JP2011106088A - Vibration-proof material with vault with outer periphery fixed, and vibration-proof method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a vibration-proof material with a vault which has an outer periphery fixed for properly maintaining load resistance and a feeling of walking by solving problems of an impact sound and a living sound on a floor, and to provide a vibration-proof method. <P>SOLUTION: While a floor-post-footing molding form 13 having a groove recess 3 with a diameter of 60 mmΦ is used as a fixing base material, the vibration-proof material 1 with the vault is placed thereon and the outer periphery of the vibration-proof material 1 is fixed to the floor-post-footing molding form 13 with a screw 17 using a fixing washer 16. Furthermore, mortar 15 is infilled and solidified in the floor-post-footing molding form 13 so as to constitute a floor post footing 2 for the vibration-proof material with the vault, and the plurality of floor post footings 2 are installed and fixed on the foundation such as the ground, a concrete slab or the like by means of the mortar 15. A turnbuckle 11 and a floor-retainer-fixing bracket 12 are used for waking the floor post footing 2 into the adjustable floor post. The floor retainer 6 is fixed to the floor-retainer-fixing bracket 12 by means of the screw 17, and floor joist assembling is performed by using a floor joist 7 to be finished by a floor board 8, so that the inexpensive and easily-adjustable vibration-proof material can be constructed. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

The present invention relates to a vaulted vibration isolator having a fixed outer periphery and a vibration isolating method.

Currently, sound insulation measures using a vibration-proof hanging tree or a sound-insulating sheet for the hanging tree that supports the ceiling below the floor are taken to block the sound of living on the floor directly above the wooden house. In addition, double floors are rapidly spreading in apartment buildings and the like because underfloor piping is possible and workability is good. This double floor is composed of, for example, a floor base that protrudes from a plurality of locations on the lower surface of a plate-like material or joist, and this support leg is placed on a floor base such as a concrete slab. It is constructed by laying so as to be adjacent to each other. And in the double floor of such a structure, the vibration insulation rubber etc. are provided in the lower end of the support leg, and the soundproofing property with respect to a floor impact is ensured.

However, the above-mentioned soundproofing measures in wooden houses and soundproofing measures such as vibration-proof rubber in collective housings are not sufficient, and the workability is poor and it is difficult to completely fix the concrete slab to the floor base. .

On the other hand, a floor vibration isolator in which a cylindrical sealed space is formed inside an elastic body interposed between a floor base material made of plate-like material, joists or support legs and a floor base such as a concrete slab ( However, it is difficult to completely fix the concrete slab or the like to the floor base.

In addition, as a well-known technique relevant to this invention, the soundproof double floor provided with the floor vibration isolator and the floor vibration isolator (refer patent document 1) can be mentioned.

Patent Publication 2000-160819

The above-described conventional technology has the following problems in the sound insulation and sound insulation measures on the floor directly above.
Anti-vibration connection between beams and flooring of wooden houses is difficult.
A vibration-proof device between a beam and a floor in a wooden house is expensive.
Costs are required to cut off the sound of living on the floor directly above and to prevent noise.
A complete anti-vibration connection between the stone block and the bundle is difficult.

The present invention has been invented in view of the above-mentioned conventional problems, and can easily and inexpensively eliminate floor impact sounds and living sounds on the upper floor, and can withstand heavy loads such as bookshelves and pianos and walking. A vibration isolator with a vault with a fixed outer periphery that can maintain a good feeling and a vibration isolating method are provided.

The present invention has been made in order to solve the above-mentioned problems, and is a vehicular vibration isolator with a fixed outer periphery and a vibration isolating method according to claim 1, including a beam member, a large pull member, a boulder stone, etc. A fixed base made of a groove is provided with a groove recess, a vaulted anti-vibration material is placed on the groove recess, and the outer periphery of the vault with anti-vibration is fixed to the fixed base. The present invention provides a vibration isolating material with a vault with a fixed outer periphery and a vibration isolating method characterized by enhancing a sound insulation effect.

