JP3275582B2 - Sound absorbing structure - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high-performance sound-absorbing structure for a duct, and particularly to a high-performance sound-absorbing structure for a duct.
The present invention relates to a sound-absorbing structure having an effective sound-absorbing performance in a low frequency range of not more than Hz.

[0002]

2. Description of the Related Art Generally, a sound absorbing material is used in various parts such as a house, a railcar, an aircraft and a vehicle in order to reduce noise, and there is a very high need. Since the sound absorbing material is restricted in space and the like at these used portions, it is important to select the most suitable type for use. In particular, sound-absorbing materials used in vehicles are subject to significant restrictions on weight, space, etc.,
It is necessary that the sound absorbing material be lighter and take up less space.

[0003] Conventionally, a non-woven fabric made of a natural fiber such as felt is installed at a site where sound absorption is required, and the amount of sound absorption material used is increased in order to ensure sufficient sound absorption performance. However, the sound-absorbing material obtained by this method cannot improve the sound-absorbing performance in spite of the adverse effects of cost and weight increase due to an increase in the amount of use, resulting in poor efficiency. Furthermore, 5
Since sound absorption in the low frequency region of 00 Hz or less cannot be effectively performed by the conventional sound absorbing material, a large amount of the sound absorbing material has to be used.

On the other hand, in the engine room, the problem related to the noise of the intake system is increasing. In order to reduce this noise, a type in which a number of small holes are provided in an intake pipe connecting a carburetor and an air cleaner, and a sound absorbing material is further attached to the outside of the small hole portion (JP-A-53-148617, Japanese Utility Model Laid-Open No. Sho 55-167562) and a type in which a partition wall for partitioning an internal combustion engine side and an air cleaner element side is arranged and a throttle hole is provided in the partition wall (Japanese Patent Laid-Open No. 64-5305).
No. 5) has been proposed.

In addition, an air cleaner using a resonator (resonance type silencer) intended to absorb sound of a specific frequency, an air cleaner with a built-in resonator disposed in the center of the element chamber (Japanese Patent Laid-Open No. 62-110722), A resonance frequency variable type resonator (JP-A-55-60444) that changes the resonance chamber volume according to the intake pipe pressure change of the internal combustion engine, and the volume of the resonator according to the intake pressure change caused by the change of the engine speed. (Japanese Patent Application Laid-Open No. 2-19644) has been proposed.

Further, a type using a bypass tube for the purpose of damping an air cleaner case and each duct (Japanese Patent Application Laid-Open No. Hei 5-18329), and a special resonance duct connected to the air cleaner case to connect a resonance in a specific frequency region. (Japanese Unexamined Patent Publication No. 5-18330) has been proposed. On the other hand, a type in which a sound absorbing material is provided in the vicinity of an opening end in a device using a sound absorbing material (Japanese Patent Application Laid-Open No. 53-14867).
Has been proposed, but is not set for low frequencies.

[0007]

However, in the type using the conventional sound absorbing material described in the above publication, it is difficult to selectively reduce a specific frequency,
There is a disadvantage that sound absorption in a low frequency region of 500 Hz or less cannot be effectively performed. Further, a type using a sound absorbing structure such as a side branch or a resonator is effective in reducing only a specific frequency, but has a drawback that it is difficult to absorb sound in a wide frequency range.

Further, when used in a limited space such as a sound absorbing material for a vehicle, it is difficult to use a large air layer behind, a large-capacity resonator, etc., so that sound absorption in a low frequency region is difficult. Met. On the other hand, in the intake system of a vehicle, although there is a change depending on the number of revolutions of the engine, noise in a low frequency region of 500 Hz or less is basically a problem.

Therefore, an object of the present invention is to pay attention to a set position where the performance of the sound absorbing material can be exhibited most effectively, and in particular, to reduce noise in a vehicle engine intake and noise in an air duct for a house, Another object of the present invention is to provide a sound absorbing structure installed in a vehicle.

