar 320 is poured into each of the plurality of zones 211 to 219 formed by the horizontal segment 310a and the vertical segment 310b. As described above, the impact sound generated from the finishing mortar 320 in any one of the plurality of zones 211 to 219 (for example, 215) is not transmitted to other adjacent zones 211 to 214 and 216 to 219. .

Therefore, as the upper surface of the impact sound reducing layer 200 is segmented in a lattice shape by the horizontal segmentation elements 310a and the vertical segmentation elements 310b, the range in which interlayer noise is generated can be further reduced.

5 is a view showing the flow of a method for constructing a building floor structure including a segment 310 for buffering noise between floors and impact sound according to the present invention, and FIG. 6 is a segment element for buffering noise between floors and impact sound according to the present invention. It is a view showing an on-site construction embodiment of a building floor structure construction method including (310).

A building floor structure construction method (hereinafter referred to as 'construction method') including a segment 310 for inter-floor noise and impact sound buffering according to the present invention is a wall of a building (hereinafter referred to as 'construction method'), referring to FIGS. 10) installing an impact sound reduction layer 200 including a buffer for reducing impact sound on the upper surface of the concrete slab layer 100 connected to (S103, FIG. 6 (C)) and the upper surface of the impact sound reduction layer 200 It includes the step of pouring a finishing mortar (mortar) layer 300 (S104, Fig. 6 (D) and (E)).

In the construction method according to the present invention, before the step (S103) of installing the impact sound reducing layer 200 including a buffer material for reducing impact sound on the upper surface of the concrete slab layer 100 connected to the wall 10 of the building, the impact sound A step of constructing a side cushioning material at each edge position where the reduction layer 200 is to be installed (S101, FIG. 6(B)) may be further included.

In step S103 of installing the impact sound reduction layer 200 including the impact sound damping material on the upper surface of the concrete slab layer 100 connected to the wall 10 of the building (S103), after the side buffer material is installed, the wall of the building An impact sound reduction layer 200 is constructed on the upper surface of the concrete slab layer 100 connected to (10). The impact sound reducing layer 200 includes a cushioning material for reducing floor impact sound, and examples of the impacting material are as described above.

In the step of pouring the finishing mortar layer 300 on the upper surface of the impact sound reducing layer 200 (S104), the upper surface of the impact sound reducing layer 200 is segmented into a plurality of zones. Installing a segmentation body 310 including a sound insulation member 315 for blocking impact sound (S105, (D) in FIG. 6) and finishing mortar in a plurality of zones segmented by the segmentation body 310, respectively ( 320) is poured (S107, FIG. 6 (E)).

Meanwhile, after step S103, a step (not shown) of installing a lightweight aerated concrete layer (not shown) and/or a heating pipe (not shown) on the upper surface of the impact sound reducing layer 200 may be further included. Therefore, after the step of installing the lightweight aerated concrete layer and/or the heating pipe, step S104 proceeds. In addition, after step S107, a step (not shown) of further installing a floor decoration material on the upper surface of the finishing mortar layer 300 may be further included.

Figure 1 and Figure 2 below are tables and graphs showing the results of measuring stratification sound by the segmental body 310 according to the present invention, the floor structure including the segmental body 310 and the construction method through the floor structure.

<Figure 1>

<Figure 2>

In order to confirm the floor impact sound reduction characteristics of the floor structure using the segmental body 310 according to the present invention and the construction method through the floor structure, the floor impact sound was measured after construction (FIG. 6(F)).

As a result of the measurement, the single numerical evaluation amount of the weight impact sound of the basic slab value without the segmental element 310 installed was 51 dB. However, after constructing the segmental body 310 according to the present invention, the single numerical evaluation amount of the weight impact sound measured 7 days later was 45 dB, and the single numerical evaluation amount of the weight impact sound measured 24 days later was 41 dB, which was rated as 2nd grade (41 to 41 dB). 43 dB). Therefore, it can be confirmed that the transmission of impact sound is very excellent by the segmental element 310 .

7 is a view showing a segmented body 310 according to another embodiment of the present invention, and FIG. 8 is a view showing a cross section of a sound insulating member 315 according to another embodiment of the present invention.

