JP2020002541A - Ceiling structure of building - Google Patents

Abstract

To provide the ceiling structure of a building providing higher noise insulation effect than a structure of lining noise insulation mats on all over gypsum boards or of increasing thickness of the gypsum boards.SOLUTION: The ceiling structure of a building comprises a ceiling substrate panel 2 formed by partitioning the inside of an outer frame 2a into multiple areas by reinforcement members 2b, and reinforced gypsum boards 3 formed by partitioning a vibration area into multiple sections by fixing the vibration area to the outer frame 2a and the reinforcement members 2b of the ceiling substrate panel 2. Noise insulation mats are provided to each of the multiple partitioned areas so as to integrally vibrate with the reinforced gypsum boards 3.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a ceiling structure of a building having excellent sound insulation performance.

  Patent Literature 1 discloses a ceiling base panel provided with a cross-shaped reinforcement portion in an outer frame, an impact sound reduction damper provided at an intersection of the cross-shaped reinforcement portion, and a gypsum fixed to the ceiling base panel. A ceiling structure having improved sound insulation by providing a board is disclosed. Further, as a ceiling structure having excellent sound insulation properties, a structure in which a sound insulation mat is solidly applied to the entire plaster board can be considered. Further, it is conceivable to increase the thickness of the gypsum board or increase the number of the gypsum boards.

JP 2013-147871 A

  However, the ceiling structure described in the above-mentioned patent document is a structure including an impact sound reduction damper, and therefore has excellent sound insulation performance, but has a drawback that the design and construction of the damper are complicated and the cost is increased. Further, in a structure in which the sound insulation mat is solidly attached to the entire plaster board, the plaster board easily vibrates as a whole, and therefore, the sound insulation effect cannot be sufficiently expected with respect to low-frequency vibration. Further, in a structure in which the thickness of the gypsum board is increased, the rigidity of the ceiling surface is increased and the area for emitting radiated sound is increased, so that also in this case, the sound insulation effect against low-frequency vibration cannot be sufficiently expected.

  An object of the present invention is to provide a ceiling structure of a building in which a sound insulating effect higher than a sound insulating effect in a structure in which a sound insulating mat is solidly adhered to the entire plaster board or a structure in which the thickness of the plaster board is increased is obtained. .

  In order to solve the above-described problems, the ceiling structure of a building according to the present invention includes a ceiling base panel in which the inside of an outer frame is divided into a plurality of regions by a reinforcing member, and the outer frame and the reinforcing member of the ceiling base panel. A ceiling structure of a building including a board partitioned into a plurality of vibration areas by being fixed, wherein a sound insulating mat is provided in the section so as to vibrate integrally with the board. I do.

  With the above configuration, the board can independently vibrate in the plurality of sections instead of the entire board. And the sound insulation mat is arranged in the section, and since the sound insulation mat does not have the rigidity of the board, when each section of the board vibrates independently, the sound insulation mat may be another board. The sound insulation mat can behave independently of each other, and compared to a structure in which the sound insulation mat is solidly attached to the entire board or a structure in which the thickness of the board is increased, the radiated sound from the ceiling surface can be suppressed, especially at low frequencies. Become. Further, an increase in cost can be avoided as compared with the structure using the shock noise reduction damper.

  The specific gravity of the sound insulating mat may be 2 or more. According to this, it is possible to enhance the vibration damping effect on the board by the sound insulating mat in the section.

  The sound insulation mat may contain asphalt, iron oxide, and calcium carbonate. Further, the mixing ratio of the asphalt among the asphalt, the iron oxide, and the calcium carbonate may be the smallest, and according to this, the specific gravity of the sound insulating mat can be made as high as possible. Further, the compounding ratio of the asphalt may be 5 to 25% by weight, the compounding ratio of the iron oxide may be 35 to 65% by weight, and the compounding ratio of the calcium carbonate may be 25 to 45% by weight.

  When the ratio of the area of the section and the area of the sound insulating mat is x: kx, the condition of 1/5 <k <1 may be satisfied. Further, the thickness of the sound insulation mat may be 4 mm or more and 10 mm or less. According to these, it is possible to enhance the vibration damping action on the board by the sound insulating mat in the section.

