JP7033400B2 - Floor structure - Google Patents

Description

The present invention relates to a technique for a floor structure including an ALC floor board.

Conventionally, a technique of a floor structure including an ALC floor board has been known. For example, as described in Patent Document 1.

Patent Document 1 discloses a technique for attaching an ALC floor plate (ALC panel) to a floor beam (framework) by disassembling the mounting bracket. Since the mounting bracket can be fastened to the ALC plate only by press-fitting it into the ALC floor plate, the construction time can be shortened.

In such a floor structure, it is conceivable to increase the thickness of the ALC floor board as a method of improving the sound insulation performance. However, if the thickness of the ALC floor plate is simply increased, the upper surface of the ALC floor plate becomes high, and it becomes difficult to form the floor surface at a desired position (height).

Japanese Unexamined Patent Publication No. 2005-248701

The present invention has been made in view of the above situations, and the problem to be solved is that it is possible to easily form a floor surface having a desired height even when the thickness of the ALC floor board is increased. It is to provide a simple floor structure.

The problem to be solved by the present invention is as described above, and next, the means for solving this problem will be described.

That is, in claim 1, the floor beam and the ALC floor plate fixed to the floor beam are provided, the ALC floor plate is provided with a recess formed on the lower surface, and the floor beam is provided in the recess. Further provided with a floor plate fixing member that is fixed to the ALC floor plate, penetrates the ALC floor plate vertically, and sandwiches the ALC floor plate and the floor beam from above and below to fix the ALC floor plate to the floor beam. The lower end of the floor plate fixing member is arranged in the recess, is located above the lower surface of the ALC floor plate, is interposed between the ALC floor plate and the floor beam, and the longitudinal direction is the floor. Further, it is provided with a vibration-proof material arranged along the longitudinal direction of the beam . Further, in claim 2, a cushion material is provided between the lower end portion of the floor plate fixing member and the lower surface of the upper flange of the floor beam.

In claim 3 , at least a part of the surface of the vibration-proof material in contact with the floor beam or the ALC floor plate is coated to reduce friction.

In claim 4 , the recess is formed so as to expand downward.

In claim 5 , a soundproofing material interposed between the ALC floor plate and the floor material, and a ceiling fixing member for fixing the ceiling panel to the floor beam via an elastic member are further provided. Is.

As the effect of the present invention, the following effects are exhibited.

In claim 1, even when the thickness of the ALC floor board is increased, the floor surface having a desired height can be easily formed. Further, in claim 1, the sound insulation performance can be improved. Further, in claim 2, workability at the time of construction can be improved.

In claim 3 , workability at the time of construction can be improved.

In claim 4 , workability at the time of construction can be improved.

In claim 5 , the sound insulation performance can be further improved.

The front sectional view which showed the floor structure which concerns on one Embodiment of this invention. An exploded perspective view showing floor beams and anti-vibration materials.

Hereinafter, the floor structure 1 according to the embodiment of the present invention will be described with reference to FIGS. 1 and 2.

The floor structure 1 mainly includes a floor beam 2, an ALC floor board 3, a vibration-proof material 4, a fixing member 5, a soundproof mat 6, a particle board 7, a floor material 8, a ceiling panel 9, a floor board 10, and a hanging material 11. ..

The floor beam 2 shown in FIGS. 1 and 2 is formed of H-shaped steel including a pair of flanges 2a and a web 2b connecting the flanges 2a to each other. The floor beam 2 is arranged with a pair of flanges 2a facing up and down. The floor beam 2 is arranged so that the longitudinal direction is substantially horizontal (in FIG. 1, the paper surface depth direction).

The ALC floor plate 3 shown in FIG. 1 is a plate-shaped structure for receiving a load. The ALC floor plate 3 is formed of lightweight aerated concrete (ALC: Autoclaved Lightweight aerated Concrete) cured by high temperature and high pressure steam. The ALC floor plate 3 is formed by a relatively high density (high specific gravity) ALC. Specifically, the ALC floor plate 3 of the present embodiment is formed so as to have a specific gravity of 0.65. The ALC floor plate 3 is arranged substantially horizontally and is fixed to the upper part (upper flange 2a) of the floor beam 2 by a fixing member 5 described later. A recess 3a is formed in the ALC floor plate 3.