Referring to FIGS. 7 and 8 , the segmental element 310 according to another embodiment of the present invention is installed between a pair of fixing members 311 and 313 and a pair of fixing members 311 and 313 for sound insulation. A honeycomb structure 317 in which a plurality of honeycomb cells 318 are coupled is formed on an outer circumferential surface of the sound insulating member 315. That is, on the outside of the honeycomb structure 317, each of the fixing members 311 and 313 comes into contact with some surfaces spaced apart from each other, and on the inside of the honeycomb structure 317, they come into contact with each surface of the sound insulating member 315.

The honeycomb structure 317 according to the present invention includes a plurality of honeycomb cells 318 in the shape of hexagonal columns having spaces therein. Meanwhile, the honeycomb structure 317 according to the present invention may be made of a silicone rubber material having a high shock absorption rate.

A state in which a plurality of hexagonal column-shaped honeycomb cells 318 are coupled and formed to be adjacent to each other so that a pair of fixing members 311 and 313 are formed to cover the outer surface of the sound insulating member 315 and some surfaces spaced apart from each other. is as shown in Fig. 7, and the cross section of the honeycomb structure 317, that is, the cross section of the honeycomb cell 318 in the shape of a hexagonal column is as shown in Fig. 8.

The inner surface of the honeycomb structure 317 according to the present invention is located on the outer surface of the sound insulation member 315, and the outer surface of the honeycomb structure 317 is formed by a pair of fixing members 311 and 313 spaced apart from each other. It is formed to be in contact with some surface.

As described above, the honeycomb structure 317 according to the present invention generates and transmits impact sound generated from the finishing mortar 320 cast in any one of the plurality of zones 201 to 203 and/or 211 to 219. absorb The honeycomb structure 317 in which a plurality of honeycomb cells 318 in the shape of a hexagonal column are combined is light and strong, and is strong against bending or compression, so it can absorb moving impact sound. Therefore, the honeycomb structure 317 of the segmental body 310 blocks the impact sound generated from the finishing mortar 320 cast in one of the plurality of zones from being transmitted to other adjacent zones.

Meanwhile, the honeycomb structure 317 according to the present invention may be made of a silicon rubber material having high thermal conductivity. Therefore, after the finishing mortar 320 is poured, the heat generated from the finishing mortar 320 can move along the honeycomb structure 317 to prevent defects such as cracks caused by heat during the curing period after the construction of the finishing mortar 320. can

Also, the plurality of hexagonal columnar honeycomb cells 318 of the honeycomb structure 317 may be formed such that one end in the longitudinal direction (y direction in FIG. 7) is open and the other end is closed. One end of the honeycomb cell 318 is opened to discharge heat generated from the finished mortar 320 and transferred to the inside of the honeycomb cell 318, and the other end of the honeycomb cell 318 is closed. This is to prevent liquid, particularly rainwater from flowing into the honeycomb structure 317 in case of rain. It is possible to selectively open or close one end and the other end of the honeycomb structure, so it is possible to select a direction in which heat generated after the construction of the finishing mortar 320 is discharged, and a honeycomb cell in a position where liquid may flow ( 318) can be closed to prevent construction defects due to inflow of liquid.

9 is a view showing a segmental body 310 according to another embodiment of the present invention.

In the segmental body 310 according to the present invention, referring to FIG. 9 , side surfaces of the fixing members 311 and 313 may be formed to have an inclination. That is, the cross-section of the segmental body 310 may have an inverted funnel shape as a whole. The segmental element 310 may have a shape that gradually widens in a downward direction (-z direction) from the center as a whole, and the bottom surface of the widest shape in the cross section of the segmental element 310 is the upper surface of the impact sound reduction layer 200. combined and installed in As the segmental body 310 has an inclination so as to gradually widen downward from the center of the segmental body 310, the load according to the pouring of the finishing mortar 320 in a plurality of areas segmented by the segmental body 310 can be dispersed to solve the problem of damage to the fixing members 311 and 313 of the segment 310, which may occur due to the pouring of the finishing mortar 320.

10 is a cross-sectional structure view between floors of a building in which a building floor structure including a segment 310 for buffering inter-floor noise and impact sound according to another embodiment of the present invention is constructed.