A plurality of groove recesses are provided in the fixed base material made of the beam material, the large pulling material, or the like according to claim 2, and a vibration isolator with a vault is placed on the plurality of groove recesses so that the outer periphery of the vibration isolator with a vault 2. The anti-vibration material with a vault with a fixed outer periphery according to claim 1, wherein the anti-vibration / sound-proofing effect of the floor interposing a floor receiving material comprising a plurality of anti-vibration materials with a vault fixed to a fixed base material is enhanced. And provide anti-vibration method.

A long nut and a floor receiving material fixing hardware are used for the vibration isolator with a vault according to claim 3, and fine adjustment between the fixed base material and the floor receiving material according to claim 1 and 2 is enabled. The anti-vibration material with the vault | fixing which fixed the outer periphery of Claim 1, 2 and the anti-vibration construction method are provided.

A turn buckle and a floor receiving material fixing hardware are used for the vault vibration isolator according to claim 4, and adjustment between the fixed base material and the floor receiving material according to claim 1 and 2 is enabled. An anti-vibration material with a vault and an anti-vibration construction method with the outer periphery fixed according to claim 1 to 3 are provided.

A boulder molding mold according to claim 5 is used as a fixed base material, and a vault vibration isolator is mounted on the boulder molding mold, and the outer periphery of the vault antivibration material is fixed to the boulder molding mold. The anti-vibration material with a vault with a fixed outer periphery and a vibration-proof construction method according to claim 1, wherein concrete or mortar is filled and solidified in a frame to form a anti-vibration material bundle with a vault.

The most notable effect of the present invention is that the waste tire, which is a negative legacy of the automobile society that continues to be discharged as industrial waste today, can be effectively used in the vibration isolator with the vault of the present invention. The effect that can be effectively used for long-term excellent houses with long service life that can continue to be built in the future is great. On the other hand, the effective use of industrial waste tires also contributes greatly to the prevention of global warming.

According to the first aspect of the present invention, a groove base is provided in a fixed base material made of a beam material, a large pulling material, or a boulder, and the vibration isolator with a vault is placed on the groove concave portion. By fixing the outer periphery to the fixed base material, all the load applied to the vault is received by the vibration isolating material, and there is an effect of inexpensively and easily enhancing the vibration proofing / sound proofing effect of the floor.

According to the second aspect of the present invention, a plurality of groove recesses are provided in the fixed base material made of the beam material, the large pulling material, and the like, and a vibration isolator with a vault is placed on the plurality of groove recesses to provide vibration isolation with the vault. By fixing the outer periphery of the material to a fixed base material and distributing the load to a plurality of vibration-proof materials with vaults, the vibration-proof / sound-proof effect of the floor can be further enhanced.

According to the invention which concerns on Claim 3, there exists an effect which enables the fine adjustment between a fixed base material and a floor receiving material by using a long nut and a floor receiving material fixed metal fitting for the said vibration isolator with a vault.

According to the invention which concerns on Claim 4, there exists an effect which enables adjustment between a fixed base material and a floor receiving material by using a turnbuckle and a floor receiving material fixed metal fitting for the said vibration isolator with a vault.

According to the invention according to claim 4, the outer periphery of the anti-vibration material with the vault is fixed to the anti-vibration molding frame with the anti-vibration material with the vault as the fixed base material, the anti-vibration molding frame provided with the groove recess, The concrete or mortar can be filled on site by filling and solidifying concrete or mortar into a boulder molding mold to make a vault anti-vibration material boulder, and the boulder molding mold can be easily cut and used. You can also.

In addition, the anti-vibration material of the anti-vibration material with vault according to the present invention is suitable for the global warming era because the waste tire, which is a negative legacy of today's automobile society, is optimal in terms of service life and strength. It is possible to reuse waste tires that are friendly to the global environment, and there is an effect of contributing to society through the effective use of industrial waste.

At present, the law concerning the promotion of long-term high-quality homes (200-year homes) that can be used by multiple generations has been enacted, and the time has come to spread long-term high-quality homes with a long service life. The floor of this house, the anti-vibration material that supports the floor, and the anti-vibration method are required to have a long service life. Considering the length of its service life, it is appropriate to reuse waste tires.

