JP2008266942A - Sound insulation floor structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a sound insulation floor structure capable of preventing finish flooring from being raised while enhancing floor impact sound insulation characteristics. <P>SOLUTION: This sound insulation floor structure includes a plurality of floor supporting units 3 disposed on a foundation flooring 2, floor underlayer panels 4 supported on the foundation flooring 2 at a predetermined height level by the floor supporting units 3, and the finish flooring 6 laid down on the floor underlayer panels 4. Gypsum boards 5 having a specific gravity of 0.9-1.4 are laid down between the floor underlayer panels 4 and the finish flooring 6. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a sound-insulating floor structure, and more particularly, to a sound-insulating floor structure by a dry flooring method in which a double floor is constructed by forming a space with an existing foundation surface in various buildings such as apartment buildings.

The floor base material is supported at a predetermined height level by the supporting leg group erected on the foundation surface via the elastic pedestal to form a double floor floor base, and the floor is disposed on the floor via the scraping material. Floor structures laid with finishing materials are called dry double floor structures, and are often used in housing complexes and physical education facilities.
In such a dry double floor structure, a floor surface with good walking feeling and motion feeling can be obtained by the action of the elastic pedestal arranged at the lower end of the support leg, and it acts on the floor surface by the elasticity of the elastic pedestal. Shock is buffered.

However, in recent years, propagation of indoor noise, particularly floor impact sound, has become a major problem. Here, the floor impact sound does not propagate only through the support legs, but also propagates through the space and walls under the floor. Accordingly, in the dry double floor structure, it is difficult to obtain sufficient sound insulation only by the elastic pedestal disposed at the lower end of the support leg.
Therefore, the present applicant has a bending strength of 35 to 50 (N / mm 2), a bending Young's modulus of 4,000 to 5,000 (N / mm 2), and a density of 0. 0 between the floor base material and the floor finishing material. A sound insulating floor structure in which 8 to 1.2 (g / cm 3) hardboard or high-density fiberboard is laid has been developed (see Patent Document 1).

And according to the sound insulation floor structure concerning patent documents 1, even when it is a case where hard flooring materials, such as wooden flooring which a floor impact sound is easy to propagate, are used, a walk feeling, durability, and a floor It becomes possible to construct a dry type sound insulation double floor having excellent impact sound insulation performance.
Japanese Patent No. 3588097

However, the sound insulating floor structure according to Patent Document 1 employs a configuration in which a hard board or a high-density fiber board is laid between the floor base material and the floor finishing material. Here, the hardboard and the high-density fiberboard are formed by adding some chemicals such as resin and paraffin to plant fibers such as pulp and kenaf. Therefore, the hard board or the high-density fiber board expands and contracts according to the humidity in the air by the vegetable fibers absorbing or releasing the moisture in the air. Therefore, in the sound-insulating floor structure according to Patent Document 1, there is a problem that the floor finish may be lifted or the like due to expansion or contraction of the hard board or the high-density fiberboard.
The present invention has been made in order to solve the above-described problems of the prior art, and the object thereof is to improve the floor impact sound isolation characteristics while preventing the floor finishing material from lifting and the like. To provide a structure.

The sound-insulating floor structure according to claim 1 includes a plurality of floor support units disposed on a foundation surface, and an underfloor supported at a predetermined height level with respect to the foundation surface by the plurality of floor support units. A sound insulating floor structure comprising a ground material and a floor finishing material laid on the floor base material,
A gypsum board having a specific gravity of 0.9 to 1.4 is laid between the floor base material and the floor finishing material.
The sound insulating floor structure according to claim 2 of the present application is the sound insulating floor structure according to claim 1, wherein each of the floor support units is provided on an elastic pedestal disposed on the foundation surface, and stands on the elastic pedestal. And a support plate that is supported by the support leg and supports the floor base material.

  According to the sound-insulating floor structure according to claim 1 or 2 of the present application, the floor impact sound is blocked by a construction in which a gypsum board having a specific gravity of 0.9 to 1.4 is laid between the floor base material and the floor finishing material. It is possible to prevent the floor finish from being lifted while improving the characteristics.

Hereinafter, a sound insulating floor structure according to an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a perspective view of a sound insulating floor structure according to an embodiment of the present invention. FIG. 2 is a side sectional view of the floor support unit provided in the sound insulating floor structure shown in FIG. 1. FIG. 3 is a plan view of an elastic pedestal disposed in the floor support unit shown in FIG. FIG. 4 is a bottom view of the elastic pedestal shown in FIG. FIG. 5 is a schematic partial plan view showing an example of an arrangement form of the floor base material laid by using the floor support unit shown in FIG. 2.

