JP2017111216A - Soundproof device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce a sound issued from a noise source by a diffraction phenomenon and further reduce it.SOLUTION: A soundproof device 10 includes: a support member 11; a first soundproof material 21 and second soundproof material 22 that are supported by the support member 11 so that they face each other with respect to the support member 11; and a plurality of cylindrical bottomed acoustic tubes 31-34 supported by the support member 11 so that they are disposed between an upper part of the first soundproof material 21 and an upper part of the second soundproof material 22. The openings of the acoustic tubes 31-34 are directed upward.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a soundproofing device arranged between a noise area and a quiet area.

  Patent Document 1 discloses a technique in which a sound insulating material is attached to both side surfaces of a scaffold, and sound generated from a noise source is sound-insulated by the sound insulating material.

JP 2014-77315 A

  However, in the technique described in Patent Document 1, the sound emitted from the noise source wraps around the scaffold and the sound insulating material due to the diffraction phenomenon, and the sound reaches the opposite side of the noise source with respect to the scaffold. It is difficult to obtain an effect.

  The present invention has been made in view of the above circumstances. The problem to be solved by the present invention is to attenuate the sound coming from a noise source and wrapping up.

  In order to solve the above problems, a soundproofing device includes a support member, a first soundproof material and a second soundproof material supported by the support member so as to face each other with the support member interposed therebetween, and the first A plurality of bottomed cylindrical acoustic tubes supported by the support member so as to be disposed between an upper portion of the sound insulating material and an upper portion of the second sound insulating material, and the opening of the acoustic tube faces upward It has been.

  Since the opening of the acoustic tube provided between the upper part of the first soundproofing material and the upper part of the second soundproofing material is directed upward, the top of the first soundproofing material and the second soundproofing material are emitted from the noise source. The sound propagated to the sound enters the opening of the acoustic tube. The sound is reflected by the bottom of the acoustic tube, and the reflected sound is emitted from the opening of the acoustic tube. Here, for a sound having a wavelength about four times the length of the acoustic tube, the incident sound and the reflected sound in the vicinity of the opening of the acoustic tube have opposite phases. Therefore, a component having a wavelength that is about four times the length of the acoustic tube out of the sound that passes near the opening of the acoustic tube is interfered by the reflected sound. Therefore, the sound that is emitted from the noise source and goes around the first soundproof material and the second soundproof material is attenuated by interference in addition to the attenuation due to the diffraction phenomenon.

  According to the present invention, the sound emitted from the noise source and wrapping around the first soundproof material and the second soundproof material is attenuated by the diffraction phenomenon and also attenuated by interference. This improves the soundproofing effect.

FIG. 1 is a front view of the soundproofing device. FIG. 2 is a plan view of the soundproofing device. FIG. 3 is a graph showing frequency characteristics when an acoustic tube is installed and frequency characteristics when no acoustic tube is installed. FIG. 4 is a front view of a modified soundproof device. FIG. 5 is a front view of a modified soundproof device. FIG. 6 is a front view of a modified soundproof device. FIG. 7 is a graph showing the difference between the frequency characteristic when the acoustic tube is installed and the frequency characteristic when the acoustic tube is not installed. FIG. 8 is a graph showing the difference between the frequency characteristic when the acoustic tube is installed and the frequency characteristic when the acoustic tube is not installed. FIG. 9 is a graph showing the difference between the frequency characteristic when the acoustic tube is installed and the frequency characteristic when the acoustic tube is not installed. FIG. 10 is a graph showing the difference between the frequency characteristic when the acoustic tube is installed and the frequency characteristic when the acoustic tube is not installed.

  Embodiments of the present invention will be described below with reference to the drawings. However, the embodiments described below are provided with various technically preferable limitations for carrying out the present invention, and the scope of the present invention is not limited to the following embodiments and illustrated examples.

FIG. 1 is a front view of the soundproofing device 10, and FIG. 2 is a plan view of the soundproofing device 10.
The soundproofing device 10 includes a support member 11, a first soundproofing material 21, a second soundproofing material 23, and a plurality of acoustic tubes 31 to 34.