The recess 3a is a portion formed so that the lower surface of the ALC floor plate 3 is recessed upward. The recess 3a is formed at the outer peripheral end of the lower surface of the ALC floor plate 3. The side surface 3b of the recess 3a is formed in a tapered shape so as to extend downward to the inside of the ALC floor plate 3. As a result, the recess 3a is formed so as to expand downward.

The ALC floor plate 3 (portion other than the recess 3a) of the present embodiment is formed so that the thickness (vertical width) is 150 mm. Further, the ALC floor plate 3 is formed so that the thickness of the recess 3a is 100 mm.

The recess 3a of the ALC floor plate 3 is placed on the flange 2a of the floor beam 2 via the vibration-proof material 4 described later. In the example shown in FIG. 1, two ALC floor plates 3 arranged side by side on the paper surface are mounted on the flange 2a of the floor beam 2, respectively. In this way, the upper portion of the floor beam 2 is located in the recess 3a of the ALC floor plate 3.

The vibration-proof material 4 shown in FIGS. 1 and 2 is provided on the upper surface of the flange 2a of the floor beam 2 and is arranged so as to be sandwiched between the flange 2a and the ALC floor plate 3. The vibration-proof material 4 can suppress the transmission of vibration between the members (in this embodiment, between the ALC floor plate 3 and the floor beam 2). The vibration-proof material 4 is formed of a material having viscoelasticity such as urethane foam or rubber.

The anti-vibration material 4 is formed in the shape of a plate having a substantially rectangular shape in a plan view. The anti-vibration material 4 is arranged so that the longitudinal direction is along the longitudinal direction of the floor beam 2. A pair of left and right anti-vibration materials 4 are placed on the upper surface of the floor beam 2 (upper flange 2a). The left and right ALC floor plates 3 (recesses 3a) are placed on the pair of left and right anti-vibration materials 4, respectively. The vibration-proof material 4 of the present embodiment is formed so that the thickness (vertical width) is 6 mm.

The surface of the anti-vibration material 4 (particularly, the upper surface and the lower surface) is appropriately coated. As the material of the coating, a material capable of reducing the friction between the vibration-proof material 4 and the floor beam 2 and the friction between the vibration-proof material 4 and the ALC floor plate 3 is appropriately selected.

The fixing member 5 shown in FIG. 1 fixes the ALC floor plate 3 to the floor beam 2. The fixing member 5 is formed in a substantially L-shape (hook shape) when viewed from the front. The fixing member 5 is arranged so as to vertically penetrate the ALC floor plate 3 (recessed portion 3a), and sandwiches the ALC floor plate 3 and the floor beam 2 (upper flange 2a) from above and below. Thereby, the ALC floor plate 3 can be fixed to the floor beam 2. At this time, a cushion material 5a is provided between the fixing member 5 and the floor beam 2 (flange 2a). The cushion material 5a is made of a material capable of suppressing the transmission of vibration.

The soundproof mat 6 is placed on the ALC floor plate 3. The soundproof mat 6 is made of an appropriate material capable of suppressing the transmission of sound and vibration. The soundproof mat 6 of the present embodiment is formed so that the specific gravity is 3.0 and the thickness (vertical width) is 10 mm.

Further, the particle board 7 and the floor material 8 are placed on the soundproof mat 6 in order. The particle board 7 of the present embodiment is formed so that the thickness (vertical width) is 9 mm. Further, the floor material 8 according to the present embodiment is formed so as to have a thickness of 12 mm. The floor material 8 forms the floor surface of the upper floor (the upper floor of the floor structure 1).

The ceiling panel 9 is a plate-shaped member formed of a frame material 9a, a sound absorbing material 9b, and the like. The sound absorbing material 9b is formed of a porous material such as rock wool. The ceiling panel 9 is arranged below the floor beam 2. The ceiling panel 9 is fixed to the floor beam 2 via a hanging member 11 described later. Two gypsum boards 10 are provided on the lower surface of the ceiling panel 9. The sound absorbing material 9b of the present embodiment is formed so that the thickness (vertical width) is 50 mm or more (for example, 55 mm). Further, the gypsum board 10 of the present embodiment is formed so as to have a thickness of 12 mm or more (for example, 12.5 mm).