[0010]

SUMMARY OF THE INVENTION The above objects of the present invention are as follows.
The fiber assembly is installed at least at one or more sites inside the cylinder or inside the cylinder whose inner diameter is expanded regardless of the cross-sectional area or the cross-sectional shape, and the opening of the fiber assembly at the position closest to the opening end of the cylinder The distance between the end side and the opening end of the cylinder is 1 to 50
This has been achieved by a sound-absorbing structure characterized in that it is less than or equal to 1/4 wavelength of the low frequency in the range of 0 Hz.

Hereinafter, the present invention will be described in more detail. The noise caused by the air flowing inside the tubular structure is mainly a sound in a low frequency range of 500 Hz or less. In order to reduce this noise, it is necessary to install a sound absorbing material as a fiber assembly at at least one or more sites in the cylinder. When installing the sound absorbing material, the fiber aggregate may be directly installed in the tube, or the inner diameter of the tube may be expanded by the thickness of the sound absorbing material so as not to increase the ventilation resistance.

In the present invention, a hollow silencer can be formed and the sound absorbing performance can be improved by increasing the inside or the inside diameter of the cylinder irrespective of the cross-sectional area or the cross-sectional shape. At this time, the inner diameter of the cylinder may be larger than the thickness of the sound absorbing material. In the present invention, by adopting such a configuration, the effect of the sound absorbing material and the effect of the hollow silencer are combined, and the sound absorbing performance can be more effectively improved.

[0013] It is preferable that the sound absorbing material is installed as close as possible to the suction port of the cylinder. A standing wave of the intake flow is formed inside the cylinder, and a velocity distribution of the air particles exists. Since the effectiveness of the sound absorbing material is proportional to the size of the particle velocity,
Generally, it is necessary to install the sound absorbing material at a position where the particle velocity is maximized in order to sufficiently obtain the effect of the sound absorbing material. Here, the inlet of the cylinder is one of the positions where the particle velocity becomes maximum. This is the boundary from the reference atmospheric pressure (0 atm) to a certain pressure (p atm) in the cylinder, and the air particles naturally have the maximum velocity.

[0014] Even when the sound absorbing material is installed in other parts, it is preferable to install the sound absorbing material at the position where the particle velocity of the standing wave in the cylinder is maximized for the same reason as described above. The wavelength of the standing wave in the cylinder depends on the length of the cylinder (tube), and there are secondary resonance, tertiary resonance, and the like (n-order resonance). Becomes Therefore, installing the sound absorbing material according to the length of the wavelength caused by the resonance frequency,
It is effective in reducing the noise in the cylinder.

In order to use a sound absorbing material having a sound absorbing effect by aiming at the resonating frequency, the sound absorbing material must be set at the target frequency. This frequency is set as a set frequency. In one wavelength length of the set frequency, there are two positions where the particle velocity is maximum, and the interval is １ ／ wavelength. Therefore, in order to absorb the set frequency, it is most effective to install the sound absorbing material at a position closest to the opening of the cylinder and to install the sound absorbing material every half wavelength from the position of the sound absorbing material.

If the sound absorbing material cannot be installed near the opening of the cylinder, the maximum position of the particle velocity may be estimated from the length of the cylinder and the first sound absorbing material may be installed. When the set frequency is two or more, it is preferable to install the sound absorbing material at a position that is a multiple or a common multiple of the length of the half wavelength.

The set frequency described here is mainly a low frequency of 500 Hz or less. Originally, the sound absorbing material was very effective in a frequency region exceeding 500 Hz, and a certain degree of sound absorbing power was obtained only by installing the sound absorbing material. However, it is very difficult to absorb sound in a low frequency range, and no effective sound absorbing performance can be obtained with a conventional sound absorbing material. In this regard, the sound absorbing structure according to the present invention has succeeded in improving the sound absorbing performance in a low frequency range by adopting the above-described configuration.