In the building floor structure according to the present invention, referring to FIG. 10 , another impact sound reduction layer 210 may be further installed at a position between the segmental elements 310 on the upper surface of the impact sound reduction layer 200 . Meanwhile, in the following, in order to separately describe the impact sound reduction layer 210 described with reference to FIG. 10 and the impact sound reduction layer 200 described above with reference to FIG. 1 , the impact sound reduction layer 200 described above with reference to FIG. 1 ) is referred to as the first impact sound reduction layer 200, and the impact sound reduction layer 210 additionally shown in FIG. 10 is referred to as the second impact sound reduction layer 210.

The second impact sound reducing layer 210 according to the present invention, like the first impact sound reducing layer 200, includes a buffer material for reducing floor impact sound, and segment elements 310 in each segment segmented by segment elements 310. ) and / or between the segmental body 310 and the wall 10.

11 is a view showing the appearance of the second impact sound reducing layer 210 according to the present invention and the segmental body 310 according to another embodiment of the present invention.

Meanwhile, referring to FIG. 11 , the second impact sound reduction layer 210 may include a plurality of different second impact sound reduction layers 211 to 214 . As described above, the second impact sound reduction layer 210 can use any one that has insulation-buffering and soundproofing functions and is intended to block, suppress, and reduce impact energy. As reducing materials, in general, glass fiber (rock wool plate-like structure, glass wool, rock wool), synthetic rubber, scrap tire pulverized chips, cross-linked 5-40 times foamed PE sheet, moisture-proof and waterproof coated glass wool, moisture-proof and waterproof coated rock wool, moisture-proof and waterproof coating a buffer material selected from the group consisting of a PET fiber sheet, an EVA foam panel, an EPS panel, a urethane panel, a binder-coated waste tire chip, an anti-vibration rubber, an asphalt-coated sheet, and a polymer foam. That is, the second impact sound reducing layer 210 may include a plurality of layers including any one of the above-described cushioning materials.

The second impact sound reduction layer 210 includes a plurality of second impact sound reduction layers 211 to 214 including different cushioning materials, and each second impact sound reduction layer 211 to 214, as described above, It is installed between the segments 310 and/or between the wall 10 and the segments 310. Therefore, the edge of each of the second impact sound reducing layers 211 to 214 is installed to be in contact with the inclined surface of the segment 310 according to another embodiment. Therefore, the inclined surface of the segmental body 310 can distribute the load according to the plurality of second impact sound reducing layers 211 to 214 including different cushioning materials, which can occur by placing the finishing mortar 320. It is possible to solve the problem that the fixing part of 310 is damaged.

12 is a cross-sectional structure view between floors of a building in which a building floor structure including a segment 310 for buffering inter-floor noise and impact sound according to another embodiment of the present invention is constructed.

Referring to FIG. 12, the building floor structure according to the present invention further reduces the impact sound transmitted to the slab layer 100 between the upper part of the concrete slab layer 100 and the lower part of the first impact sound reducing layer 200 A third impact sound reducing layer 230 may be further included. The third impact sound reduction layer 230 further reduces impact sound transmitted to the slab layer 100 by including a coil mat and/or a sound absorbing material shown in FIG. 3 below. That is, in the building floor structure according to an embodiment, the third impact sound reduction layer 230 is constructed on the concrete slab layer 100, and the first impact sound reduction layer ( 200) is installed, the segmental body 310 is installed on the first impact sound reduction layer 200, and the finishing mortar 320 is poured in each of the plurality of segments segmented as the segmental body 310 is installed. A finishing mortar layer 300 is formed.

<Figure 3>

13 is a cross-sectional structure view between floors of a building in which a building floor structure including a segment 310 for buffering inter-floor noise and impact sound according to another embodiment of the present invention is constructed.

In addition, in the building floor structure according to the present invention, referring to FIG. 13 , the first impact sound reduction layer 200 and the segment 310 may be installed together on top of the third impact sound reduction layer 230 . At this time, the lower part of the segmented element 310 may be placed at the same position as the first impact sound reducing layer 200, and the upper part of the segmented element 310 may be placed at the same position as the finishing mortar 210.

14 is a view showing an embodiment of a segment 310 constructed together with the impact sound reducing layer 200 according to the present invention.

13, when the first impact sound reduction layer 200 and the segment 310 are constructed together, the fixing members 311 and 313 of the segment 310 are entirely made of EPS, and the finishing mortar layer In addition to reducing the impact sound transmitted from the first impact sound reduction layer 200 , the impact sound transmitted from the first impact sound reduction layer 200 may also be reduced.

