JP2020002648A - Noise reduction method and attic structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a noise reduction method and an attic structure for reducing noise from the attic. SOLUTION: In a noise reduction method, a sound pressure level corresponding to a frequency in a room to be measured is measured with a sound level meter (S10), and a set frequency to be reduced is set based on the measurement result by the sound level meter (S20). Find the position in the horizontal plane of the ceiling where the particle velocity of the set frequency is maximized (S30), and install a sound absorbing material extending in the width direction of the ceiling and the height of the ceiling at at least one of the positions (S30). S40). [Selection diagram] Fig. 1

Description

  The present invention relates to a noise reduction method for reducing noise from above the ceiling and a structure above the ceiling.

  When a building such as a tenant building is partitioned by a partition wall to a ceiling, a soundproofing device has been proposed in which a sound-absorbing material is erected behind the ceiling for soundproofing and soundproofing between adjacent rooms (Patent Document 1). ). The soundproofing device of Patent Literature 1 is installed behind a ceiling above a partition wall.

  On the other hand, when low-frequency noise is generated from equipment such as fans, air conditioners, and ducts installed in the space behind the ceiling between the ceiling and the upper floor, In some cases, noise reduction is required. In such a case, it is common to install a sound absorbing material on the equipment itself, not on the sound insulation device between adjacent rooms. However, such a measure against low-frequency sound imposes a heavy construction load, and the low-frequency sound cannot be reduced significantly.

JP-A-8-22289

  Therefore, an object of the present invention is to provide a noise reduction method for reducing noise from above the ceiling and a structure above the ceiling.

  SUMMARY An advantage of some aspects of the invention is to solve at least a part of the problems described above, and the invention can be implemented as the following aspects or application examples.

[1] One aspect of the noise reduction method according to the present invention is as follows.
Measure the sound pressure level according to the frequency in the room with a sound level meter,
Set a frequency to be reduced based on the measurement result by the sound level meter,
Find the position in the horizontal plane behind the ceiling where the particle velocity of the set frequency is the maximum,
At least one of the positions is provided with a sound absorbing material extending in a width direction of the ceiling space and a height direction of the ceiling space.

  According to one aspect of the noise reduction method, the noise from the ceiling can be reduced by installing the sound absorbing material at an appropriate position in the ceiling.

[2] In one aspect of the noise reduction method,
Two parallel walls facing each other are arranged behind the ceiling,
The position can be obtained from the result of measuring the sound pressure level of the set frequency at a plurality of locations between the two walls by the sound level meter.

  According to one aspect of the noise reduction method, the sound absorbing material can be installed at an appropriate position based on the measurement results of the sound pressure levels at a plurality of locations between two opposing parallel walls behind the ceiling.

[3] In one embodiment of the noise reduction method,
Two parallel walls facing each other are arranged behind the ceiling,
The position can be determined as a position at a distance from one of the two walls toward the other, which is an odd multiple of 1/4 wavelength of the set frequency.

  According to one aspect of the noise reduction method, the sound absorbing material can be installed at an appropriate position based on the wavelength of the set frequency.

[4] In one embodiment of the noise reduction method,
Two parallel walls facing each other are arranged behind the ceiling,
The position is an odd multiple of 1 / 2n (n is a natural number) of the distance from one of the walls to the other when the distance between the two walls matches or approximates the length of the wavelength of the set frequency. It can be obtained as a position.

  According to one aspect of the noise reduction method, the sound absorbing material can be installed at an appropriate position when the interval between two opposing walls behind the ceiling matches or approximates the wavelength of the standing wave.

[5] One embodiment of the structure above the ceiling according to the present invention is:
The width of the ceiling at least one of the positions where the horizontal distance from one of two opposing parallel walls on the ceiling to the other is an odd multiple of 1/4 wavelength of the set frequency to be reduced. It has a sound absorbing material extending in a direction and a height direction of the ceiling space.

  According to one aspect of the above-the-ceiling structure, noise from the inside of the ceiling to the room can be reduced by the sound absorbing material provided on the ceiling.

[6] One embodiment of the structure above the ceiling according to the present invention is:
At least one of positions at which a horizontal distance from one of two opposing parallel walls behind the ceiling to the other is an odd multiple of 1 / 2n (n is a natural number) of the distance between the two walls. It is characterized by having a sound absorbing material extending in the width direction of the ceiling back and the height direction of the ceiling back above the location.