The intake noise of the vehicle engine is mainly 50
The problem is low-frequency noise in the range of -500 Hz. When the frequency is less than 50 Hz, it is difficult for human ears to hear the sound, which is a problem as vibration, but is less likely to be a serious problem as noise. Further, when the frequency is lower than 50 Hz, the half wavelength becomes 3.5 m or more, so that the length becomes close to the entire length of the vehicle, and the sound absorbing structure becomes less realistic.
Conversely, if the frequency exceeds 500 Hz, an effect can be obtained with a general sound absorbing material, and there is no point in providing a sound absorbing structure having a complicated structure.

Even when a sound absorbing structure having a high set frequency is installed, every other, every two or more sound absorbing members constituting the sound absorbing structure are provided with a sound absorbing structure having a low set frequency. However, this effect is not limited. The sound-absorbing material closest to the opening installed in the cylinder is
It is important that the distance from the opening is within 1/4 of the set frequency. This is because the velocity distribution of the standing wave formed in the cylinder appears at every 1/4 wavelength, so if the distance to the sound absorbing material becomes longer than the 1/4 wavelength of 500Hz, which is the shortest wavelength among the set frequencies. This is because the sound absorbing effect cannot be obtained.

Here, the reason why the numerical value is not limited is that the wavelength changes because the speed of sound changes according to the temperature of air. The length of the sound absorbing material to be installed in the longitudinal direction is
The wavelength at 40 degrees Celsius of the highest frequency setting frequency,
It is effective that the length is longer than the difference from the wavelength at −20 ° C. This is a temperature difference to be considered in the natural environment, and the sound speed changes and the wavelength changes in the temperature difference. Therefore, considering the change of the wavelength with respect to the temperature at the shortest wavelength among the set frequencies, if the width of the sound absorbing material is shorter than this, the sound absorbing material is shifted from the maximum particle velocity position. Again, for the same reason as above, there is no limitation with numbers.

When a plurality of set frequencies are used, the sound absorbing material may be substantially completely covered with the inside of the cylinder, but is not particularly limited. In a prismatic duct or the like, sound absorbing structures having different set frequencies can be installed in parallel on each side, but this case is not particularly limited.

The fibers forming the fiber aggregate constituting the sound-absorbing structure of the present invention may be natural fibers or synthetic fibers as long as they are within the specified diameter range. In addition, it is preferable to use synthetic fibers that can define all the distributions of the fibrous bodies, can always produce the same material, and can produce a uniform density distribution.

In the present invention, the synthetic fibers constituting the fiber assembly can be appropriately selected from known synthetic fibers and used, for example, nylon, polyacrylonitrile, polyacetate, polyethylene, polypropylene, wire, and the like. Polyester, polyamide and the like can be suitably used. Among these synthetic fibers, polyester fibers and polypropylene fibers, which can be mixed with fibers having different softening points, especially in view of the merits such as recycling of the sound absorbing material and simultaneous moldability and the ability to maintain the shape. It is preferred to use.

The polyester fiber preferably has an average diameter of 10 to 40 μm produced by a melt spinning method. It is difficult to produce a polyester fiber having an average diameter of less than 10 μm by the melt spinning method, and if it exceeds 40 μm, it is difficult to secure sound absorbing performance depending on the surface area of the fiber. Polyester fibers produced by the melt spinning method are the most common and economical.

The polypropylene fibers produced by the melt blown method can produce ultra-fine fibers, so that the sound absorbing performance can be improved. The polypropylene fibers preferably have an average diameter in the range of 1 to 15 μm. It is difficult to produce a polypropylene fiber having an average diameter of less than 1 μm by the melt blown method.
If it exceeds m, economic efficiency will be poor.