  The support member 11 is a frame scaffold constructed by assembling a building frame, bracing, a footboard, and a handrail. The support member 11 is erected between a noise area (for example, a construction site, a construction site, a motorway) and a silent area (for example, a residential area, a walking path), and the noise area and the silent area are supported by the support member 11. It is partitioned by.

  A first soundproof material 21 is attached to the side surface of the support member 11 on the noise area side by a bracket 22. A second soundproof material 23 is attached to the side surface of the support member 11 on the quiet area side by a bracket 24. Therefore, the soundproof materials 21 and 23 are supported in a standing state by being attached to the support member 11, and are disposed to face each other with a space between the soundproof materials 21 and 23. These soundproof materials 21 and 23 are made of universal steel plates. In addition to the universal steel plate, a soundproof panel, a soundproof sheet, a concrete plate, and other materials having a soundproofing effect may be used for the soundproof materials 21 and 23.

  The sound emitted from the noise source located below the upper ends of the soundproof materials 21 and 23 in the noise area is attenuated by the soundproof materials 21 and 23 when passing through the soundproof materials 21 and 23. Therefore, when the sound pressure (intensity) of the sound transmitted through the soundproof materials 21 and 23 is reduced, noise due to the transmitted sound is suppressed at a position below the upper ends of the soundproof materials 21 and 23 in the silent area. be able to.

  The sound emitted from the noise source located below the upper ends of the soundproof materials 21 and 23 in the noise area is diffracted above the upper ends of the soundproof materials 21 and 23, and the upper ends of the soundproof materials 21 and 23 in the silent area. Propagate to a position below. Since the sound is attenuated by the diffraction, noise caused by the diffracted sound can be suppressed at a position below the upper ends of the soundproof materials 21 and 23 in the silent area. Furthermore, in this embodiment, since the predetermined frequency component of the sound propagating from the upper end of the first soundproof material 21 toward the upper end of the second soundproof material 23 is attenuated by the acoustic tubes 31 to 34 described later, this is caused by the diffracted sound. Noise can be suppressed more efficiently.

Acoustic tubes 31 to 34 are arranged between the upper part of the first soundproof material 21 and the upper part of the second soundproof material 23. These acoustic tubes 31 to 34 are attached to the upper portion of the support member 11 by brackets so that the respective central axes extend in the vertical direction. The lower ends of the acoustic tubes 31 to 34 are closed by a bottom plate, and the upper ends of the acoustic tubes 31 to 34 are opened. The upper ends of the acoustic tubes 31 to 34 are aligned with the upper ends of the soundproof materials 21 and 23.
The acoustic tubes 31 to 34 are larger in diameter and length in the order of the acoustic tube 31, the acoustic tube 32, the acoustic tube 33, and the acoustic tube 34.
The acoustic tube 31 has a length larger than the diameter. The same applies to the acoustic tubes 32-34.

As shown in FIG. 2, these acoustic tubes 31 to 34 are two-dimensionally arranged as viewed from above. Here, the plurality of acoustic tubes 31 having the same diameter and length are arranged in a row in the horizontal direction along the first soundproof material 21, and the adjacent ones are in contact with each other. The acoustic tubes 32 to 34 are similarly arranged. Further, from the first soundproofing material 21 to the second soundproofing material 23, the acoustic tube 31, the acoustic tube 32, the acoustic tube 33, and the acoustic tube 34 are arranged in this order.
The acoustic tubes 31 to 34 are not limited to the cylindrical shape as shown in FIG. 2, and may have other shapes (for example, a rectangular tube shape). When the acoustic tubes 31 to 34 are rectangular cylinders, the length of the acoustic tubes 31 to 34 is larger than the side length in the horizontal section.