  According to one aspect of the above-the-ceiling structure, noise from the inside of the ceiling to the room can be reduced by the sound absorbing material provided on the ceiling.

[7] In one aspect of the under-the-ceiling structure,
The sound absorbing material may be a structure including a porous sound absorbing material having air permeability.

  According to one aspect of the above-the-ceiling structure, noise from the room above the ceiling to the room can be reduced by the sound absorbing material including the porous sound absorbing material having air permeability.

  ADVANTAGE OF THE INVENTION According to this invention, the noise reduction method which reduces the noise from behind a ceiling can be provided. Further, according to the present invention, it is possible to provide an under-the-roof structure that reduces noise from behind the ceiling.

4 is a flowchart of a noise reduction method according to the embodiment. It is a longitudinal section of a measurement object room and a ceiling back of a noise reduction method concerning this embodiment. It is a top view of a measurement object room of the noise reduction method concerning this embodiment. It is a top view of the ceiling back of the construction object of the noise reduction method concerning this embodiment. It is a longitudinal section of the ceiling back of the construction subject of the noise reduction method concerning this embodiment, and is a figure explaining the relation between a standing wave and particle velocity. It is a longitudinal cross-sectional view of the inside of the ceiling showing the installation state of the sound absorbing material of the noise reduction method according to the embodiment. It is a top view of the ceiling back which shows the installation state of the sound absorbing material of the noise reduction method concerning this embodiment. 5 is a measurement result of a sound pressure level in a room in Example 1. 3 is a sound pressure distribution in a room in the first embodiment. Fig. 3 is a sound pressure distribution under the ceiling before construction in Example 1. 5 is a measurement result of a sound pressure level in a room after construction in Example 1. 5 is a sound pressure distribution in a room after construction in Example 1.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. The embodiments described below do not unduly limit the contents of the present invention described in the claims. In addition, all of the configurations described below are not necessarily essential components of the invention.

  The noise reduction method according to one embodiment of the present invention measures a sound pressure level according to a frequency in a room with a sound level meter, sets a set frequency to be reduced based on a measurement result by the sound level meter, and sets the set frequency. Determining a position in the horizontal plane above the ceiling at which the particle velocity becomes maximum, and installing a sound absorbing material extending in the width direction of the ceiling space and the height direction of the ceiling space in at least one of the positions. And

1. Noise Reduction Method A noise reduction method according to the present embodiment will be described with reference to FIGS. FIG. 1 is a flowchart of a noise reduction method according to the present embodiment, FIG. 2 is a longitudinal sectional view of a measurement target room 10 and a ceiling space 20, FIG. 3 is a plan view of the measurement target room 10, and FIG. FIG. 5 is a plan view of the ceiling space 20 to be constructed, FIG. 5 is a longitudinal sectional view of the ceiling space 20 to be constructed, and is a diagram for explaining the relationship between the standing wave Sw and the particle velocity. FIG. 7 is a vertical sectional view of the ceiling space 20 showing the installation state of the sound absorbing members 40 and 41, and FIG.

  As shown in FIG. 1, the noise reduction method according to the present embodiment includes an indoor measurement step (S10), a setting step (S20), a step of obtaining a position (S30), and an installation step (S40). According to one aspect of the noise reduction method, noise from the ceiling back 20 can be reduced by installing the sound absorbing materials 40 and 41 at appropriate positions on the ceiling back 20. The noise reduction method can be performed by installing the sound absorbing materials 40 and 41 at appropriate positions on the ceiling floor 20 above the measurement target room 10. Hereinafter, each step will be described in detail.

  S10: The indoor measurement step is a step of measuring the sound pressure level according to the frequency in the room with the sound level meter. By measuring the sound pressure level in the room, a measurement result used for estimating or specifying the frequency of the noise in question can be obtained.

  As shown in FIG. 2, the “room” is inside the measurement target room 10 in which noise is a problem. As shown in FIGS. 2 and 3, the measurement target room 10 is a space formed by walls 11, 12, 13, 14, a ceiling 15, and a floor 16 arranged on four sides, for example. In the present embodiment, the measurement target room 10 is one room, but the measurement target room 10 may be a set of two or more rooms in a building.