As mentioned above, although the effect of this invention was demonstrated, although reuse of a waste tire was emphasized in description, discharge | emission of industrial waste cannot be stopped in today's human society. It is important how effectively the industrial waste can be used, and the fact that waste tires can be reused for the vault antivibration material of the present invention is a great achievement and a great effect. However, the reuse of waste tires is just one proposal.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

1 to 13 relate to an embodiment of the present invention, FIG. 1 is a detailed view of a vibration isolator with a vault, FIG. 2 is a sectional view of the vibration isolator with a vault used for a wooden beam, and FIG. FIG. 4 is a cross-sectional view of a finely adjustable floor bundle vibration isolation method, FIG. 5 is a side view of a finely adjustable floor bundle vibration isolation method, and FIG. 6 is an adjustable floor. FIG. 7 is a side view of an adjustable floor bundle vibration isolation method, FIG. 8 is a cross sectional view of a floor bundle vibration isolation method capable of fine adjustment used for a driving form, and FIG. It is a side view of the floor bundle vibration isolating method which can be finely adjusted used for the formwork.

Referring to the drawings of the present invention, FIG. 1 shows a configuration of a vibration isolator 1 with a vault, and a vibration isolator 9 of about 100 mm square having a plurality of holes 20 and a vault on the vibration isolator 9. FIG. 2 is a detailed view showing the vault antivibration material 1 with 18 attached thereto, and a detailed view showing a fixed washer 16 for firmly attaching and fixing the base material such as the beam material 4 or the boulder molding mold 13. The fixed washer 16 is processed so that a hole 20 of about 60 mm and a plurality of holes 20 for enhancing the vibration isolating effect can be formed in the center and fixed with screws 17.

FIG. 2 shows the vault anti-vibration material 1 shown in FIG. 1 provided with a groove recess 3 on the beam 4 and the vault anti-vibration material 1 on the groove recess 3 using a fixed washer 16 and a screw 17. The floor support material 6 is inserted into the vault 18 of the vibration isolator 1 with a vault and is fastened and fixed with a nut 19. 7 is a cross-sectional view of a vibration isolating method in which seven joists are assembled on the floor support material 6 and finished with a floor plate 8. FIG.

FIG. 3 is a side view of the vibration isolation method shown in FIG.

FIG. 4 shows that the anti-vibration material 1 with the vault is mounted on the boulder molding mold 13 provided with the groove recess 3 and the outer periphery of the anti-vibration material 1 with the vault is attached to the boulder molding mold 13 with the fixed washer 16. And fixed with screws 17, mortar 15 is filled and solidified in a boulder molding mold 13 to form a vibration isolator bundling stone 2 with a vault, and fine adjustment is performed using a long nut 10 and a floor support material fixing hardware 12. The anti-vibration material bundling stone 2 with the vault is finished with the concrete 14 by using the mortar 15 between the vaults and the concrete 2 with the vault. The floor assembly is a cross-sectional view in which the floor support material 6 is fixed to the floor support material fixing hardware 12 with screws 17, the joists are assembled with joists 7 and finished with the floor plate 8.

FIG. 5 is a side view of the vibration isolation method shown in FIG.

FIG. 6 shows that the anti-vibration material 1 with the vault is mounted on the boulder molding mold 13 provided with the groove recess 3 and the outer periphery of the anti-vibration material 1 with the vault is attached to the boulder molding mold 13 with the fixed washer 16. And fixed with screws 17, mortar 15 is filled and solidified in boulder molding mold 13 to form anti-vibration material bundling stone 2 with vault, and adjustment is made using turnbuckle 11 and floor support material fixing hardware 12. For the anti-vibration material bundling stone 2 with a vault, the anti-vibration material bundling stone 2 with the vault is finished with a concrete 14 using a mortar 15 between the soils. The floor assembly is a cross-sectional view in which the floor support material 6 is fixed to the floor support material fixing hardware 12 with screws 17, the joists are assembled with joists 7 and finished with the floor plate 8.

FIG. 7 is a side view of the vibration isolation method shown in FIG.