  A part of the sound propagating above the acoustic tubes 31 to 34 from the first sound insulating material 21 toward the second sound insulating material 23 enters the acoustic tube 31 and is reflected by the bottom of the acoustic tube 31. Here, for a sound having a wavelength about four times the length of the acoustic tube 31, the phase of the incident sound and the phase of the reflected sound are shifted by 180 °. Therefore, the frequency component having a wavelength about four times the length of the acoustic tube 31 out of the sound propagating above the acoustic tubes 31 to 34 from the first acoustic material 21 to the second acoustic material 23 is It is canceled out by interference of reflected sound from the bottom. Similarly, in the acoustic tubes 32 to 34, the frequency component having a wavelength about four times the length of each of the acoustic tubes 32 to 34 is canceled by interference. Therefore, it is possible to suppress noise generated in the silent area due to diffracted sound (particularly, a frequency component having a wavelength approximately four times the length of the acoustic tubes 31 to 34).

The frequency of the sound canceled by the acoustic tubes 31 to 34 is determined as follows.
First, a noise source (for example, a general noise source at a construction site) is arranged below the upper ends of the soundproof materials 21 and 23 in the noise area, and the sound is received below the upper ends of the soundproof materials 21 and 23 in the silent area. When the sound is emitted from the noise source when the points are arranged and the acoustic tubes 31 to 34 are not installed, the frequency characteristic of the sound at the sound receiving point (distribution representing the A characteristic sound pressure level for each frequency) Obtain by calculation or experiment. A curve C1 illustrated in FIG. 3 represents an example of a frequency characteristic of sound at a sound receiving point when the acoustic tubes 31 to 34 are not installed. A curve C2 represents a frequency characteristic of sound at a sound receiving point when the acoustic tubes 31 to 34 are installed. In FIG. 3, the vertical axis represents the A characteristic sound pressure level, and the horizontal axis represents the frequency. Further, the A characteristic sound pressure level when the horizontal axis of FIG. 3 is “A” is an energy composite value of the A characteristic sound pressure level in the entire frequency band.
Then, the maximum value of the A characteristic sound pressure level is specified from the acquired frequency characteristic, and the frequency (hereinafter referred to as peak frequency) that takes the maximum value of the A characteristic sound pressure level is specified. In FIG. 3, Lp [dB] is the maximum value of the A characteristic sound pressure level, and f1 [Hz] is the peak frequency. Here, assuming that the sound speed of air is V [m / s], the wavelength λ1 [m] of the sound having the peak frequency f1 is V / f1.
Also, among the frequency characteristics, the frequency of the sound having an A characteristic sound pressure level 15 [dB] lower than the maximum value of the A characteristic sound pressure level (however, lower than the peak frequency; hereinafter referred to as the lower limit frequency) is specified. To do. In FIG. 3, Lu [dB] is an A characteristic sound pressure level 15 [dB] lower than the maximum value Lp [dB] of the A characteristic sound pressure level, and f2 [Hz] is a lower limit frequency. Here, if the sound speed of air is V [m / s], the wavelength λ2 [m] of the sound having the lower limit frequency f2 is V / f2.
And the frequency of the sound canceled by the acoustic tubes 31 to 34 is not less than the specified lower limit frequency. That is, the length of the acoustic tubes 31 to 34 is not more than 1/4 times the product of the reciprocal of the lower limit frequency and the sound speed.

  Even if a sound having a frequency lower than the lower limit frequency cannot be canceled by the acoustic tubes 31 to 34, such a sound hardly affects the noise in the silent area. This is because the increase that the A characteristic sound pressure level Lu [dB] gives to the energy composite value of the A characteristic sound pressure level is 0.135 [dB] from the following equation (1), and therefore the maximum value of the A characteristic sound pressure level. This is because an A characteristic sound pressure level that is 15 [dB] lower than Lp [dB], that is, an A characteristic sound pressure level lower than the A characteristic sound pressure level Lu does not affect the energy composite value of the A characteristic sound pressure level. is there. The synthesis of L1 [dB], L2 [dB], L3 [dB]... Is expressed by the following equation (2) (reference: Sho Kimura, “2.6 Synthesis of decibels”. Architectural acoustics and noise prevention plan. 3rd edition, Shokokusha, 1999, p.17-18, (New Architecture Technology Series-9)), and formula (2), the synthesis of L1 [dB] and L2 [dB] is next Since it is expressed by equation (3), equation (1) is obtained from equation (3).