As shown in FIG. 2 and FIG. 4, there is a ceiling space 20 above the measurement target room 10. The ceiling back 20 is a space surrounded by walls 21, 22, 23, 24 arranged on all sides, a ceiling 15 of the measurement target room 10, and a floor 25 on the upper floor. If there is no upper floor, a roof may be used instead of the floor 25.
The walls 21, 22, 23, 24 need not be arranged to completely cover all sides, but include at least two opposing parallel walls 21, 22. The ceiling space 20 can be substantially rectangular in plan view. The wall 21 and the wall 22 face each other at both ends in the longitudinal direction of the ceiling space 20 in plan view. The wall 23 and the wall 24 face each other at both ends in the short direction of the ceiling space 20 in plan view. In the present embodiment, the longitudinal walls 21 and 22 of the ceiling space 20 will be described, but two parallel walls 23 and 24 of the ceiling space 20 that are opposed to each other in the short direction may be used instead of the two walls 21 and 22. .

  Equipment 30 can be arranged on the ceiling 20. The equipment 30 is, for example, a fan, an air conditioner, a duct, or the like, and in the case of indoor noise, the equipment 30 located in the ceiling 20 may be a source of noise. The so-called low frequency sound of 20 Hz to 100 Hz out of the noise generated by the equipment 30 tends to be a problem. In the noise reduction method according to the present embodiment, it is possible to reduce the noise corresponding to the dominant frequency component of the low-frequency sound generated in the ceiling space 20.

  As the sound level meter, a commercially available sound level meter capable of analyzing the frequency of noise can be employed. The sound level meter can measure a sound pressure level according to a frequency by, for example, 1/3 octave band analysis. In order to accurately set the frequency to be reduced, it is preferable to use a high-precision bandpass filter. For example, a 1/3 octave band filter is more preferable than a 1/1 octave band filter. According to the 1/3 octave band analysis, it is possible to measure the sound pressure level for each band obtained by dividing one octave of the frequency into three. The measurement result can be represented as a sound pressure level at the center frequency of the 1/3 octave band.

  The measurement of the sound pressure level in the measurement target room 10 by the sound level meter can be performed at a plurality of places in the room, for example, the positions of square points in FIGS. 2 and 3. The measurement positions in FIGS. 2 and 3 are, for example, at equal intervals of 0.5 m from the wall 11 to the wall 12 and 0.5 m from the wall 13 to the wall 14 in a horizontal plane having a height H2 lower than the total height H1 of the measurement target chamber 10. Are arranged at equal intervals.

  In the present embodiment, an example will be described in which all the measurement positions in the fourth row from the wall 21 to the wall 23 in FIGS.

  S20: The setting step is a step of setting a set frequency to be reduced based on the measurement result by the sound level meter in the indoor measurement step (S10). The measurement result by the sound level meter is a sound pressure level corresponding to the frequency at each measurement position. For example, the center frequency (unit: Hz) is plotted on the horizontal axis, and the sound pressure level (unit: dB) is plotted on the vertical axis. Create a line graph for each measurement position.

  Since the noise in question indicates an excellent sound pressure level in the measurement result, the frequency indicating the excellent sound pressure level is set as a set frequency to be reduced. The set frequency is the center frequency of the bandpass filter of the sound level meter. The set frequency can be a low frequency sound of 100 Hz or less.

  S30: The step of obtaining the position is a step of obtaining the positions A1 and A2 in the horizontal plane of the ceiling space 20 where the particle velocity at the set frequency set in the setting step (S20) is maximized. The phrase "the particle velocity at which the particle velocity becomes the maximum" includes the one at which the particle velocity at the preset frequency is estimated to be the maximum.

  The step of obtaining the position (S30) can be performed by the following two methods (1), (2) and (3).

(1) Measurement of the sound pressure level behind the ceiling The positions A1 and A2 of the ceiling above the ceiling 20 shown in FIG. 4 in the horizontal plane are measured at a plurality of locations between the two walls 21 and 22 by using a sound level meter. It can be determined from the measured results. Thereby, the sound absorbing materials 40 and 41 (FIGS. 6 and 7) are moved to the appropriate positions A1 and A2 based on the measurement results of the sound pressure levels at a plurality of locations between the two opposing parallel walls 21 and 22 of the ceiling space 20. Can be installed in The appropriate positions A1 and A2 of the sound absorbing members 40 and 41 are positions where the noise reduction effect in the measurement target room 10 is excellent.