In this specification, a "unit" includes a unit realized by hardware, a unit realized by software, and a unit realized using both. Further, one unit may be realized using two or more hardware, and two or more units may be realized by one hardware.

The protection scope of the present invention is not limited to the description and expression of the embodiments explicitly described above. In addition, it is added once again that the scope of protection of the present invention cannot be limited due to obvious changes or substitutions in the technical field to which the present invention belongs.

10: wall
100: slab layer
200: first impact sound reduction layer
210: second impact sound reduction layer
220: side buffer
230: third impact sound reduction layer
300: finishing mortar layer
310: segmental body
310a: transverse segmental body
310b: vertical segment
311: fixing member
313: fixing member
315: sound insulation member
317: honeycomb structure
318: honeycomb cell
320: finishing mortar

Claims (5)

In the building floor structure including the segment 310 for interfloor noise and impact sound buffering,
The floor structure,
A concrete slab layer 100 connected to the wall 10 of the building;
An impact sound reduction layer 200 installed on top of the concrete slab layer 100 and including a buffer material for reducing floor impact sound; and
A finishing mortar layer (300) poured on top of the impact sound reduction layer (200);
Including,
The finishing mortar layer 300,
segmentation elements 310 that segment the upper surface of the impact sound reduction layer 200 into a plurality of regions; and
Finishing mortar 320, which is poured into each of the plurality of zones segmented by the segmental body 310;
including,
The segmental body 310 includes a sound insulation member 315 that blocks impact sound,
The sound insulation member 315 reduces the impact sound in the horizontal direction by preventing the impact sound generated on the finishing mortar 320 poured in each of the plurality of zones from being transmitted to other adjacent zones,
The floor structure,
It is formed between the concrete slab layer 100 and the impact sound reduction layer 200, and further includes an impact sound reduction layer 230 made of a coil mat or sound absorbing material,
The impact sound reduction layer 230 reduces the impact sound in the vertical direction by preventing the impact sound generated on the finishing mortar 320 poured in each of the plurality of zones from being transmitted to the concrete slab layer 100,
The segmental body 310,
A pair of fixing members 311 and 313 formed to be symmetrical to each other and spaced apart from each other by a predetermined distance and installed on the impact sound reducing layer 200; and
a sound insulation member 315 installed between the pair of fixing members 311 and 313 to block impact sound;
Including, the impact sound generated from the finishing mortar 320 cast in any one of the plurality of zones is not transferred to the finishing mortar 320 cast in another adjacent zone,
The segmental body 310,
A honeycomb structure 317 formed around the outer circumferential surface of the sound insulating member 315 is further included,
The honeycomb structure 317,
Including a plurality of hexagonal column-shaped honeycomb cells 318 made of silicon rubber material and having a space therein,
The honeycomb structure 317 absorbs the impact sound generated from the finishing mortar 320 poured in one of the plurality of zones and does not further transmit it to the finishing mortar 320 poured in the other adjacent zone. A building floor structure comprising a segmented body for buffering inter-floor noise and impact sound. delete delete delete It is installed on the upper surface of the impact sound reducing layer 200, and the upper surface of the impact sound reducing layer 200 is segmented into a plurality of zones, so that the finishing mortar 320 is poured into each of the plurality of zones, inter-layer noise and impact sound buffering. In the segment 310 for
The segmental body 310,
A pair of fixing members 311 and 313 formed to be symmetrical to each other and spaced apart from each other by a predetermined distance and installed on the impact sound reducing layer 200; and
a sound insulation member 315 installed between the pair of fixing members 311 and 313 to block impact sound;
Including, the impact sound generated from the finishing mortar 320 cast in any one of the plurality of zones is not transferred to the finishing mortar 320 cast in another adjacent zone,
The segmental body 310,
A honeycomb structure 317 formed around the outer circumferential surface of the sound insulating member 315 is further included,
The honeycomb structure 317,
Including a plurality of hexagonal column-shaped honeycomb cells 318 made of silicon rubber material and having a space therein,
The honeycomb structure 317 absorbs impact sound generated from the finishing mortar 320 cast in one of the plurality of zones and does not further transmit it to the finishing mortar 320 cast in another adjacent zone. segmental element for buffering inter-floor noise and impact sound.

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