As shown in FIG. 1, the sound insulating floor structure 1 is installed in various buildings such as an apartment house, and has a plurality of floor support units 3 disposed on a floor surface of a foundation surface 2 such as a concrete slab, and a floor support A floor base material 4 supported by the unit 3, a gypsum board 5 laid on the floor base material 4, and a floor finishing material 6 laid on the gypsum board 5 are provided.
As shown in FIG. 2, each floor support unit 3 includes an elastic pedestal 8 disposed on the base surface 2, a support leg 9 erected on the elastic pedestal 8, and a support plate supported by the support leg 9. 10.

  The elastic pedestal 8 is formed in a substantially cylindrical shape from an elastic material such as rubber. A central hole portion 11 is formed in the central portion of the substantially upper half portion of the elastic pedestal 8 as viewed from the vertical direction. An annular groove-like recess 12 is formed below the inner peripheral surface of the central hole 11 to accommodate a protrusion 20 of a hollow support bolt 18 described later. Further, as shown in FIGS. 2 and 3, a cross-shaped groove portion 14 extending from the bottom surface 13 of the central hole portion 11 toward the upper side of the inner peripheral surface is formed on the inner surface of the central hole portion 11. On the lower surface of the elastic pedestal 8, as shown in FIG. 4, a plurality of (four in the illustrated example) groove portions 16 having a substantially U-shaped cross section by ribs 17 extend outward from the center. It is formed radially. Further, as shown in FIGS. 2 and 4, the elastic pedestal 8 is formed with a pair of communication holes 23 that communicate with the groove 14 of the central hole 11 and the groove 16 on the lower surface of the elastic pedestal 8 substantially vertically. ing. In the present embodiment, two communication holes 23 are formed, but three or four or more may be provided corresponding to the groove portion 14, and depending on the fluidity of the adhesive used, etc. However, only one may be provided. Further, four substantially hemispherical protrusions 15 are formed symmetrically on the lower surface of the elastic base 8. The elastic pedestal 8 has a ground contact area with the base surface 2 by forming the protrusions 15 and can obtain appropriate elasticity (sinking) while dispersing the received load. The impact sound can be reduced. Here, the height of each projection 15 is preferably about 2 to 4 mm, and all the projections 15 are preferably the same height. The elastic pedestal 8 is fixed and installed on the base surface 2 by bonding or the like at a predetermined interval.

The support leg 9 includes a hollow support bolt 18 erected on the elastic base 8 so as to be rotatable, and a level adjusting nut 19 into which an upper end portion of the hollow support bolt 18 is screwed.
The hollow support bolt 18 is formed from a relatively short hollow pipe having a central placement hole 26. An annular projecting portion 20 projecting laterally is buckled at the lower end portion of the hollow support bolt 18. A male threaded portion 21 is formed at the upper end of the outer peripheral surface of the center support bolt 18 by a predetermined length from the upper end. On the upper end surface of the hollow support bolt 18, a groove-like engagement portion 22 is formed for engaging the tip of a rotary tool such as a screwdriver or an electric screwdriver.

  The level adjusting nut 19 is formed of a relatively short hollow pipe having a central placement hole into which the hollow support bolt 18 can be screwed. A female screw portion 24 that fits the male screw portion 21 of the hollow support bolt 18 by a predetermined length from the lower end is formed at the lower end portion of the inner peripheral surface of the level adjusting nut 19. In addition, an annular support portion 25 projects from a substantially central portion in the vertical direction of the outer peripheral surface of the level adjusting nut 19.

The support leg 9 is configured by screwing the upper end portion of the male screw portion 21 of the hollow support bolt 18 into the female screw portion 24 of the level adjusting nut 19.
The support plate 10 is formed by forming a particle board, a laminated plywood, a wood fiber board or the like into a substantially rectangular flat plate shape. An insertion hole 27 into which the upper portion of the level adjusting nut 19 is fitted is provided in a substantially central portion of the support plate 10 as viewed from the vertical direction. A chamfered portion 28 that is chamfered and expanded upward is formed at the upper end of the insertion hole 27.

  The elastic base 8 and the support leg 9 are combined by fitting the lower end of the hollow support bolt 18 of the support leg 9 into the central hole 11 of the elastic base 8. In this case, the protrusion 20 of the hollow support bolt 18 is engaged with the recess 12 of the elastic pedestal 8 so that the support leg 9 is rotatably supported by the bottom surface 13 of the central hole 11 of the elastic pedestal 8. It is set up at. Further, the support leg 9 and the support plate 10 are fitted into the insertion hole 27 of the support plate 10 with the upper end of the level adjustment nut 19 of the support leg 9, and the lower surface of the support plate 10 is supported by the level adjustment nut 19. They are combined by being supported by the portion 25. In this case, the upper end portion of the level adjustment nut 19 of the support leg 9 is expanded and partially buried in the chamfered portion 28 of the insertion hole 27 of the support plate 10, so that an adhesive is formed on the upper portion of the level adjustment nut 19. A reservoir 29 is formed.