  From the result of measuring the sound pressure level on the ceiling floor 20, the position where the sound pressure level becomes minimum may be determined as the positions A1 and A2 where the sound absorbing materials 40 and 41 are installed. The minimum sound pressure level means that the particle velocity at the set frequency becomes maximum. Therefore, by measuring sound pressure levels at a plurality of locations on the ceiling floor 20 using a sound level meter, the positions where the sound pressure levels become minimum can be obtained as the positions A1 and A2. When the positions A1 and A2 are obtained from the measurement results of the sound pressure level by the sound level meter, the sound level meter used in the indoor measurement step (S10) can be used.

  In FIG. 4, the position measured by the sound level meter is a position at a predetermined interval, for example, every 0.5 m from the wall 21 of the ceiling back 20 to the opposing wall 22 as indicated by a black dot, and is within a horizontal plane at a height H4 from the ceiling 15. Can be set to In FIG. 4, the measurement points are obtained for the walls 21 and 22 which are parallel walls opposed to each other in the longitudinal direction of the ceiling space 20, but the measurement points may be obtained for the short walls 23 and 24. Alternatively, the measurement may be performed in both the short direction and the short direction. It is preferable that the measurement position is set so as to avoid the equipment 30.

  In the present embodiment, the measurement position is targeted for the “longitudinal direction” of the ceiling space 20 because the particle measurement is performed in the longitudinal direction of the ceiling space 20 by performing the indoor measurement process (S10) over the entire area of the measurement target room 10. This is due to the assumption that there is a maximum position. Also, considering the wavelength of the low-frequency sound and the distance L1 in the longitudinal direction, antinodes of the particle velocities of a plurality of standing waves are considered to be formed in the longitudinal direction. The distance L1 is an interval between two opposing parallel walls 21 and 22.

(2) Calculate the distance from the wall The positions A1 and A2 in one horizontal plane of the ceiling 20 shown in FIG. 5 are set at the wavelength of the set frequency from one of the parallel walls 21 and 22 facing the ceiling 20 toward the other. Can be obtained as a position at a distance L2, L3 that is an odd multiple of 1/4 of. Thus, the sound absorbing members 40 and 41 can be installed at appropriate positions based on the wavelength of the set frequency. In the present embodiment, the two walls 21 and 22 facing each other in the longitudinal direction of the ceiling space 20 will be described. However, two walls 23 and 24 facing each other in the short direction may be used.

  It is inferred from the results of experiments by the inventors that a noise problem may occur when the standing wave Sw is generated at the ceiling 20 at the set frequency. Therefore, as shown in FIG. 5, when the wavelength of the set frequency to be reduced and the distance between the walls 21 and 22 of the ceiling space 20 match or approximate, the standing wave Sw of the set frequency is generated by the ceiling space 20. It can be estimated that it has occurred. The positions of the antinodes B1 and B2 of the standing wave Sw are located at distances L2 and L3 which are odd multiples of 1/4 of the wavelength of the standing wave Sw from the one wall 21, and are the positions A1 and A2 to be obtained. It is estimated that the particle velocity at the set frequency at the positions A1 and A2 obtained in this way becomes maximum.

  Since the positions A1 and A2 correspond to the positions of the antinodes B1 and B2 of the standing wave Sw, the sound absorbing materials 40 and 41 can be arranged at the positions where the particle velocity at the set frequency is maximum, so that noise is efficiently reduced. Can be reduced.

In the present embodiment, the distance from the wall 21 to the wall 23 is targeted for the same reason as in the above (1), and in consideration of the wavelength of the low-frequency sound and the distance L1 in the longitudinal direction, the longitudinal direction is considered. This is because antinodes B1 and B2 of the particle velocities of the plurality of standing waves Sw are considered to be formed.

  A step (S30) of obtaining a position by combining the above (1) and the above (2) may be performed. For example, when the positions A1 and A2 obtained in the above (1) and the positions A1 and A2 obtained in the above (2) match or approximate to each other, the position is obtained by either the above (1) or the above (2). The positions A1 and A2 may be adopted.