An example of specific specifications of the acoustic tubes 31 to 34 is given below (hereinafter, the sound velocity of air is about 340 [m / s]).
The acoustic tube 31 has a diameter of 0.30 [m] and a length of 0.34 [m]. The sound component causing interference by the acoustic tube 31 has a wavelength of 1.36 [m] and a frequency of 250 [Hz].
The acoustic tube 32 has a diameter of 0.25 [m] and a length of 0.27 [m]. The sound component that causes interference by the acoustic tube 32 has a wavelength of 1.08 [m] and a frequency of 315 [Hz].
The acoustic tube 33 has a diameter of 0.20 [m] and a length of 0.21 [m]. The sound component that causes interference by the acoustic tube 33 has a wavelength of 0.84 [m] and a frequency of 400 [Hz].
The acoustic tube 34 has a diameter of 0.15 [m] and a length of 0.17 [m]. The sound component causing interference by the acoustic tube 34 has a wavelength of 0.68 [m] and a frequency of 500 [Hz].

The frequency of the sound canceled by the acoustic tubes 31 to 34 is 1/3 octave. That is, the frequency of the sound is canceled by the sound tube 32 is 2 ^1/3 times the frequency of the sound is canceled by the acoustic pipe 31, the same applies to the frequency of the sound is canceled by the acoustic tubes 33 and 34, sound tube 32, This is 2 ^1/3 times the frequency of the sound canceled by 33.

  As mentioned above, although the form for implementing this invention was demonstrated, the said embodiment is for making an understanding of this invention easy, and is not for limiting and interpreting this invention. The present invention can be changed and improved without departing from the gist thereof, and equivalents thereof are also included in the present invention. Changes from the above embodiment will be described below. The changes described below may be applied in combination as much as possible.

(1) In the said embodiment, the diameter and length of the acoustic tubes 31-34 are long in order of the acoustic tube 31, the acoustic tube 32, the acoustic tube 33, the acoustic tube 34, and the acoustic tube 34. On the other hand, as shown in FIG. 4 or FIG. 5, the acoustic tubes 31 to 34 may be longer in diameter and length in the order of the acoustic tube 34, the acoustic tube 33, the acoustic tube 32, and the acoustic tube 31. In addition, as shown in FIG. 4, the upper ends of the acoustic tubes 31 to 34 are aligned.

(2) In the above embodiment, the upper ends of the acoustic tubes 31 to 34 are aligned. On the other hand, as shown in FIG. 5 or 6, the lower ends of the acoustic tubes 31 to 34 may be aligned.

(3) In the above embodiment, the upper ends of the acoustic tubes 31 are aligned with the upper ends of the soundproof materials 21 and 23. On the other hand, the upper end of the acoustic tube 31 may be shifted upward or downward from the upper ends of the soundproof materials 21 and 23. The same applies to the upper ends of the acoustic tubes 32 to 34.

(4) In the said embodiment, the acoustic tubes 31-34 were empty. On the other hand, you may adjust the substantial length of the acoustic tubes 31-34 by storing a fluid (for example, water) in the bottom of the acoustic tubes 31-34. The substantial length of the acoustic tubes 31 to 34 refers to the distance from the fluid level to the upper end of the acoustic tubes 31 to 34, which corresponds to ¼ of the wavelength of sound that can be canceled by the acoustic tubes 31 to 34. To do. In addition, by making the lengths of the acoustic tubes 31 to 34 equal and storing a fluid (for example, water) at the bottom of the acoustic tubes 31 to 34, the substantial length of the acoustic tubes 31 to 34 is reduced to the acoustic tube 31. The acoustic tube 32, the acoustic tube 33, and the acoustic tube 34 may be increased in the order (or the reverse order). Further, by making the lengths of the acoustic tubes 31 to 34 equal and storing fluid (for example, water) at the bottom of the acoustic tubes 31 to 34, the substantial length of the acoustic tubes 31 to 34 is the lower limit frequency. You may make it become 1/4 times or less of the product of a reciprocal number and a sound speed.

