JPH08246421A - Resonator type soundproof panel - Google Patents

Abstract

PURPOSE: To improve a sound absorbing coefficient, and to enhance sound- absorbing performance by attaching a second resonator absorbing a sound in frequency different from a first resonator absorbing a sound in aimed frequency to a panel having a hollow section and a slit on the inside. CONSTITUTION: First resonators 13 absorbing a sound in aimed frequency X(Hz) are juxtaposed to a resonator type soundproof panel 11 at regular intervals. Second resonators 15 absorbing a sound in frequency X+α<(Hz) different from aimed frequency X are disposed among the mutual first resonators 13. That is, the first resonators 13 absorbing the sound in aimed frequency X(Hz) and the second resonators 15 absorbing the sound in frequency X+α(Hz) higher than the frequency X are juxtaposed and combined alternately at regular pitches, thus integrating a sound-absorbing effect for damping lower resonance frequency. Accordingly, the maximum value of the sound-absorbing effect is conformed to the aimed frequency X(Hz), thus remarkably increasing the sound absorbing coefficient of frequency X(Hz).

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a resonator type soundproof panel having a sound absorbing effect, and is particularly suitable for use as a sound insulating wall for railways, roads, factories and the like.

[0002]

2. Description of the Related Art Various types of soundproof panels utilizing a sound absorbing effect are known. For example, there are a plate-shaped body such as a slate having a large number of holes formed therein, and a metal hollow perforated panel filled with a sound absorbing material such as rock wool. However, in the case of using a slate or the like, the sound absorbing effect is obtained by combining a plurality of sound absorbing bodies, so that there is a problem that the construction is troublesome. Also, in the case of filling with sound absorbing material, the sound absorbing material absorbs moisture due to rain etc.
When water is absorbed, there is a drawback that the sound absorption coefficient is remarkably lowered especially in the high sound range.

In order to solve such inconvenience, a so-called resonator type soundproof panel has been proposed which does not require a combination of sound absorbers and does not need to be filled with a sound absorbing material. As an example of this type of resonator type soundproof panel having a resonator having a hollow portion and a slit, for example, the one disclosed in Japanese Patent Laid-Open No. 58-117158 will be described with reference to FIGS. FIG. 3 is a perspective view of a conventional resonator type soundproof panel, and FIG. 4 is a diagram for explaining the dimensional relationship of the resonator. In the resonator type soundproof panel in this conventional example,
The hollow portion 3 of the panel 1 is opened to the panel outer surface 1a through the slit 5, and the hollow portion 3 and the slit 5 allow
A so-called Helmholtz resonator (resonator) that absorbs sound energy of a specific frequency by resonance and attenuates it.
Make up 7. The hollow portion 3 is closed by some means at the upper and lower ends of the panel 1 and set to a specific volume.

In such a configuration, the resonance frequency f of the resonator 7 is

## EQU1 ## f [Hz] = (c / 2π) × √ (s / (v × (t + δ)) ... given by Equation 1. Here, c: sound velocity s: opening end cross-sectional area (h × d) v: hollow portion volume t: plate thickness of slit portion, that is, distance that sound passes through slit δ: correction term.

Therefore, the panel 1 resonates with the sound of the frequency f calculated by the above-mentioned formula 1 by appropriately setting the opening end cross-sectional area s, the hollow volume v, and the sound passage distance t in the slit. , It functions as a Helmholtz resonator that absorbs this, and a sound absorbing effect in a desired frequency band can be obtained.

[0006]

In the conventional resonator type soundproof panel using the above-mentioned Helmholtz principle, when it is desired to absorb a sound of a target frequency, a single resonator having the same resonance frequency f is arranged. When installed, it absorbs sound energy and attenuates it to absorb sound. However, theoretically, 100% of sound can be absorbed by the above-mentioned principle, but in reality, a soundproof panel provided with only a single resonator that matches the target frequency can obtain a sufficient sound absorbing effect. I couldn't. Here, the result of the experiment conducted by the inventor is shown in FIG.
In the soundproof panel in which a single resonator having a resonance frequency f = X [Hz] that matches the target frequency X [Hz] is installed in parallel, the sound absorption coefficient at X [Hz] is 54%. It has been found that the sound absorption coefficient can be increased only to a certain degree, and the sound absorption coefficient becomes maximum (63%) at a frequency W [Hz] lower than X [Hz]. On the other hand, in various uses of the soundproof panel, it is generally 80 to 90.
If the sound absorption coefficient of% is not obtained, the purpose cannot be sufficiently achieved. Therefore, further improvement of sound absorption performance has been a major issue. The present invention has been made in view of the above situation, and can increase the sound absorption coefficient,
It is an object of the present invention to provide a resonator type soundproof panel capable of absorbing sound with high efficiency by matching the maximum value of the sound absorption coefficient to a target frequency, and to improve sound absorbing performance.