(3) Calculation Based on Wall Interval The positions A1 and A2 in one horizontal plane of the ceiling space 20 shown in FIG. In the case of matching or approximating the wavelength length, it can be determined as a position of an odd multiple of 1 / 2n (n is a natural number) of the distance L1 from one wall 21 to the other wall 22. Accordingly, when the distance L1 between the walls 21 and 22 of the ceiling space 20 matches or approximates the wavelength of the standing wave Sw, the sound absorbing members 40 and 41 can be installed at appropriate positions. The reason that the distance L1 and the length of the wavelength are approximated is also included in consideration of the bandwidth of the bandpass filter of the sound level meter. In the present embodiment, the distance L1 will be described. However, instead of the distance L1, a full width W1, which is an interval between two walls 23 and 24 facing each other in the short direction, may be used. Note that an odd multiple of 1 / 2n (n is a natural number) of the distance L1 is a distance inside the ceiling space 20, and therefore does not exceed the distance L1. This is the same when the distance L1 is set to the full width W1.

  Since the set frequency generally has a band by a band-pass filter, the processing can be simplified by directly calculating the distance A1 from the distance L1 of the ceiling floor 20 to obtain the positions A1 and A2. In order to estimate that the distance L1 coincides with the wavelength of the standing wave Sw that is considered to be generated on the ceiling floor 20, it is assumed that the distance L1 and the length of the set frequency match or approximate.

1-4. Installation Step S40: The installation step includes a sound absorbing material 40, 41 extending in at least one of the positions A1 and A2 determined in the position determination step (S30) in the width direction of the ceiling back 20 and the height direction of the ceiling back 20. Is installed. Even if there are a plurality of positions A1 and A2, there is an effect of reducing noise by installing the sound absorbing materials 40 and 41 at at least one position, and the sound absorbing materials 40 and 41 are installed at all of the plurality of positions A1 and A2. By doing so, a noise reduction effect can be obtained.

  As shown in FIGS. 6 and 7, two sound absorbing members 40 and 41 (shaded areas) can be installed at positions A1 and A2 of the ceiling space 20. The sound absorbing materials 40 and 41 have the same width and height as the total width W1 and the total height H3 of the ceiling space 20, and the thickness of the sound absorbing materials 40 and 41 can be, for example, 50 mm to 200 mm. The thickness of the sound absorbing materials 40 and 41 may be different depending on the material.

  The sound absorbing members 40 and 41 have a rectangular plate shape. A plurality of plate-shaped sound absorbing members 40 and 41 may be arranged in the lateral direction. By preparing a plurality of pairs of hanging bolts 50 and arranging them along the both sides of the sound absorbing materials 40 and 41 in the short direction of the ceiling space 20, the sound absorbing materials 40 and 41 are sandwiched and supported by the hanging bolts 50. Can be. The suspension bolts 50 are connected at both ends to the ceiling 15 and the upper floor 25. For example, the suspension bolts 50 may be suspended from the upper floor 25 to suspend the ceiling 15.

  According to the noise reduction method of the present embodiment, it is possible to efficiently reduce the noise from the ceiling space 20 in the measurement target room 10.

2. As shown in FIGS. 6 and 7, the ceiling-back structure 60 according to the present embodiment reduces the horizontal distance from one of the two opposing parallel walls 21 and 22 of the ceiling-back 20 to the other. Sound absorbing members 40 and 41 are provided at one or more positions A1 and A2 at odd multiples of 1/4 wavelength of the set frequency to be set, extending in the width direction of the ceiling back 20 and the height direction of the ceiling back 20. In the present embodiment, a case will be described in which the distance L1 and the wavelength of the set frequency match or approximate. However, when the total width W1 and the wavelength of the set frequency match or approximate, two walls in the short direction are used. 23 or 24.

  As shown in FIGS. 6 and 7, it is preferable to install the sound absorbing materials 40 and 41 at two places in order to obtain an excellent noise reduction effect. However, for example, only one sound absorbing material 40 can obtain the noise reducing effect. be able to.

  The sound absorbing materials 40 and 41 can be a structure including a porous sound absorbing material having air permeability. Examples of the porous sound-absorbing material having air permeability include fiber materials such as glass wool and rock wool, and foam materials using polymers such as urethane.

It is considered that the sound absorbing materials 40 and 41 preferably have a flow resistance of 10,000 Ns / m ⁴ and a thickness of 100 mm. When glass wool is used as the sound absorbing materials 40 and 41, for example, the thickness can be 32 kg / m ³ and the thickness can be 100 mm.

3. Above-the-ceiling structure according to the modified example The above-the-ceiling structure 60 according to the modified example is similar to the above-described second embodiment when the distance L1 between the opposing walls 21 and 22 of the ceiling 20 coincides with the wavelength of the standing wave Sw. Since this is the same as the above-the-back structure 60, description will be made with reference to FIGS.