<Verification>
The effect of sound interference by the acoustic tubes 31 to 34 was verified by calculation.
7 shows the sound pressure level between the frequency characteristic (calculation result) when the acoustic tubes 31 to 34 are installed as shown in FIG. 1 and the frequency characteristic (calculation result) when the acoustic tubes 31 to 34 are not installed. It shows the difference.
FIG. 8 shows the sound pressure level between the frequency characteristics (calculation results) when the acoustic tubes 31 to 34 are installed as shown in FIG. 4 and the frequency characteristics (calculation results) when the acoustic tubes 31 to 34 are not installed. It shows the difference.
9 shows the sound pressure level between the frequency characteristics (calculation results) when the acoustic tubes 31 to 34 are installed as shown in FIG. 5 and the frequency characteristics (calculation results) when the acoustic tubes 31 to 34 are not installed. It shows the difference.
FIG. 10 shows the sound pressure level between the frequency characteristic (calculation result) when the acoustic tubes 31 to 34 are installed as shown in FIG. 6 and the frequency characteristic (calculation result) when the acoustic tubes 31 to 34 are not installed. It shows the difference.

  Here, the frequency characteristic assumes that the noise source is in a position below the upper ends of the soundproof materials 21 and 23 in the noise area, and is lower than the upper ends of the soundproof materials 21 and 23 in the silent area. Assuming that a sound receiving point is installed at a position, this is a frequency characteristic of sound incident on the sound receiving point. 7 to 10, the vertical axis represents the sound pressure level difference, and the horizontal axis represents the frequency. When the sound pressure level difference is negative, the A characteristic sound pressure level when the acoustic tubes 31 to 34 are installed is lower than the A characteristic sound pressure level when the acoustic tubes 31 to 34 are not installed. Represents. In addition, the sound pressure level difference when the horizontal axis of the figure is “A” is the energy composite value of the A characteristic sound pressure level in the entire frequency band when the acoustic tubes 31 to 34 are installed, and the acoustic tubes 31 to 34. It is the difference from the energy composite value of the A characteristic sound pressure level in the entire frequency band when not installed.

7 to 10, it can be seen that there is a frequency component in which the sound pressure level difference is negative. In particular, since the sound pressure level difference when the horizontal axis in FIGS. 7 to 10 is “A” is negative, the energy composite value of the A characteristic sound pressure level in the entire frequency band when the acoustic tubes 31 to 34 are installed. Is smaller than the energy composite value of the A characteristic sound pressure level in the entire frequency band when the acoustic tubes 31 to 34 are not installed. Therefore, it can be seen that the soundproofing effect is higher when the acoustic tubes 31 to 34 are installed than when the acoustic tubes 31 to 34 are not installed.
Further, there is a frequency component (near 125 [Hz]) in which the A characteristic sound pressure level is higher when the acoustic tubes 31 to 34 are installed than when the acoustic tubes 31 to 34 are not installed ( Hereinafter, this phenomenon is referred to as a rebound phenomenon), and the A characteristic sound pressure level of the frequency component hardly affects the energy composite value of the A characteristic sound pressure level of the entire frequency band, and the sound of the frequency component is loud. The influence on the thickness can be almost ignored. This is from the A characteristic sound pressure level of the frequency component where the rebound phenomenon occurs (when the acoustic tubes 31 to 34 are installed) to the A characteristic sound pressure level of the frequency component (when the acoustic tubes 31 to 34 are not installed). Sound pressure level difference (in the case of FIG. 7, about 3-5 [dB] near 125 [Hz]) is rebounded from the maximum value of A-weighted sound pressure level (when acoustic tubes 31-34 are not installed) The rebound phenomenon is smaller than the sound pressure level difference (approximately 13 [dB] referring to FIG. 3) up to the A characteristic sound pressure level of the frequency component where the phenomenon occurs (when the acoustic tubes 31 to 34 are not installed). This is because the increase in the A-weighted sound pressure level due to can be almost ignored. That is, this is because the sound pressure level difference between the frequency components in which the rebound phenomenon occurs hardly contributes to the energy composite value of the A characteristic sound pressure level.

