KR100366368B1 - Sound absorbent device - Google Patents

Abstract

Provides a sound absorbing device that can absorb and reduce the noise of all frequency bands by using both the resonance type sound absorption method and the loss type sound absorption method.

The sound absorbing device includes a main body 10 having a diaphragm 12 formed therein to form an expansion chamber 14 therein; Installed in the diaphragm 12 of the inside of the main body 10, the collecting unit 18 is exposed to the outside where the noise is generated, and the expansion chamber to guide the noise collected from the collecting unit 18 to the expansion chamber ( 14) a resonant sound absorbing tube (16) integrally provided with an extension (20) extending into it; And a vane type sound absorbing plate 22 provided around the collecting unit 18 of the sound absorbing tube 16 so that the sound absorbing air chamber 24 is formed between the diaphragm 12.

Description

Sound absorbing device {SOUND ABSORBENT DEVICE}

The present invention relates to a sound absorbing device, and more particularly, to a sound absorbing device capable of absorbing and reducing noise in all frequency bands by using both a resonance sound absorbing method and a lossy sound absorbing method.

Generally, machines or devices generate noise as the engines, drives or power units mounted thereon operate. Accordingly, most machines, devices or components are provided with sound insulation or sound absorbing material to prevent the occurrence of such noise or to reduce the noise. Such a sound absorbing material is classified into a resonance sound absorbing material and a disappearing sound absorbing material according to the sound absorbing structure.

That is, as shown in Fig. 1, a resonance type sound absorbing material 1, which is widely used in general, is provided on the wall 2 of the device or part. The sound absorbing material 1 is formed in the form of a porous plate 4 in which a plurality of sound absorbing holes 3 are perforated. The porous plate 4 of the sound absorbing material 1 is installed spaced apart from the wall 2 at a predetermined interval, and thus an expansion chamber 5 is formed between the porous plate 4 and the wall 2. An air layer is formed in the expansion chamber. The expansion chamber 5 acts as a resonator to absorb specific frequency noise flowing through the sound absorbing hole 3. That is, sound waves of a resonance frequency whose parameters are aperture ratio, the thickness of the porous plate, and the length of the expansion chamber, which are ratios of the diameters of the sound absorbing holes to the surface area of the entire porous plate, are absorbed. The resonance frequency is expressed as follows.

According to this equation, in an expansion chamber of the same length, the lower the frequency to reduce noise, the lower the opening ratio or the larger the thickness of the porous plate. Here, if the opening ratio is lowered, the non-absorbing surface is increased, and if the thickness of the porous plate is increased, the volume of the sound absorbing material is increased.

On the other hand, as shown in Figure 2, the vane type sound absorbing material 6 for converting sound waves into heat has a certain thickness, for example, is formed of glass fibers having a high sound absorption effect at a high frequency of 500 Hz or more. This vane type sound absorbing material 6 is also provided with sound absorbing material 6 at regular intervals with respect to the wall 2 in order to improve sound absorption, and the sound absorbing air layer 7 is formed between the sound absorbing material 6 and the wall 2. Method is being adopted. In addition, as another method, there is a method of increasing the thickness of the sound absorbing material to lower the frequency to reduce the noise.

However, the method of forming the sound absorbing air layer has a problem in that the sound absorption rate is lowered in the high frequency region, so that the sound absorbing air layer cannot be increased indefinitely, and volume or excessive installation space is required. In addition, the method of increasing the thickness of the sound absorbing material is excessively expensive due to the increase of expensive materials, as well as the problem that the volume increases.

On the other hand, in addition to the sound absorbing material described above, US Patent Nos. 43193939, 405093, 4884615, 5260811, 5210383, 5856640, etc., Korean Patent Publication Nos. 97-31086, 97-50101, 97-69916, 98-28832, 98-49137, 98-79800, 98-87557, 99-7528, and the like are variously configured and applied or used. Such patents are broadly classified into sound absorbing materials having a maze-shaped space formed so as to have excellent sound absorbing performance and methods of manufacturing the sound absorbing agents, and sound absorbing materials to which new functions are added, such as improving heat resistance.

However, the sound absorbing material or the sound absorbing device disclosed in such a patent is formed in the resonance type or the disappearing type, it has been shown that it has the advantages according to each shape, but also has the disadvantages accordingly.

Accordingly, the present invention has been invented to solve the above-described problems, an object of the present invention is to provide a sound absorbing device that can effectively reduce the noise by reducing the noise regardless of the frequency band.

Another object of the present invention is to provide a sound absorbing device having the advantages of both a resonance type sound absorbing material and a disappearing sound absorbing material.