FIG. 8 shows that the anti-vibration material 1 with the vault is mounted on the boulder molding mold 13 provided with the groove recess 3 and the outer periphery of the anti-vibration material 1 with the vault is attached to the boulder molding mold 13 with the fixed washer 16. And fixed with screws 17, mortar 15 is filled and solidified in a boulder molding mold 13 to form a vibration isolator bundling stone 2 with a vault, and fine adjustment is performed using a long nut 10 and a floor support material fixing hardware 12. For the anti-vibration material bundling stone 2 with vaults, a stationary concrete 14 is placed on the decorative casting form 21 to finish the slab. The floor assembly is a cross-sectional view in which the floor receiving material 6 is fixed to the floor receiving material fixing hardware 12 with screws 17 and directly finished with the floor plate 8.

FIG. 9 is a side view of the vibration isolation method shown in FIG.

Example 1 An example will be described with respect to a vibration isolation method for a two-story floor structure of a wooden house. As shown in FIG. 2, groove recesses 3 of 60 mmΦ are provided on the beam of the beam material 4 at intervals of 900 mm, and a plurality of holes 20 shown in FIG. The anti-vibration material 1 with the vault 18 attached to the anti-vibration material 9 is firmly attached and fixed using the fixed washer 16 and the screw 17 and the floor support material 6 is inserted into the vault 18 of the anti-vibration material 1 with the vault. An anti-vibration floor can be constructed easily and inexpensively by assembling the joists 7 on the floor receiving material 6 that is fastened and fixed by the nut 19 and finishing it with the floor plate 8.

Example 2 An example will be described regarding a vibration isolation method for a floor structure based on ground, concrete slab, or the like. As shown in FIG. 4, a boulder molding mold 13 provided with a groove recess 3 of 60 mmΦ is used as a fixed base, and the anti-vibration material 1 with a vault is placed on the outer periphery of the anti-vibration material 1 with a vault. It is fixed with screws 17 using a fixed washer 16, and a mortar 15 is filled and solidified in a boulder molding mold 13 to form a vibration isolator with vault 2, and the mortar 15 is placed on a foundation such as the ground or a concrete slab. A plurality of anti-vibration material bundling stones 2 with a vault are fixed and fixed. The vault anti-vibration material bundling stone 2 is a floor bundle that can be finely adjusted by using a long nut 10 and a floor receiving material fixing metal 12, and the floor receiving material 6 is fixed to the floor receiving material fixing metal 12 with screws 17. By building a joist with the joists 7 and finishing with the floor board 8, an anti-vibration floor that can be finely adjusted easily at low cost can be constructed.

Example 3 An example of the vibration isolating method for a high-floor structure based on the ground, a concrete slab, or the like will be described. As shown in FIG. 6, a boulder molding mold 13 provided with a groove recess 3 of 60 mmΦ is used as a fixed base, and the anti-vibration material 1 with a vault is placed on the outer periphery of the anti-vibration material 1 with a vault. It is fixed with screws 17 using a fixed washer 16, and a mortar 15 is filled and solidified in a boulder molding mold 13 to form a vibration isolator with vault 2, and the mortar 15 is placed on a foundation such as the ground or a concrete slab. A plurality of anti-vibration material bundling stones 2 with a vault are fixed and fixed. A floor bundle that can be adjusted using the turn buckle 11 and the floor support material fixing hardware 12 is attached to the vibration isolating material bundle stone 2 with the vault, and the floor support material 6 is fixed to the floor support material fixing hardware 12 with screws 17. An anti-vibration floor that can be adjusted inexpensively and easily can be constructed by building a joist with the joists 7 and finishing with the floor board 8.

Example 4 An example will be described with respect to a vibration isolation method for a floor structure based on a reinforced concrete cast-in formwork. As shown in FIG. 8, a boulder molding mold 13 provided with a groove recess 3 of 60 mmΦ is used as a fixed base, and the anti-vibration material 1 with a vault is placed on the outer periphery of the anti-vibration material 1 with a vault. A fixed washer 16 is used to fix with a screw 17, and a mortar 15 is filled and solidified in a boulder molding mold 13 to form a vault anti-vibration material boulder 2 with a plurality of vaults on the base of the driving mold A floor bundle that can be fine-adjusted using a long nut 10 and a floor support material fixing hardware 12 to the vibration-proof material bundle 2 with a vault fixed by placing and solidifying the vibration-proof material bundle 2 and placing the concrete 14 by casting solidification, By fixing the floor receiving material 6 to the floor receiving material fixing metal 12 with screws 17 and finishing with the floor plate 8, a vibration-proof floor that can be finely adjusted easily at low cost can be constructed.