  As shown in FIG. 5, when the wavelength of the standing wave Sw matches the distance L1, the positions of the horizontal distances L2 and L3 from the wall 21 to the wall 22 are positions of the antinode of the particle velocity of the standing wave Sw. The distance L2 matches the distance of １ ／ of the wavelength of the standing wave Sw from the wall 21, and the distance L3 matches the distance of ／ of the wavelength of the standing wave Sw from the wall 21.

  As shown in FIGS. 6 and 7, in the ceiling back structure 60 according to the modified example, the horizontal distances L2 and L3 from one of the parallel walls 21 and 22 facing the longitudinal direction of the ceiling back 20 to the other are the walls. At least one of the position A1 of 1/4 of the distance L1 and the position A2 of 3/4 of the distance L1 between the 21 and 22 has sound absorbing materials 40 and 41 extending in the width direction of the ceiling back 20 and the height direction of the ceiling back 20. May be. By doing so, the sound absorbing materials 40 and 41 provided on the ceiling back 20 can reduce noise from the ceiling back 20 into the measurement target room 10.

  The material and size of the sound absorbing members 40 and 41 may be the same as those of the underside structure 60 according to the embodiment.

The sound pressure level according to the frequency was measured in the measurement target chamber 10 having the shape shown in FIGS. 2 and 3 using a sound level meter. The measurement target chamber 10 had a total length (distance L1) × a total width W1 × a total height H1 of 6.6 m × 2.2 m × 2.51 m. The shape of the ceiling back 20 in plan view was the same as the room to be measured 10, and the total height was 1.3 m. The equipment 30 has been arranged in the ceiling 20. The sound level meter used was NA-28 manufactured by Rion with a 1/3 octave band filter function. The height H2 at the measurement position of the measurement target chamber 10 was 1.5 m. The measurement positions of the measurement target chamber 10 were 63 places at 0.5 m intervals in the horizontal plane. FIG. 8 shows the measurement results at the measurement positions Pt1 and Pt2 by the sound level meter. The horizontal axis in FIG. 8 is the center frequency (unit is Hz), and the vertical axis is the sound pressure level (unit is dB).

  In FIG. 8, the sound pressure level of 50 Hz was dominant at the measurement position Pt2. Based on the result of measurement by the sound level meter, it was expected that the noise in question was at a frequency of 50 Hz, and 50 Hz was set as a set frequency to be reduced.

  Further, a sound pressure distribution in a 50 Hz band was created from the measurement results by the sound level meter, and this is shown in FIG. FIG. 9 corresponds to a plan view of the measurement target chamber 10, and the left side of FIG. 9 corresponds to the wall 11 and the right side corresponds to the wall 12. There were measurement positions at sound pressure levels of 60 dB to 65 dB at positions 2 m and 5 m from the wall 11. The sound pressure level tended to be close along the width direction of the measurement target chamber 10.

  The sound pressure level at a set frequency of 50 Hz was measured using a sound level meter at a measurement position of a black square point in the longitudinal direction of the ceiling space 20 in FIG. This measurement result is shown in FIG. In FIG. 10, the horizontal axis represents the distance (unit: m) from the wall 21 of the ceiling space 20 to the measurement position, and the vertical axis represents the sound pressure level (unit: dB).

  From the measurement results of FIG. 10, the sound pressure level was the smallest at the measurement positions Pt3 and Pt4 (FIG. 4) 2 m and 5 m from the wall 21. That is, the particle velocity at the set frequency of 50 Hz was the maximum at the measurement positions Pt3 and Pt4 in the horizontal direction on the ceiling floor 20. In addition, since the wavelength at the set frequency of 50 Hz is 6.8 m, the horizontal distances L2 and L3 that are odd multiples of ８ of 6.8 m from the wall 21 to the wall 22 are 1.7 m and 5.1 m. Become. Since the distance L1 between the walls 21 and 22 was 6.6 m, when the distance L1 was divided into four equal parts, the distance L2 from the wall 21 was 1.65 m (6.6 / 4), and from the wall 21 Was 4.95 m (3 × 6.6 / 4).