In the floor support unit 3 configured as described above, the tip of a rotating tool such as a screwdriver is fitted into the engagement portion 22 formed on the upper end surface of the hollow support bolt 18 to rotate the hollow support bolt 18. As a result, the support plate 10 supported by the level adjusting nut 19 is moved in the vertical direction. Thereby, the height level with respect to the base surface 2 of the floor base material 4 supported by the support plate 10 can be adjusted.
As the floor base material 4, particle board, hard board, high density fiber board, plywood or the like is used. The floor base material 4 is fixed to the upper surface of the support plate 10 of the floor support unit 3 with an adhesive, a nail or the like, and is supported at a predetermined height level with respect to the base surface 2.

As the gypsum board 5, one formed by coating the outer surface of the core material formed into a plate shape with gypsum with a paper material is used. Here, the gypsum board 5 is formed to have a specific gravity of 0.9 to 1.4. Here, when the specific gravity of the gypsum board 5 is set to less than 0.9, there arises a disadvantage that sufficient sound insulation performance cannot be obtained. Moreover, when the specific gravity of the gypsum board 5 is set to be larger than 1.4, cutting and fastening become difficult. In particular, the specific gravity of the gypsum board 5 is preferably set to 1.0 to 1.3. The gypsum board 5 is cut into a predetermined size by a cutter, or is laid on the floor base material 4 in a fixed size, and then fastened to the floor base material 4 with nails.
As the floor finish 6, flooring, a wood-based decorative board, a synthetic resin cushion sheet, a carpet, a carpet, a tatami mat, and the like can be used.

Next, an installation mode example of the sound insulating floor structure 1 will be described.
In installing the sound insulating floor structure 1, first, a plurality of floor support units 3 are installed on the foundation surface 2 at a predetermined pitch corresponding to the shape of the floor base material 4.
Then, the floor base material 4 is installed on the support plate 10 of each floor support unit 3 in a state where the edge of the floor base material 4 is supported by each support plate 10. In this case, the floor base material 4 is installed such that the adhesive reservoir 29 of each level adjusting nut 19 is exposed from the edge of the floor base material 4. Here, it is possible to prepare a floor support unit 3 attached to the lower surface of the floor base material 4 in advance and install it on the base surface 2. The support plate 10 and the floor base material 4 of each floor support unit 3 are fixed using an adhesive sheet or the like.

Then, a rotating tool is inserted from above the adhesive reservoir 29 of the support plate 10 of each floor support unit 3, and the hollow support bolt 18 is rotated via the engaging portion 22, so that the underfloor supported by the support plate 10. The height level of the ground material 4 is adjusted.
Further, adjacent floor base materials 4 are similarly fixed on the floor support unit 3 with a predetermined gap so that the level of the floor base material 4 can be adjusted.
Such an operation is repeated with the floor base material 4 so that the floor base material 4 is laid uniformly on the base surface 2 and the height level of the floor base material 4 with respect to the base surface 2 is adjusted to a predetermined height. To do.

  After the floor surface level of the floor base material 4 is adjusted, an adhesive is injected into the adhesive reservoir 29 exposed in the gap between the adjacent floor base materials 4. In this case, the adhesive injected from the adhesive reservoir 29 formed on the upper part of the level adjusting nut 19 first penetrates into the threaded portion between the level adjusting nut 19 and the hollow support bolt 18. The adjusting nut 19 and the hollow support bolt 18 are bonded. Further, the adhesive injected from the adhesive reservoir 29 penetrates into the gap between the floor base material 4 and the support plate 10, and bonds the floor base material 4 and the support plate 10. Further, the adhesive injected from the adhesive reservoir 29 flows into the central hole 11 of the elastic base 8 from the adhesive reservoir 29 via the central placement hole 26 of the hollow support bolt 18, and the lower end of the hollow support bolt 18. And the elastic base 8 are also bonded. Further, the adhesive injected from the adhesive reservoir 29 flows from the groove portion 14 of the central hole portion 11 into the groove portion 16 on the lower surface of the elastic pedestal 8 through the communication hole 23, and between the elastic pedestal 8 and the base surface 2. Also glue. Therefore, in the sound insulating floor structure 1, adhesion between the level adjusting nut 19 and the hollow support bolt 18, adhesion between the floor base material 4 and the support plate 10, and hollow support by a single adhesive injection operation. Adhesion between the bolt 18 and the elastic pedestal 8 and adhesion between the elastic pedestal 8 and the base surface 2 can be performed at the same time, and the workability of the adhesive injection can be greatly improved.