The above-mentioned anti-vibration material 9 is a negative legacy of the automobile society, and from the meaning of constructing a system that can continue to effectively use the waste tire 22 that is industrial waste that can continue to be discharged even in the electric car society, It is desirable to effectively use the waste tire 22 as the vibration isolator 9. For example, if four waste tires 22 discharged by a general ordinary car are cut into 100 mm squares, 85 to 170 vibration-proof materials 9 can be taken. This is the vibration isolator 9 that can be consumed by one or two ordinary houses, and a structure that allows the waste tires 22 to be used effectively can be constructed. In addition, if the waste tire 22 can be effectively used in a vibration-proofing method that eliminates the sound of living in a house, social contribution can be made through industrial waste treatment.

As mentioned above, although embodiment and the Example of this invention were described, the scope of the present invention is not limited to this. For example, the reuse of waste tires has been emphasized for the vibration isolator, but the material and dimensions are not limited, and are appropriately selected such as changing according to the purpose of use.

While industrial waste treatment is regarded as a problem, the waste tire 22, which is a negative legacy of the automobile society, can be used as a vibration isolator 9 in the housing industry. The market of the housing industry is huge, and the demand for inexpensive anti-vibration materials 9 is great.

Detailed view of the anti-vibration material with vault Cross section of a vaulted anti-vibration material used for wooden beams Side view of anti-vibration material with vault used for wooden beams Cross section of finely adjustable floor bundle vibration isolation method Side view of finely adjustable floor bundle vibration isolation method Cross section of adjustable floor bundle vibration isolation method Side view of adjustable floor bundle anti-vibration method Cross-sectional view of floor bunch vibration isolation method that can be fine-tuned used for driving formwork Side view of the floor bundle anti-vibration method that can be fine-adjusted for the driving form.

Anti-vibration material with vault Anti-vibration material with vault Stone groove Recessed beam material Flooring material joist floor plate Anti-vibration material Long nut Turnbuckle Floor receiving material Fixed hardware Bundle stone Forming mold Concrete mortar Fixed washer Screw vault Nut hole makeup Drive-in formwork scrap tires

Claims (5)

A vibration isolator with a vault with a fixed outer periphery and a vibration isolating method,
A groove base is provided in a fixed base material such as a beam, large pulling material or boulder, and a vibration isolator with a vault is placed on the groove concave part to fix the outer periphery of the anti-vibration material with a vault to the fixed base. An anti-vibration material with a vault with a fixed outer periphery and an anti-vibration method characterized by enhancing the anti-vibration and sound-proofing effect of the floor with the receiving material interposed. A plurality of groove recesses are provided in the fixed base material made of the beam material, the large pulling material, etc., and a vibration isolating material with a vault is placed on the plurality of groove recesses, and the outer periphery of the vibration isolating material with a vault is fixed to the fixing base material. 2. The anti-vibration material with a vault with a fixed outer periphery and the anti-vibration method according to claim 1, wherein the anti-vibration / sound-proofing effect of the floor through a floor receiving material comprising a plurality of anti-vibration materials with a vault is interposed. A fine adjustment between the fixed base material and the floor support material according to claims 1 and 2 is made possible by using a long nut and a floor support material fixing hardware for the vibration isolator with vault. 2. Anti-vibration material with vault and anti-vibration method with the outer periphery fixed. The adjustment between the fixed base material and the floor support material according to claims 1 and 2 is made possible by using a turnbuckle and a floor support material fixing hardware for the vibration isolator with vault. Anti-vibration material with vault and anti-vibration construction method with fixed outer periphery. The anti-vibration material with vault is mounted on the boulder molding formwork provided with the groove recess, and the outer periphery of the anti-vibration material with vault is fixed to the boulder molding formwork, and concrete or mortar is placed in the boulder molding formwork. The anti-vibration material with a vault with a fixed outer periphery and the anti-vibration method according to claim 1, wherein the anti-vibration material bundle with a vault is solidified.

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