  The outer frame may be supported by beams of the building. In such a structure, the board tends to vibrate in a large area due to the entire board, but by vibrating independently in a plurality of sections as described above, a high sound insulation effect can be obtained.

  According to the present invention, it is possible to avoid an increase in cost due to the use of the impact sound reduction damper, and to reduce the sound insulation effect in a structure in which the sound insulation mat is solidly applied to the entire gypsum board or a structure in which the thickness of the gypsum board is increased. The effect that a high sound insulation effect is obtained is produced.

It is the perspective view which showed the outline of the ceiling structure of the building of embodiment of this invention. It is sectional drawing which showed the outline of the ceiling structure and floor structure of FIG. It is explanatory drawing which showed the outline of the ceiling structure and floor structure of FIG. 1 in three dimensions. It is the graph which showed the measurement result of the heavy floor impact sound level in the ceiling structure of the building of embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. As shown in FIG. 1, a ceiling structure 1 of a building according to this embodiment includes a ceiling base panel 2 and two reinforced gypsum boards 3. As an example, the long side of the ceiling base panel 2 and the reinforced gypsum board 3 is approximately 1820 mm, and the short side is approximately 910 mm.

  In the ceiling base panel 2, the inside of the rectangular outer frame 2a is rectangularly divided into a plurality of regions (eight in this example) by the reinforcing member 2b. In particular, in this example, each region has a substantially square shape. A plurality of suspension fittings 41 are attached to the lower flange of the H-section steel, which becomes the beam 4 of the building, and the ceiling base panel 2 is suspended and supported by the suspension fittings 41.

  The reinforced gypsum board 3 is fixed to the lower surface side of the ceiling base panel 2. This fixation is performed by pressing the reinforced gypsum board 3 on the underside of the ceiling base panel 2 fixed to the beam 4 at the site, and screws or the like from the lower side of the reinforced gypsum board 3 to the ceiling base panel 2. You can do it by typing. In this way, by fixing the reinforced gypsum board 3 to the outer frame 2a and the reinforcing member 2b of the ceiling base panel 2, the vibration region is divided into a plurality of areas in the reinforced gypsum board 3. In this example, the vibration region of each reinforced gypsum board 3 is divided into eight by the outer frame 2a and the reinforcing member 2b, but is not limited to such eight divisions.

  On the other hand, as shown in FIGS. 2 and 3, a floor 7 of a building is formed on the upper flange of the beam 4. On the floor 7, a precast concrete slab 72 is placed on the upper flange of the beam 4 with an anti-vibration rubber 71 interposed therebetween. The precast concrete slab 72 is fixed so as to be pressed against the beam 4 by a fixture (not shown). A plurality of ribs 72a are formed at equal intervals on the upper surface side of the precast concrete slab 72. On the rib portion 72a, a calcium silicate plate 74 is disposed via a vibration isolating rubber 73, and on the calcium silicate plate 74, a damping mat 75 and a flooring 76 are disposed.

  And in the said ceiling structure 1, the sound insulation mat 5 is provided so that it may vibrate integrally with the said gypsum board 3 in each of said several division. For example, the sound insulation mat 5 can be adhered to the reinforced gypsum board 3 using an adhesive, double-sided tape, or self-adhesion of the sound insulation mat, and can be integrated therewith. A rock wool sound absorbing material 6 is provided on the ceiling base panel 2 and the reinforced gypsum board 3. For example, the sound insulating mat 5 is bonded and arranged in advance on the upper surface of the reinforced gypsum board 3 located on the upper side, and the reinforced gypsum board 3 to which the sound insulating mat 5 has been bonded is fixed to the beam 4 above the ceiling base. A construction method in which the panel 2 is pressed against and fixed to the lower side can be used.

  The sound insulation mat 5 contains, for example, asphalt, iron oxide, and calcium carbonate, and the mixing ratio of the asphalt is the least among these materials. Regarding the compounding ratio of the sound insulating mat 5 used for verifying the sound insulating performance, the asphalt was 15% by weight, the iron oxide was 50% by weight, the calcium carbonate was 35% by weight, and the specific gravity was 2.5. Further, the thickness of the used sound insulating mat 5 was 6 mm. The used sound insulation mat 5 had such a size that the edge did not come into contact with the outer frame 2a and the reinforcing member 2b, and was specifically 227.5 mm square. Further, the sound insulation mat 5 was attached to the reinforced gypsum board 3 with a double-sided tape to be integrated.