The hanging member 11 fixes the ceiling panel 9 to the floor beam 2. The hanging member 11 is fixed to the floor beam 2 (lower flange 2a) and the ceiling panel 9, respectively. Thereby, the hanging member 11 can fix the ceiling panel 9 to the floor beam 2. A part of the suspension member 11 is formed by a leaf spring 11a, and the ceiling panel 9 and the floor beam 2 are connected via the leaf spring 11a. The leaf spring 11a can suppress the transmission of vibration between the floor beam 2 and the ceiling panel 9.

In the floor structure 1 configured in this way, the sound insulation can be improved by the high-density ALC floor plate 3. Further, the sound insulation is improved by forming the thickness of the ALC floor plate 3 to be relatively thick (150 mm). However, the recess 3a is formed in the ALC floor plate 3 and the recess 3a is supported by the floor beam 2. , I try not to affect the floor height.

Further, by using the soundproof mat 6 having a relatively high specific gravity, it is possible to suppress the floor height, the number of constructions, the cost, and the like, and it is possible to improve the sound insulation property with a simple configuration. Further, by arranging the anti-vibration material 4 between the floor beam 2 and the ALC floor plate 3 so as to extend (linearly) along the longitudinal direction of the floor beam 2, the compressive strength is ensured and the anti-vibration material 4 is arranged. We are trying to improve the property (sound insulation). In particular, in such a configuration, since the anti-vibration material 4 can be arranged in a portion close to the upper floor, it is possible to take anti-vibration measures at a position close to the sound source on the upper floor, and a great cost-effectiveness can be expected. ..

Further, by using the leaf spring 11a for the suspension material 11, the vibration isolation (sound insulation) can be improved with a simple configuration, and the number of constructions can be suppressed. Further, since a vibration-proof material (fluid damper or the like) using a fluid material whose effect is uncertain is not used, a stable sound insulation effect can be obtained.

As described above, the floor structure 1 according to the present embodiment is
Floor beam 2 and
The ALC floor plate 3 fixed to the floor beam 2 and
Equipped with
The ALC floor board 3 is
It is provided with a recess 3a formed on the lower surface, and has a recess 3a.
The floor beam 2 is
It is fixed to the ALC floor plate 3 in the recess 3a.
With this configuration, even when the thickness of the ALC floor plate 3 is increased, a floor surface having a desired height can be easily formed. That is, by appropriately setting the depth of the recess 3a, the upper surface of the ALC floor plate 3 can be set to a desired height even if the thickness of the ALC floor plate 3 is increased. Further, since a part of the floor beam 2 can be arranged in the recess 3a of the ALC floor plate 3, the thickness of the other portion (the portion other than the recess 3a) can be increased. As a result, high sound insulation can be ensured.

Further, the floor structure 1 has a floor structure 1.
Further, the anti-vibration material 4 is interposed between the ALC floor plate 3 and the floor beam 2 and is arranged so that the longitudinal direction is along the longitudinal direction of the floor beam 2.
With such a configuration, the sound insulation performance can be improved. That is, the sound insulation can be improved in a wide range along the longitudinal direction of the floor beam 2. Further, by arranging the vibration-proof material 4 in this way, it becomes easy to secure the compressive strength.

Further, on the surface of the vibration-proof material 4, at least a part of the surface in contact with the floor beam 2 or the ALC floor plate 3 is coated to reduce friction.
With such a configuration, workability at the time of construction can be improved. That is, when the ALC floor plate 3 is positioned with respect to the floor beam 2, the ALC floor plate 3 can be easily moved by sliding while being placed on the floor beam 2 (more accurately, the anti-vibration material 4). Further, since the anti-vibration material 4 and the floor beam 2 or the ALC floor plate 3 can be made slippery, it is possible to suppress unintended deformation of the anti-vibration material 4 when vibration or the like occurs. As a result, it is possible to suppress a decrease in the vibration-proof property (sound insulation property) of the vibration-proof material 4.

Further, the recess 3a is
It is formed so as to spread downward.
With such a configuration, workability at the time of construction can be improved. That is, during the construction of the floor structure 1, the recess 3a and other members (for example, the floor beam 2 and the fixing member 5) are prevented from unintentionally interfering with each other, and a wide work space is secured. Can be done.