The positions A1 and A2 shown in FIGS. 4 and 5 are set at 1.7 m and 5.1 m from the wall 21, and the positions A1 and A2 are in the width direction of the ceiling space 20 and the ceiling as shown in FIGS. Sound absorbing materials 40 and 41 extending in the height direction of the back 20 were provided. The sound absorbing materials 40 and 41 were arranged vertically using a glass wool having a thickness of 100 mm, 32 kg / m ³ and having a length of 2.2 m and a height of 1.3 m.

  After the installation of the sound absorbing materials 40 and 41, the sound pressure level was measured using a sound level meter at the measurement position in the second row from the wall 14 of the measurement target room 10. FIG. 11 shows the measurement result at the measurement position Pt2. The horizontal axis in FIG. 11 is the center frequency (unit: Hz), the vertical axis is the sound pressure level (unit: dB), the broken line is the measurement result before the sound absorbing materials 40 and 41 are installed, and the solid line is the sound absorbing level. It is a measurement result after constructing materials 40 and 41. FIG. 12 shows the measurement results at the measurement positions in the second row from the wall 14. The horizontal axis in FIG. 12 is the distance (unit: m) from the wall 11, the vertical axis is the sound pressure level (unit: Hz), and the broken lines are the measurement results before the sound absorbing materials 40 and 41 are installed. The solid line is the measurement result after the sound absorbing materials 40 and 41 are installed.

  According to FIG. 11, the sound pressure level after the construction was reduced by about 11 dB from that before the construction in the band of the center frequency of 50 Hz. According to FIG. 12, the sound pressure level in the band of the center frequency of 50 Hz after the construction is lower in the entire longitudinal direction of the measurement target chamber 10 than in the area before the construction.

The present invention is not limited to the embodiments described above, and various modifications are possible. For example, the invention includes substantially the same configuration as the configuration described in the embodiment (for example, a configuration having the same function, method, and result, or a configuration having the same object and effect). The invention also includes a configuration in which a non-essential part of the configuration described in the embodiment is replaced. Further, the invention includes a configuration having the same operational effects as the configuration described in the embodiment or a configuration capable of achieving the same object. Further, the invention includes a configuration obtained by adding a known technique to the configuration described in the embodiment.

  10 ... room to be measured, 11, 12, 13, 14 ... wall, 15 ... ceiling, 16 ... floor, 20 ... ceiling, 21, 22, 23, 24 ... wall, 25 ... floor, 30 ... equipment, 40, 41: sound absorbing material, 50: hanging bolts, 60: ceiling structure, A1, A2: position, B1, B2: belly, H1: total height, H2: height, H3: total height, H4: height, L1, L2 L3: distance, Pt1, Pt2, Pt3, Pt4: measurement position, Sw: standing wave, W1: full width

Claims (7)

Measure the sound pressure level according to the frequency in the room with a sound level meter,
Set a frequency to be reduced based on the measurement result by the sound level meter,
Find the position in the horizontal plane behind the ceiling where the particle velocity of the set frequency is the maximum,
A noise reduction method, comprising: installing a sound absorbing material extending in a width direction of the ceiling space and a height direction of the ceiling space in at least one of the positions. In claim 1,
Two parallel walls facing each other are arranged behind the ceiling,
A noise reduction method, wherein the position is obtained from the result of measuring the sound pressure level of the set frequency at a plurality of locations between the two walls by the sound level meter. In claim 1,
Two parallel walls facing each other are arranged behind the ceiling,
A noise reduction method, wherein the position is determined as a position at a distance which is an odd multiple of 1/4 of the wavelength of the set frequency from one of the two walls to the other. In claim 1,
Two parallel walls facing each other are arranged behind the ceiling,
Determining the position as an odd multiple of 1 / 2n (n is a natural number) of the distance from one side of the wall to the other when the distance between the two walls is close to the wavelength of the set frequency; A noise reduction method.   At least one of the positions where the horizontal distance from one of two opposing parallel walls on the ceiling to the other is an odd multiple of 1/4 of the wavelength of the set frequency to be reduced, A ceiling back structure comprising a sound absorbing material extending in a width direction and a height direction of the ceiling back.   At least one of the positions at which the horizontal distance from one of two opposing parallel walls behind the ceiling to the other is an odd multiple of 1 / 2n (n is a natural number) of the distance between the two walls. A ceiling space structure, characterized by having a sound absorbing material extending in the width direction of the space above the ceiling and in the height direction of the space above the ceiling. In claim 5 or claim 6,
The under-the-ceiling structure, wherein the sound absorbing material is a structure including a porous sound absorbing material having air permeability.