[0007]

The structure of a resonator type soundproof panel according to the present invention for achieving the above object has a resonator having a hollow portion inside the panel and a slit for communicating the hollow portion with the outside. The resonator type soundproof panel is characterized in that the panel is provided with a first resonator that absorbs a sound of a target frequency and a second resonator that absorbs a sound of a different frequency.
The second resonator is preferably a resonator that absorbs a sound with a frequency higher than the target frequency sound. Further, the structure of the resonator type soundproof panel is such that the first resonator and the second resonator are alternately arranged in parallel, and the first resonators and the second resonators are 1/4 of a wavelength corresponding to each frequency. It is preferable to arrange at a pitch within the length of.

[0008]

When the first resonator which absorbs the sound of the target frequency and the second resonator which absorbs the sound higher than the target frequency are alternately arranged in parallel at a predetermined interval, the lower resonance frequency, that is, the target The sound absorbing effect is integrated so as to attenuate the sound of the frequency to be absorbed, and the sound absorbing coefficient is cumulatively increased.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A preferred embodiment of a resonator type soundproof panel according to the present invention will be described in detail below with reference to the drawings. FIG.
FIG. 2 is a sectional view of a resonator type soundproof panel according to the present invention. The same members or parts as those shown in FIG. 3 are designated by the same reference numerals, and overlapping description will be omitted. The resonator type soundproof panel 11 has a desired frequency X [H
z] (60 Hz to 4000 Hz arbitrary specific frequency), first resonators 13 that absorb sound are arranged in parallel at a predetermined interval, and the first resonator 13 has a resonance frequency f of X [Hz] in FIG. The opening end sectional area s, the hollow volume v, and the sound passing distance t in the slit are set. Further, between the first resonators 13 is provided a second resonator 15 that absorbs a sound of a frequency X + α [Hz] (where α is a positive number) different from the target frequency X [Hz],
The second resonator 15 has an opening end sectional area s, a hollow volume v, and a sound passage distance t in the slit so that the resonance frequency f becomes X + α [Hz]. Therefore, the first resonator 13 and the second resonator 15 are alternately arranged at a predetermined pitch.

The different frequency X + α [Hz] described above is
Predetermined frequency α [Hz] to the target frequency X [Hz]
Is added. That is, the resonator type soundproof panel 1
The first resonator 13 is a combination of a first resonator 13 that absorbs a target frequency X [Hz] and a second resonator 15 that absorbs a higher sound. Further, in the present embodiment, the value of the predetermined frequency α [Hz] is ⅓ of X [Hz].
It is an octave. This is a value found from the results of experiments conducted by the inventor, which will be described later, that the sound absorbing effect of the resonator type soundproof panel 11 is the best. That is, the resonator type soundproof panel 11 includes a first resonator 13 that absorbs a target frequency X [Hz] and
It is combined with the second resonator 15 that absorbs the sound above / 3 octave.

Further, the resonator has predetermined pitches P1 and P.
It was found from the results of experiments conducted by the inventor that the parallel arrangement within 2 results in high efficiency, and the value is within 1/4 of each wavelength λ. Therefore, when alternately arranging the first resonator 13 and the second resonator 15 in parallel, for example, the second resonator 15 having a short wavelength is used as a reference, and the parallel pitch P2 is set at a length of ¼ of the wavelength λ. By designing and providing the first resonator 13 between them, the first resonator 13 having a long wavelength inevitably satisfies the juxtaposed pitch P1 within ¼ of the wavelength λ.

The resonator type soundproof panel 11 is, for example,
Manufactured as an extruded cement board. The extrusion-molded cement plate can easily be molded into a hollow cross-sectional shape, and can be formed into the same quality and with high accuracy as an integral molding. Furthermore, by exchanging the extrusion molding die, various cross-sectional shapes can be accommodated.
As a result, it is possible to easily mix the first resonator 13 that absorbs the sound of the target frequency and the second resonator 15 that absorbs the sound of the different frequency in one extruded cement board. As the method for forming the slits 5, the slits 5 may be formed at the same time as extrusion, or may be formed by cutting after molding (after primary curing or after AC), punching, water jet and the like. .

Further, the panel can be hollowed in one step only in the resonator part, or multi-stepped hollow if strength is required, and in order to prevent scattering when shock is applied,
It is also possible to insert the wire 17 and the reinforcing bar at the time of manufacturing. As a material, an inorganic material such as cement is used as a main raw material. In addition, the frequency band that can be absorbed and attenuated is
Although it can be dealt with by changing the shape of the resonator, 60 Hz to 4000 Hz is optimal in terms of manufacturing and accuracy.