In order to obtain good sound absorbing performance, a polypropylene fiber produced by a melt blown method is effective. However, when a fiber having an average diameter of more than 15 μm is produced, a melt spinning method is required from the viewpoint of performance and economy. Is effective. Since the rigidity of the sound-absorbing material itself cannot be obtained with ultra-fine fibers, mixing these two fibers may result in a sound-absorbing material that has both sound absorbing performance and rigidity, and is particularly effective when used in places with strong airflow. There is.

The fiber aggregate used for molding and installing the sound absorbing material has a softening point of at least 20.
It is preferable to mix fibers different by ° C. By mixing fibers having different softening points by at least 20 ° C., a product can be produced by heating and press molding while maintaining the shape of the fiber aggregate. on the other hand,
When the difference in softening point is smaller than 20 ° C., it is not possible to impart a shape to the fiber aggregate using the softening fiber as a binder in a temperature range in which only some fibers are softened according to the difference in softening point. . That is, it is considered that the fiber aggregate is softened and melted. As a result, the fiber aggregate cannot be maintained and becomes a plate shape.

It is also effective to form a fibrous body by integrally molding using a method such as a needle punch to form a fiber aggregate. With this fiber aggregate, a nonwoven fabric can be produced using only one kind of fiber having the same softening point, and a sound absorbing structure can be formed without using relatively expensive fibers having different softening points.

The areal density of the thus formed sound absorbing structure is preferably in the range of 0.4 to 5 kg / m ² . When the surface density of the sound absorbing structure is less than 0.4 kg / m ² , the performance as the sound absorbing structure cannot be secured. Conversely, 5
When the weight exceeds kg / m ² , the weight increases and the resulting cost is exceeded, so that the performance is not improved and the efficiency is not only high. The sound absorption material is reduced, and becomes almost plate-like, and loses its effect as a sound absorbing material.

The sound absorbing structure of the present invention is particularly effective for use in a duct in an air cleaner system for a vehicle. In an intake duct of an engine, noise generated by intake air is one of sound sources of vehicle noise, and a method for efficiently absorbing this noise is required. At present, in order to reduce the noise in the low-frequency region in the noise region, a resonator or a resonance duct whose capacity is adjusted to the target frequency is currently used. This is because it is difficult to absorb low-frequency sounds of 500 Hz or less with current sound absorbing materials.

Furthermore, it is possible to remove part or all of the resonator and the resonance duct attached to the air cleaner for this purpose. This is very effective because it secures space in the engine and has the cost effect of removing accessory parts. When the sound-absorbing structure of the present invention is used in a vehicle and used in a general environment, the sound-absorbing material may be installed so that the opening side edge of the fiber assembly is located within 5 cm from the opening of the duct. preferable. Further, one length of the fiber assembly in the duct direction is in a range of 7 to 20 cm,
When two or more fiber aggregates are installed, it is preferable that the interval between the opening side edges of each fiber aggregate be in the range of 17 to 90 cm. Thereby, the length of the wavelength of the set frequency can be determined in the usage environment of the vehicle.

[0032]

Next, the operation of the present invention will be described. As a result of installing the sound absorbing structure of the present invention in a blower duct of a house or in an air duct for an air cleaner system for a vehicle, it was confirmed that the sound absorbing structure was high-performance and compact in a low-frequency region.

[0033]

EXAMPLES The present invention will be described in more detail with reference to the following Examples, but it should not be construed that the invention is limited thereto.

Example 1 A circular duct having a length of 4 m and a diameter of 12 cm had a surface density of 2
A sound-absorbing structure was produced using a polyester fiber nonwoven fabric having an average fiber diameter of 20 μm in kg / m ² as a sound-absorbing material. At this time, the set frequency is 50 Hz, the installation position of the sound absorbing material closest to the opening is 3 cm from the opening, and the sound absorbing material is installed on the circumference of the pipe with a width of 10 cm. The sound-absorbing structure (1) was produced by installing the individual components.