In the verification of the sound insulation performance, the following conditions were adopted.
・ Floor slab: precast concrete slab 72 (fixing bracket tightening torque 12.5N)
-Cushioning material: anti-vibration rubber 71 on beam 4 (width 30 w x length 186 mm, thickness 19 mm)
Floor configuration: anti-vibration rubber 73 (5 mm thick) / calcium silicate plate 74 (9 mm thick) / vibration damping mat 75 (specific gravity 3.0, 8 mm thick) / flooring 76 (thickness) on rib 72 a 12mm)
・ Ceiling composition: Rock wool sound absorbing material 6 (30K, thickness 55mm) / Ceiling base panel 2 / reinforced gypsum board ・ Sound source room: 6 tatami mat on the second floor ・ Measurement item: Heavy floor impact sound level (LH)
Test contents: (1) Benchmark: Two layers of 12.5 mm thick reinforced gypsum boards were applied on the ceiling.
(2) On the ceiling, two layers of reinforced gypsum board 3 having a thickness of 12.5 mm were adhered, and sound insulation mats 5 (thickness 6 mm, specific gravity 2.5, size 227.5 mm square) were provided at a 455 mm pitch. .
(3) Two layers of 15 gm thick reinforced gypsum board were stuck on the ceiling.
-Measuring method: JIS-A-1418 "Measurement method of floor impact sound insulation performance of building". Lmax (heavy floor impact sound level) at 5 times of tire drop / Sound receiving point height is 80, 100, 120, 140, 160 cm
-Evaluation method: JIS-A-1419-2 "Evaluation method of sound insulation performance of buildings and building members-Part 2: Floor impact sound insulation performance".

  The results of verifying the sound insulation performance are shown in Table 1 and the graph of FIG.

  As can be seen from the above Table 1 and the graph of FIG. 4, in the weight floor impact sound level (LH), the configuration in which the thickness of the reinforced gypsum board of (3) is increased is 0 in comparison with the benchmark of (1). A difference of 0.9 dB was observed, and a difference of 2.0 dB was observed in the structure (2) having the sound insulation mats 5 interspersed with the benchmark of (1). That is, the structure provided with the sound insulation mats 5 in (2) in a dotted manner has a weight floor impact sound level (LH) of 1.1 dB as compared with the structure in which the thickness of the reinforced gypsum board in (3) is increased. It has been improved.

  The reinforced gypsum board 3 can vibrate independently in the plurality of sections instead of the whole. The sound insulation mats 5 are arranged in the respective partition areas, and each of the sound insulation mats 5 does not have the rigidity of the reinforced gypsum board 3. Therefore, when the respective sections of the reinforced gypsum board 3 vibrate independently. In addition, the sound insulating mat 5 can behave independently of other sound insulating mats, and is particularly low in comparison with a structure in which the sound insulating mat is solidly applied to the entire reinforced gypsum board and a structure in which the thickness of the reinforced gypsum board is increased. As for the frequency, it becomes possible to suppress the radiated sound from the ceiling surface. Further, an increase in cost can be avoided as compared with the structure using the shock noise reduction damper.

  In addition, it is considered that the structure in which the sound insulation mat is solidly applied to the entire reinforced gypsum board is similar to increasing the thickness of the entire reinforced gypsum board or increasing the number of sheets for low sound. That is, it is considered that the sound insulation performance of the structure in which the sound insulation mat is solidly applied to the entire reinforced gypsum board is equivalent to the sound insulation performance of the configuration in which the thickness of the reinforced gypsum board in (3) is increased. Here, if it is assumed that the ceiling weight is increased by the same weight with respect to the benchmark of (1), the weight of (2) is increased rather than increasing the thickness of (3) by increasing the thickness of the reinforced gypsum board. It can be said that better sound insulation performance can be obtained by increasing the weight by arranging the sound insulating mats 5, and the dotted arrangement of the sound insulating mats 5 in (2) is to strengthen the sound insulating mats as a whole plaster board. It can be said that high sound insulation performance can be obtained with a smaller weight increase as compared with the weight increase when the solid is applied.