The operation of the resonator type soundproof panel 11 thus constructed will be described based on the result obtained by the experiment conducted by the inventor. FIG. 2 is a graph showing the sound absorption coefficient of this example obtained by an experiment. As a sound absorption test body, a panel A in which a single first resonator 13 which absorbs a sound of a target frequency X [Hz] is arranged in parallel at a predetermined interval is used to absorb a sound higher than the target frequency X [Hz]. Panel B in which a single second resonator 15 is arranged in parallel at a predetermined interval A panel C of this embodiment, in which the first resonator 13 and the second resonator 15 are alternately arranged in parallel at a predetermined interval, was used. In addition,
In the figure, panel A is shown by a broken line with a circle, panel B is shown by a broken line with a triangle, and panel C is shown by a broken line with a circle. Further, the test method conforms to the reverberation room method (JIS A 1414), and the test conditions are: test room: reverberation room (164 m ² ) sample area: 3 m ² (1.5 × 2).

From the test results shown in FIG. 2, in the panel A in which the first resonator 13 which absorbs the sound of the target frequency X [Hz] is arranged in parallel, the sound absorption coefficient at X [Hz] is 54%. Can only be increased to a certain degree, and
The sound absorption efficiency becomes maximum (63%) at the frequency W [Hz] lower than X [Hz]. Further, in the panel B in which the second resonators 15 that absorb sounds higher than the frequency X [Hz] are arranged in parallel at a single predetermined interval, the sound absorption efficiency becomes maximum at X [Hz], but the value is 53%. And small.

On the other hand, in the panel C corresponding to this embodiment in which the first resonator 13 and the second resonator 15 are alternately arranged in parallel at a predetermined interval, the sound absorption efficiency becomes maximum at X [Hz], and the value is It increased remarkably to 88%. That is, in the case of the panel C in which the first resonator 13 and the second resonator 15 are arranged side by side, the lower resonance frequency, that is, X [Hz].
The sound absorption effect is integrated to attenuate the.

According to the above-mentioned resonator type soundproof panel 11, the first resonator 13 which absorbs the sound of the target frequency X [Hz] and the second resonator 15 which absorbs the sound of the higher frequency X + α [Hz]. By combining and, the sound absorption effect is integrated so as to attenuate the lower resonance frequency, and as a result, the maximum value of the sound absorption effect matches the target frequency X [Hz], The sound absorption coefficient can be remarkably increased.

In the above embodiment, the frequency α is X.
Although it has been described as an example in which it is 1/3 octave of [Hz] and the pitch is within 1/4 of the wavelength λ, the resonator type soundproof panel is not manufactured by these exact numerical values, and It suffices that the manufacturing is performed with an allowable error (measurement error, manufacturing error) within a range not departing from the spirit of the invention. However, when the target frequency was, for example, 1000 Hz, it was found by experiments by the inventor that when the resonators that absorb the sounds of 1000 Hz and 2000 Hz are combined, the above-described sound absorbing effect is not accumulated. ing.

[0019]

As described above in detail, according to the resonator type soundproof panel of the present invention, the first resonator for absorbing the sound of the target frequency and the second resonator for absorbing the sound of the higher frequency than this. By arranging the resonator and the resonator at a predetermined pitch, the sound absorption effect was integrated to attenuate the lower resonance frequency.Therefore, the maximum value of the sound absorption effect matches the target frequency and The sound absorption coefficient of the frequency can be significantly increased. As a result, highly efficient sound absorption can be performed, and the sound absorption performance can be significantly improved.

[Brief description of drawings]

FIG. 1 is a cross-sectional view of a resonator type soundproof panel according to the present invention.

FIG. 2 is a graph showing the sound absorption coefficient of this example obtained by an experiment.

FIG. 3 is a perspective view of a conventional resonator type soundproof panel.

FIG. 4 is a diagram illustrating a dimensional relationship of a resonator.

FIG. 5 is a graph showing a sound absorption coefficient of a conventional soundproof panel provided with only a single resonator.

[Explanation of symbols]

 3 Hollow part 5 Slit 11 Resonator type soundproof panel 13 First resonator 15 Second resonator P1, P2 Arrangement pitch of resonator

Claims (3)

[Claims] 1. A resonator type soundproof panel having a resonator comprising a hollow portion inside the panel and a slit communicating the hollow portion with the outside, wherein a first resonator for absorbing a sound of a target frequency and a different frequency are used. A resonator type soundproof panel, characterized in that the panel is provided with a second resonator for absorbing the sound of the above. 2. The resonator type soundproof panel according to claim 1, wherein the second resonator is a resonator that absorbs a sound having a frequency higher than a sound of a target frequency. 3. The first resonator and the second resonator are alternately arranged in parallel, and the first resonators and the second resonators are within a length of ¼ of a wavelength corresponding to each frequency. The resonator type soundproof panel according to claim 1 or 2, wherein the resonator type soundproof panel is arranged at a pitch of.