Example 2 A sound absorbing structure was produced using the same duct and sound absorbing material as in Example 1. At this time, the set frequency was 100 Hz, and the installation position of the sound absorbing material closest to the opening was 2c from the opening.
m, three sound-absorbing materials were installed on the circumference of the pipe at a width of 10 cm, and three sound-absorbing structures (2) were installed in the pipe at intervals of 1.7 m.

Example 3 A sound absorbing structure was produced using the same duct and sound absorbing material as in Example 1. At this time, the set frequency was 200 Hz, and the installation position of the sound absorbing material closest to the opening was 1c from the opening.
m, a sound-absorbing material (3) was prepared by installing five sound-absorbing materials on the circumference of the pipe at a width of 10 cm at intervals of 0.85 m in the pipe.

Example 4 A sound absorbing structure was produced using the same duct and sound absorbing material as in Example 1. At this time, the set frequency was 300 Hz, and the installation position of the sound absorbing material closest to the opening was 1c from the opening.
m, a sound-absorbing structure (4) was prepared by installing seven sound-absorbing materials on the circumference of the pipe at a width of 10 cm, with seven pieces installed at intervals of 0.57 m in the pipe.

Example 5 A sound absorbing structure was produced using the same duct and sound absorbing material as in Example 1. At this time, the set frequency was 400 Hz, and the installation position of the sound absorbing material closest to the opening was 1c from the opening.
m, a sound-absorbing material (5) was prepared by installing 10 sound-absorbing materials on the circumference of the pipe at a width of 10 cm at intervals of 0.43 m in the pipe.

Example 6 A sound absorbing structure was produced using the same duct and sound absorbing material as in Example 1. At this time, the set frequency was 500 Hz, and the installation position of the sound absorbing material closest to the opening was 0.5 mm from the opening.
The sound-absorbing structure (6) was prepared by installing 13 sound-absorbing materials at a width of 8 cm on the circumference of the pipe at a spacing of 0.34 m in the pipe.

Example 7 A sound absorbing structure was manufactured in a square duct having a length of 4 m and a side of 12 cm, using a polyester fiber non-woven fabric having an area density of 1 kg / m ² and an average fiber diameter of 20 μm as a sound absorbing material. At this time, the sound absorbing structure having a set frequency of 100 Hz is installed on one side of the square duct. The installation position of the sound absorbing material closest to the opening is 0.5 cm from the opening and the sound absorbing material size is 12 cm.
cm × 8 cm, and three tubes were installed in the tube at intervals of 1.7 m. Further, at the same time, a sound absorbing structure having a set frequency of 400 Hz is installed on a side different from the end of the square duct, and the installation position of the sound absorbing material closest to the opening is set at 0.
5 cm, the size of the sound absorbing material was 12 cm × 8 cm, and 10 pieces were installed in the pipe at intervals of 0.43 m to produce a sound absorbing structure (7).

Example 8 A sound-absorbing structure was prepared in a square column duct having a length of 4 m and a side of 12 cm, using a polypropylene fiber nonwoven fabric produced by a melt blown method having an area density of 0.5 kg / m ² and an average fiber diameter of 5 μm as a sound absorbing material. Was prepared. At this time, the set frequency is 50
With the method of installing the sound absorbing structure of Hz on one side of the square duct, the installation position of the sound absorbing material closest to the opening is 0.5 cm from the opening, the sound absorbing material size is 12 cm × 8 cm,
Two pieces were installed in the pipe at an interval of 3.4 m. Furthermore, at the same time, the sound absorbing structure with the set frequency of 200 Hz is installed on a side different from the end of the square duct, the installation position of the sound absorbing material closest to the opening is 0.5 cm from the opening, and the size of the sound absorbing material is 12 cm × 8 cm, and five tubes were installed in the tube at an interval of 0.85 m. Furthermore, at the same time, the sound absorbing structure having a set frequency of 400 Hz is installed on a side different from the end of the square duct, and the installation position of the sound absorbing material closest to the opening is 0.5 cm from the opening, and the size of the sound absorbing material is 12 cm × The sound-absorbing structure (8) was prepared by setting 10 pieces at a spacing of 0.43 m in a tube with a length of 8 cm.