Still another object of the present invention is to provide a sound absorbing device for reducing noise of devices in which noise energy is concentrated at specific frequencies.

1 is a cross-sectional view showing the structure of a conventional resonance-type sound absorbing material.

Figure 2 is a cross-sectional view showing the structure of a conventional disappearing sound absorbing material.

3 is a cross-sectional view showing the structure of a sound absorbing device according to the present invention.

Figure 4 is a graph showing the acoustic impedance according to the frequency for the sound absorbing device according to the present invention.

Figure 5 is a graph showing the sound absorption rate according to the frequency for the sound absorbing device according to the present invention.

* Description of the symbols for the main parts of the drawings *

10: body 12: diaphragm

14: expansion chamber 16: sound absorption tube

18: collecting part 20: expanding part

22: sound absorption plate 24: sound absorption air chamber

The above-mentioned objects are provided in a sound absorbing device for absorbing and reducing noise generated in an apparatus or a mechanical device, comprising: a main body having a diaphragm formed therein to form an expansion chamber therein; A resonance sound absorbing tube installed in the diaphragm of the main body, and having a collecting unit exposed to the outside where noise is generated, and an expansion unit extending into the expansion chamber to guide the noise collected from the collecting unit into the expansion chamber. ; And it can be achieved by a sound absorbing device, characterized in that the sound-absorbing plate is formed around the collecting portion of the sound absorbing tube so that the sound-absorbing air chamber is formed between the diaphragm.

According to one feature of the invention, the collecting portion of the sound absorbing tube is formed in an inverted cone shape.

According to another feature of the invention, the expansion of the sound absorbing tube is bent to reduce the volume of the expansion chamber.

According to another feature of the present invention, the resonance type sound absorbing tube absorbs and reduces the noise of a relatively low frequency band among the noises generated by the devices, and the sound absorbing plate of the missing type absorbs and reduces the noise of the high frequency band.

Hereinafter, a sound absorbing device according to the present invention will be described in detail with reference to the accompanying drawings.

First, referring to FIG. 3 showing a cross-sectional view of a sound absorbing device according to a preferred embodiment of the present invention, the sound absorbing device includes a main body 10 having an inner space. The body 10 is preferably formed in a box shape or a housing shape so as to form a space of a constant size.

Inside the main body 10, there is a built-in diaphragm 12 for partitioning the inner space of the main body up and down. Since the diaphragm 12 is embedded to partition the inside of the main body 10 up and down, an expansion chamber 14 having a constant volume is formed between the lower bottom of the main body 10 and the diaphragm 12.

The diaphragm 12 inside the main body 10 is provided with a resonance sound absorbing tube 16 for sucking noise. The sound absorbing tube 16 has a collecting part 18 exposed to the outside where noise is generated. The collecting unit 18 is preferably formed in an inverted cone shape so as to effectively collect and guide sound waves. The collecting portion 18 is integrally formed with an expansion portion 20 extending into the expansion chamber 14 to guide the noise collected from the collecting portion into the expansion chamber. The extension 20 is also preferably curved in the expansion chamber 14 to reduce the volume of the expansion chamber as well as the entire sound absorbing device.

In addition, around the collection unit 18 of the sound absorbing tube 16, a missing sound absorbing plate 22 surrounding the collection unit 18 and closing the upper portion of the main body 10 is provided. The sound absorbing plate 22 is provided at a predetermined interval with the diaphragm 12 built into the main body 10, whereby a sound absorbing air chamber 24 is formed between the sound absorbing plate 22 and the diaphragm 12. The sound-absorbing air chamber 24 forms a sound-absorbing air layer surrounding the periphery of the collecting portion 18 between the sound-absorbing plate 22 and the diaphragm 12. Here, the thickness of the sound absorbing plate 22 and the volume of the sound absorbing air chamber 24 can be selectively changed according to the desired frequency to reduce the noise.

The sound absorbing device configured as described above will have a structure in which the noise resonant sound absorption method and the disappearance sound absorption method coexist. That is, the sound absorbing surface exposed to the outside of the sound absorbing device is the sound absorbing surface of the resonance type collecting portion 18 which guides the noise to the expansion chamber 14 through the sound absorbing tube 16 and the sound absorbing surface of the disappearing sound absorbing plate 22. It will be included. Accordingly, the noise that is not absorbed by the resonance type sound absorbing tube 16 is absorbed by the vane type sound absorbing plate 22, and the sound can be absorbed completely by absorbing the noise in reverse. As a result, the sound absorbing device according to the present invention has a configuration capable of absorbing and reducing all noise regardless of the frequency band by using the disappearing sound absorbing plate and the resonance type sound absorbing tube.