Then, after the laying of the floor base material 4 on the foundation surface 2 is completed, the gypsum board 5 is uniformly laid on the floor base material 4.
For laying the gypsum board 5 on the floor base material 4, the gypsum board 5 is placed on the floor base material 4 and fastened to the underfloor seat 4 with nails. In this case, since the gypsum board 5 can be cut by a cutter, the size can be easily finely adjusted on site.
Then, after the laying of the gypsum board 5 on the floor base material 4 is completed, the floor finishing material 6 is laid uniformly on the gypsum board 5 to complete the installation of the sound insulating floor structure 1.

  In the sound insulating floor structure 1, the gypsum board 5 also functions as a scraping material in the conventional double floor structure, and therefore no laying material is required. Further, the floor base material 4 may be arranged in a staggered manner as shown in FIG. 5 or in parallel. Moreover, in the sound insulating floor structure 1, in order to further improve the floor impact sound insulating performance, if necessary, the vibration damping and sound insulating sheet made of a rubber asphalt sheet containing metal powder such as cast iron powder, the surface and / or A sound-absorbing sheet comprising a polyester nonwoven fabric, a synthetic resin film, a sheet having a metal foil attached to the back surface, or a polyester-based, polypropylene-based, pulp-based nonwoven fabric, preferably a polyester nonwoven fabric, particularly a polyester hollow fiber nonwoven fabric. You may arrange | position in the substantially whole area except the support leg installation location under the floor base material 4. FIG. Alternatively, the underfloor space may be configured to be closed in a grid pattern.

  In the sound insulating floor structure 1 having the above configuration, the gypsum board 5 is laid between the floor base material 4 and the floor finishing material 6. Moreover, the gypsum board 5 is formed so that specific gravity may be set to 0.9-1.4. Therefore, according to the sound insulating floor structure 1, it is possible to suppress the propagation of vibration from the floor finishing material 6 to the floor base material 4, and it is possible to improve the floor impact sound blocking performance. Moreover, since the gypsum board 5 does not expand and contract according to the humidity in the air, the sound insulating floor structure 1 can prevent the floor finish 6 from being lifted. Here, a function of absorbing and decomposing formaldehyde can be added to the gypsum board. Therefore, in the sound-insulating floor structure 1, it is possible to absorb and decompose formaldehyde in the installed room by the configuration including the gypsum board 5 to which the formaldehyde absorption and decomposition function is added.

Although the embodiments of the present invention have been described above, various modifications can be made in the embodiments of the present invention.
For example, in this embodiment, the support leg 9 of the floor support unit 3 is configured to include a hollow support bolt 18 having a center placing hole 26 and a level adjusting nut 19. However, instead of the hollow support bolt 18, a solid support bolt that does not have the center placing hole 26 may be used.

Next, a test example of the floor impact sound level for the sound insulating floor structure 1 will be shown to specifically explain the effect of the present invention.
In the following test examples, the measurement method and evaluation of the floor impact sound level were performed in accordance with the provisions of JIS A1418: 2000 (measurement method for floor impact sound insulation performance of buildings).
Measuring method:
FIG. 6 is a schematic configuration diagram of a laboratory for testing a floor impact sound level. FIG. 7 is a diagram showing test results of a floor impact sound level test.
As shown in FIG. 6, an experimental building 110 divided into a sound source room 111 on the upper floor and a sound receiving room 112 on the lower floor by a basic surface 100 made of a concrete slab (RC floor board) having a thickness of 150 mm was used as a laboratory. . In the sound source room 111, a sound insulating floor structure 113 serving as a test body is constructed on the base surface 100, and the measurement target floor 114 is configured from the base surface 100 and the sound insulating floor structure 113.

Two types of floor impact sound generators 115 are used: a lightweight floor impact sound generator (tapping machine) and a heavy floor impact sound generator (bang machine). The sound is collected by the microphone 116 installed in the sound chamber 112 and received by the indication sound level meter 118 of the sound receiving device 117, and is received by the octave analyzer 119 for each frequency band of the 1/1 octave band. Sound pressure level was recorded. The frequency bands are 63 Hz, 125 Hz, 250 Hz, 500 Hz, 1,000 Hz (1 kHz), 2,000 Hz (2 kHz), and 4,000 Hz (4 kHz), and the higher the number, the higher the sound.
The height of the sound receiving chamber microphone was 1200 mm.