The specific specifications of the acoustic tubes 31 to 34 shown in FIGS. 1 and 6 are as follows (however, the sound velocity of air is about 340 [m / s]), and the graphs of FIGS. 7 and 10 are used. Acquired.
The acoustic tube 31 has a diameter of 0.30 [m] and a length of 0.34 [m]. The sound component causing interference by the acoustic tube 31 has a wavelength of 1.36 [m] and a frequency of 250 [Hz]. The acoustic tube 32 has a diameter of 0.25 [m] and a length of 0.27 [m]. The sound component that causes interference by the acoustic tube 32 has a wavelength of 1.08 [m] and a frequency of 315 [Hz]. The acoustic tube 33 has a diameter of 0.20 [m] and a length of 0.21 [m]. The sound component that causes interference by the acoustic tube 33 has a wavelength of 0.84 [m] and a frequency of 400 [Hz]. The acoustic tube 34 has a diameter of 0.15 [m] and a length of 0.17 [m]. The sound component causing interference by the acoustic tube 34 has a wavelength of 0.68 [m] and a frequency of 500 [Hz].

  Further, the specific specifications of the acoustic tubes 31, 32, 33, 34 shown in FIGS. 4 and 5 are the same as the specifications of the acoustic tubes 34, 33, 32, 31 shown in FIGS. 1 and 6, respectively (however, The sound velocity of air is about 340 [m / s]), and the graphs of FIGS. 8 and 9 were obtained.

  DESCRIPTION OF SYMBOLS 10,10A, 10B, 10C, 10D ... Soundproofing device, 11 ... Supporting member, 21 ... First soundproofing material, 23 ... Second soundproofing material, 31-34 ... Sound tube

Claims (6)

A support member;
A first soundproof material and a second soundproof material supported by the support member so as to face each other across the support member;
A plurality of bottomed cylindrical acoustic tubes supported by the support member so as to be disposed between the upper part of the first soundproofing material and the upper part of the second soundproofing material,
The soundproofing device, wherein an opening of the acoustic tube is directed upward.   2. The soundproofing device according to claim 1, wherein the acoustic tubes are arranged in order of length from one to the other of the first soundproofing material and the second soundproofing material.   The length of the acoustic tube is equal to or less than 1/4 times the product of the reciprocal of the lower limit frequency and the sound velocity (where the lower limit frequency is the noise on the first soundproofing material side when the acoustic tube is not installed). Among the frequency characteristics representing the A characteristic sound pressure level for each frequency of the received sound when the noise emitted from the source is received at the sound receiving point on the second soundproofing material side, the A characteristic sound pressure level 3. The soundproofing device according to claim 1 or 2, wherein the frequency of a component having an A-weighted sound pressure level lower by a predetermined decibel than the maximum value of.   The soundproofing device according to claim 1, wherein a stored matter is stored at a bottom of the acoustic tube.   The acoustic tube is arranged in order of increasing distance from the surface of the reservoir to the upper end of the acoustic tube from one to the other of the first soundproof material and the second soundproof material. The soundproofing device according to claim 4.   The distance from the surface of the reservoir to the upper end of the acoustic tube is not more than 1/4 times the product of the reciprocal of the lower limit frequency and the sound velocity (where the lower limit frequency is when the acoustic tube is not installed, A frequency characteristic representing the A characteristic sound pressure level for each frequency of the received sound when the noise generated from the noise source on the first sound insulating material side is received at the sound receiving point on the second sound insulating material side. 6. The soundproofing device according to claim 4, wherein a frequency of a component having an A characteristic sound pressure level that is a predetermined decibel lower than a maximum value of the A characteristic sound pressure level.

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