Further, the floor structure 1 has a floor structure 1.
A soundproof mat 6 (soundproof material) interposed between the ALC floor plate 3 and the floor material 8 and
A suspension member 11 (ceiling fixing member) for fixing the ceiling panel 9 to the floor beam 2 via a leaf spring 11a (elastic member),
Is further provided.
With such a configuration, the sound insulation performance can be further improved. That is, vibration can be suppressed stepwise by the ALC floor plate 3, the vibration-proof material 4, the sound-proof mat 6, and the hanging material 11, and high sound-insulating properties can be obtained. In particular, by interposing the vibration isolator 4 between the ALC floor plate 3 and the floor beam 2, vibration can be transmitted from the upper floor to the lower floor in a portion close to the sound source (sound source) generated on the upper floor. It can be suppressed and high sound insulation can be ensured. Further, by making the ALC floor plate 3 having a relatively high density, higher sound insulation can be ensured.

Further, in the present embodiment, the thickness of the vibration-proof material 4 is suppressed to 6 mm. By keeping the thickness of the vibration-proof material 4 small in this way, it is possible to prevent the elasticity of the vibration-proof material 4 from adversely affecting the performance of the floor vibration. Further, in the present embodiment, the thickness of the soundproof mat 6 is relatively large (10 mm) while the thickness of the vibration-proof material 4 is suppressed. As a result, the balance between the vibration-proof property (soundproof property) by the vibration-proof material 4 and the vibration-proof property by the soundproof mat 6 is improved, and the soundproof performance of the floor structure 1 as a whole is improved.

The soundproof mat 6 according to the present embodiment is an embodiment of the soundproof material according to the present invention.
Further, the leaf spring 11a according to the present embodiment is an embodiment of the elastic member according to the present invention.
Further, the suspending material 11 according to the present embodiment is an embodiment of the ceiling fixing member according to the present invention.

Although one embodiment of the present invention has been described above, the present invention is not limited to the above configuration, and various modifications can be made within the scope of the invention described in the claims.

For example, the shape, material, and the like of each part of the floor structure 1 can be appropriately changed within the scope of the invention described in the claims.

Further, the position and shape of the recess 3a of the ALC floor plate 3 can be arbitrarily changed. For example, in the present embodiment, the side surface 3b is formed in a tapered shape so that the recess 3a expands downward, but the side surface 3b can also be formed substantially vertically.

Further, the configurations of the fixing member 5 and the suspending member 11 are examples, and the shape and the like are not limited as long as the members can be fixed to each other.

Further, the suspension member 11 is intended to fix the ceiling panel 9 to the floor beam 2 via the leaf spring 11a, but the present invention is not limited to this, and various other elastic members (for example, rubber or the like) are used instead of the leaf spring 11a. ) Can also be used.

Further, in the present embodiment, the upper surface and the lower surface of the vibration-proof material 4 (that is, the entire surface in contact with the floor beam 2 and the ALC floor plate 3) are coated, but the present invention is not limited to this. do not have. For example, at least a part of the surface in contact with the floor beam 2 or the ALC floor plate 3 may be coated.

1 Floor structure 2 Floor beam 3 ALC floor board 3a Recess 4 Anti-vibration material 5 Fixing member 6 Soundproof mat 8 Floor material 9 Ceiling panel 11 Suspension material 11a Leaf spring

Claims (5)

Floor beams and
The ALC floor board fixed to the floor beam and
Equipped with
The ALC floor board is
It has a recess formed on the lower surface and has a recess.
The floor beam is
Fixed to the ALC floor plate in the recess,
A floor plate fixing member for fixing the ALC floor plate to the floor beam by penetrating the ALC floor plate vertically and sandwiching the ALC floor plate and the floor beam from above and below is further provided.
The lower end portion of the floor plate fixing member is arranged in the recess and is located above the lower surface of the ALC floor plate.
Further comprising an anti-vibration material interposed between the ALC floor plate and the floor beam and arranged so that the longitudinal direction is along the longitudinal direction of the floor beam.
Floor structure. A cushion material is provided between the lower end of the floor plate fixing member and the lower surface of the upper flange of the floor beam.
The floor structure according to claim 1. Of the surface of the vibration-proof material, at least a part of the surface in contact with the floor beam or the ALC floor plate is coated to reduce friction .
The floor structure according to claim 1 or 2. The recess is
Formed to spread downward,
The floor structure according to any one of claims 1 to 3 . A soundproofing material interposed between the ALC floorboard and the flooring material,
A ceiling fixing member that fixes the ceiling panel to the floor beam via an elastic member,
Further equipped,
The floor structure according to any one of claims 1 to 4.

Images