Floor impact sound level improvement:
(1) Improvement amount of floor impact sound level in the laboratory First, the floor impact sound generator (light weight, weight) 115 is directly struck on the basic surface 100 of the sound source chamber 111, and the floor impact sound level is set in the sound receiving chamber 112. It was measured.
Next, a double floor 113 having a predetermined size is constructed on the foundation surface 100 of the sound source chamber 111 that has been emptied, and a floor impact sound generator 115 is used to create a floor impact at the same location as the above-mentioned struck impact. A sound was generated and the floor impact sound level was measured in the sound receiving chamber 112. The floor impact sound level was defined as the total average value of values measured by repeatedly hitting three times at three hit points.
From the measured values obtained as described above, the floor impact sound level improvement amount ΔL in the laboratory was calculated by the following formula (1).
ΔL = LO−Ln (dB) (1)
Here, LO is the floor impact sound level (dB) of the foundation surface 100, and Ln is the floor impact sound level (dB) of the foundation surface 100 on which the double floor 113 is constructed.

(2) Estimation of floor impact sound level in the field The amount of improvement is an absolute performance evaluation of the floor structure itself, which is different from the JIS evaluation. Therefore, in order to make an evaluation generally called L value, the floor impact sound level at the site is estimated by the following equation (2).
L = Ls−ΔL (dB) (2)
Here, Ls is the floor impact sound level (dB) of the base surface 100 obtained in the field, and ΔL is the floor impact sound level improvement amount (dB) in the laboratory.
Therefore, this L is the floor impact sound level in the field referred to in JIS, and this value is transcribed in FIG. 2 of JIS A 1419, and the L value according to the JIS standard is estimated.

Specimen:
Specimen A has a sound-insulating floor structure according to a comparative example. YP-90 type support legs (support leg interval 458 mm × 615 mm) as a floor support unit, particle board (1820 mm × 600 mm × 20 mm) as a floor base material, floor A color floor (1818 mm × 303 mm × 12 mm) is applied as a finishing material, and a high-density fiberboard (MDF) (1820 mm × 910 mm × 7 mm) is laid between the floor base material and the floor finishing material.
The test body B is a sound-insulating floor structure according to the example of the present invention. In the configuration of the test body A, a gypsum board (1820 mm × 909 mm × 9.5 mm) is laid instead of the high-density fiberboard.
The test body C is a sound-insulating floor structure according to the example of the present invention. In the configuration of the test body A, a gypsum board (1820 mm × 606 mm × 12.5 mm) is laid instead of the high-density fiberboard.

Test results:
As is clear from the results shown in FIG. 7, the double floor constructed by laying the gypsum board between the floor base material and the floor finish material has a high density between the floor base material and the floor finish material. It has floor impact sound insulation performance equal to or better than a double floor constructed by laying fiberboard.

1 is a perspective view of a sound insulating floor structure according to an embodiment of the present invention. It is side surface sectional drawing of the floor support unit with which the sound-insulating floor structure shown in FIG. 1 is equipped. It is a top view of the elastic pedestal arrange | positioned at the floor support unit shown in FIG. FIG. 4 is a bottom view of the elastic pedestal shown in FIG. 3. FIG. 3 is a schematic partial plan view showing an example of an arrangement form of a floor base material laid using the floor support unit shown in FIG. 2. It is a schematic block diagram of the laboratory which tests a floor impact sound level. It is a figure which shows the test result of the test of a floor impact sound level.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Sound insulation floor structure 2 Base surface 3 Floor support unit 4 Floor base material 5 Gypsum board 6 Floor finishing material 8 Elastic base 9 Support leg 10 Support plate 11 Central hole 12 Recess 13 Bottom surface 14 Groove 15 Projection 16 Groove 17 Rib 18 Hollow Support bolt 19 Nut for level adjustment 20 Protruding part 21 Male thread part 22 Engaging part 23 Communication hole 24 Female thread part 25 Support part 26 Centering hole 27 Insertion hole 28 Chamfered part

Claims (2)

A plurality of floor support units disposed on the base surface, a floor base material supported at a predetermined height level with respect to the base surface by the plurality of floor support units, and laid on the floor base material A sound-insulating floor structure comprising a floor finishing material,
A sound insulating floor structure, wherein a gypsum board having a specific gravity of 0.9 to 1.4 is laid between the floor base material and the floor finishing material.   Each of the floor support units includes an elastic pedestal disposed on the base surface, a support leg standing on the elastic pedestal, and a support plate supported by the support leg and supporting the floor base material. The sound-insulating floor structure according to claim 1, comprising:

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