Optionally, the noise collected by the collecting portion of the resonant sound absorbing tube has a structure that is expanded and reduced in the expansion chamber via the expansion portion, so that the resonances are obtained by using the surface area of the collecting portion, the shape of the expansion tube, and the volume of the expansion chamber as parameters. The optimum flaw tube can be designed by setting the collection performance and the resonance frequency of the type sound absorber.

Hereinafter, the operation of the sound absorbing device according to the present invention and its operation and effect will be described in detail.

For example, but not limited to, when installed in devices in which noise energy is concentrated at specific frequencies, such as transformers or pumps, to absorb noise, the noise energy concentrated at low frequencies may be collected in the sound absorbing tube 16 of the sound absorbing device. It is collected by the unit 18. In this way, the collected noise is guided through the expansion portion 20 in communication with the collecting portion 18 is introduced into the expansion chamber 14 of the main body 10 is absorbed to reduce the noise.

On the other hand, at the same time, the noise of the high frequency of the noise generated in the equipment is absorbed by the disappearing sound absorbing plate 22 provided around the collecting unit 18 of the sound absorbing tube 16. The noise absorbed in this way is absorbed into the sound absorbing air chamber 24 formed between the sound absorbing plate 22 and the diaphragm 12 after passing through the sound absorbing plate 22, and the noise is absorbed by the sound absorbing air layer generated in the sound absorbing air chamber 24. This is absorbed and reduced.

The sound absorbing device according to the present invention is capable of effectively absorbing and reducing noise in all frequency bands by a vane type sound absorbing plate and a resonance type sound absorbing tube. In addition, since the overall thickness of the sound absorbing tube serving as the porous plate of the conventional resonance sound absorbing material is increased by the length leading to the expansion pipe, the same aperture ratio is formed at a lower frequency with a much lower resonance frequency than the conventional resonance sound absorbing material, thereby reducing the low frequency noise. To reduce the noise of the low frequency can be effectively reduced without increasing the thickness or length of the sound absorbing tube. In addition, the collecting portion of the sound absorbing tube is formed such that the cross section is changed, such as inverted conical, it is possible to effectively capture the sound as well as to quickly guide the expansion chamber is to improve the noise reduction performance.

Meanwhile, referring to FIG. 4 which shows the acoustic impedance according to the frequency for the sound absorbing device and the sound absorption rate according to the frequency as a graph by experimenting with the acoustic characteristic of the embodiment of the present invention by the impedance tube method. In the same experimental condition, the sound absorption effect of the resonance type sound absorbing tube has a value near zero in both the real and the imaginary parts at the resonance frequency. In addition, the sound absorption rate shows a result that the sound absorption effect of the resonance type sound absorbing tube is inferior, assuming that complete sound absorption is performed when having a value of 1. However, even based on the above results, the results shown in the respective graphs show that the sound absorbing effect of the resonance type suction tube and the sound absorbing effect of the missing type sound absorbing plate are suitably harmonized to improve the overall sound absorbing effect.

As a result, according to the sound absorbing device according to the present invention, the noise of all frequency bands generated by the device or the mechanical device can be reduced by using both the resonance type sound absorbing method and the loss type sound absorbing method simultaneously. There is a significant improvement.

In addition, it can be configured with a relatively small thickness and length compared to the conventional sound absorbing material has the advantage that the productability is improved by compact and small volume.

Claims (4)

In the sound absorbing device for absorbing and reducing the noise generated by the equipment or machinery, A main body 10 having a diaphragm 12 embedded therein to form an expansion chamber 14 at an inner lower side thereof; Installed in the diaphragm 12 inside the main body 10, the collecting unit 18 is exposed to the outside where noise is generated, and the noise collected from the collecting unit 18 to guide the expansion chamber 14 A resonant sound absorbing tube (16) integrally provided with an extension (20) extending into the expansion chamber (14); And Sound-absorbing device, characterized in that the sound-absorbing air chamber (24) is formed between the diaphragm (12) is formed around the collecting portion (18) of the sound absorbing tube (16) so as to form a sound-absorbing air chamber (24). The sound absorbing device according to claim 1, wherein the collecting part (18) of the sound absorbing tube (16) is formed in an inverted cone shape. The sound absorbing device according to claim 1, wherein the expansion part (20) of the sound absorbing tube (16) is bent to reduce the volume of the expansion chamber (14). According to claim 1, Resonant sound-absorbing tube 16 is a relatively low-frequency band of the noise generated from the devices are absorbed and reduced, the sound-absorbing plate 22 is relatively high frequency band noise The sound absorption device characterized in that the sound absorption is reduced.