  When the specific gravity of the sound insulating mat 5 is 2 or more, the sound insulating mat 5 can have an appropriate weight to enhance the vibration damping action of the sound insulating mat 5 in each vibration section. The upper limit of the specific gravity of the sound insulating mat 5 may be 3.5 or less.

  In the case where the sound insulating mat 5 contains asphalt, iron oxide and calcium carbonate as described above, the specific gravity of the sound insulating mat 5 is reduced if the mixing ratio of the asphalt is the smallest among these materials. It becomes easy to increase as much as possible. For example, the compounding ratio of the asphalt may be 5 to 25% by weight, the compounding ratio of the iron oxide may be 35 to 65% by weight, and the compounding ratio of the calcium carbonate may be 25 to 45% by weight. Preferably, the ratio is 10 to 20% by weight, the compounding ratio of the iron oxide is 40 to 60% by weight, and the compounding ratio of the calcium carbonate is 30 to 40% by weight. In addition, although the compounding amount of the rubber material is set to 0 in the material mixing of the sound insulating mat 5, the compounding ratio of the rubber material may be set to 0 to 10% by weight. Of course, other materials may be added. In addition, the surface of the sound insulating mat 5 may be covered with a nonwoven fabric covering material, which facilitates cutting out the sound insulating mat 5 to a predetermined size.

  When the ratio of the area of the section to the area of the sound insulating mat 5 is x: kx, the condition of 1/5 <k <1 may be satisfied. Further, the thickness of the sound insulating mat 5 may be 4 mm or more and 10 mm or less. According to these, it is possible to enhance the vibration damping action of the sound insulating mat 5 on the reinforced gypsum board 3 in each vibration section.

  When the outer frame 2a is supported by the beams 4 of the building, the outer frame 2a tends to vibrate in a large area due to the entire reinforced gypsum board 3. By vibrating, a high sound insulation effect can be obtained.

  Although the embodiments of the present invention have been described with reference to the drawings, the present invention is not limited to the illustrated embodiments. Various modifications and variations can be made to the illustrated embodiment within the same range as the present invention or within an equivalent range.

1: ceiling structure 2: ceiling base panel 2a: outer frame 2b: reinforcing member 3: reinforced gypsum board (board)
4: Beam 5: Sound insulation mat 6: Rock wool sound absorbing material 7: Floor 41: Suspension metal fitting 71: Anti-vibration rubber 72: Precast concrete plate 72a: Rib portion 73: Anti-vibration rubber 74: Calcium silicate plate 75: Vibration damping mat 76: Flooring

Claims (8)

  A building including a ceiling base panel in which the inside of an outer frame is partitioned into a plurality of regions by a reinforcing member, and a board partitioned into a plurality of vibration regions by being fixed to the outer frame and the reinforcing member of the ceiling base panel. The ceiling structure of a building, wherein a sound insulation mat is provided in the section so as to vibrate integrally with the board.   The ceiling structure of a building according to claim 1, wherein the specific gravity of the sound insulation mat is 2 or more.   3. The ceiling structure of a building according to claim 1, wherein the sound insulating mat contains asphalt, iron oxide, and calcium carbonate. 4.   4. The ceiling structure of a building according to claim 3, wherein a mixing ratio of the asphalt is the smallest among the asphalt, the iron oxide, and the calcium carbonate.   The ceiling structure of a building according to claim 4, wherein the asphalt has a compounding ratio of 5 to 25% by weight, the iron oxide has a compounding ratio of 35 to 65% by weight, and the calcium carbonate has a compounding ratio of 25 to 45% by weight. The ceiling structure of a building characterized by the fact that there is.   In the ceiling structure of a building according to any one of claims 1 to 5, when a ratio of an area of the section and an area of the sound insulation mat is x: kx, a condition of 1/5 <k <1 is satisfied. The ceiling structure of a building characterized by satisfying.   The ceiling structure of a building according to any one of claims 1 to 6, wherein the thickness of the sound insulation mat is 4 mm or more and 10 mm or less.   The ceiling structure of a building according to any one of claims 1 to 7, wherein the outer frame is supported by beams of the building.