Example 9 A circular duct having a length of 4 m and a diameter of 12 cm had an area density of 1
kg / m ² , an end face of the sound absorbing material is set at the opening, using a polyester fiber non-woven fabric having an average fiber diameter of 20 μm as a sound absorbing material,
The sound-absorbing structure (9) was prepared so as to cover the entire inside of the 4-m pipe.

Comparative Example 1 A sound absorbing structure was produced using the same duct and sound absorbing material as in Example 1. At this time, the set frequency was 100 Hz, and the installation position of the sound absorbing material closest to the opening was 7c from the opening.
m, three sound absorbing materials were installed on the circumference of the pipe at a width of 10 cm, and three sound absorbing materials were installed at intervals of 1.7 m in the pipe to produce a sound absorbing structure.

Comparative Example 2 A sound absorbing structure was produced using the same duct and sound absorbing material as in Example 1. At this time, the set frequency was 100 Hz, and the installation position of the sound absorbing material closest to the opening was 2c from the opening.
m, a sound-absorbing structure was prepared by installing three sound-absorbing materials at a width of 4 cm on the circumference of the pipe at intervals of 1.7 m in the pipe.

Comparative Example 3 The same duct as in Example 1 was used, and the area density was 0.2 kg.
A sound-absorbing structure was produced using a polyester fiber non-woven fabric having an average fiber diameter of 20 μm / m ² and an average fiber diameter of 20 μm. At this time, the set frequency is 100 Hz, the installation position of the sound absorbing material closest to the opening is 2 cm from the opening, and the sound absorbing material is installed at a width of 10 cm on the circumference of the tube. A sound absorbing structure was prepared by installing the individual components.

Comparative Example 4 The same duct as in Example 1 was used, and the area density was 6 kg / m.
^{2. A} sound absorbing structure was produced using a polyester fiber nonwoven fabric having an average fiber diameter of 20 μm as a sound absorbing material. At this time, the set frequency is 100 Hz, the installation position of the sound absorbing material closest to the opening is 2 cm from the opening, and the sound absorbing material is installed at a width of 10 cm on the circumference of the tube.
A sound absorbing structure was prepared by installing the individual components.

REFERENCE EXAMPLE 1 The sound absorbing structure obtained in Example 3 was connected to an air cleaner duct of a vehicle, and the sound pressure level at each frequency was measured by running an engine. 7 dB higher than when there was no. Furthermore, the average was improved by 2 dB over all frequencies.

Reference Example 2 The sound absorbing structure obtained in Example 9 was connected to an air cleaner duct of a vehicle, and the engine was operated to measure the sound pressure level at each frequency. As a result, there was no sound absorbing material in the region of 50 Hz or more. On average, it was improved by 4 dB. Further, at a frequency of 500 Hz or more, the average was improved by 10 dB.

Reference Example 3 When the sound-absorbing structure obtained in Example 1 was used in an air duct with a blower in a house, the air-absorbing structure was used. Improved.

Conventional Example 1 A felt 1 m × 1 m having an area density of 1.0 kg / m ² and made of natural fibers and synthetic fibers which were opened was used as a sound absorbing material.

Test Examples The following experiments were performed on the low-frequency sound absorbing materials obtained in the above Examples, Conventional Examples and Comparative Examples. The sound absorbing structure obtained by the method of each of the above Examples and Comparative Examples was attached to an air cleaner duct of a four-cylinder engine installed in a semi-anechoic chamber, and air was taken from one of the ducts. A microphone for measurement was placed at a position about 10 cm from the mouth. At the time of measurement, the engine was a motoring slow acceleration experiment in which the engine was rotated by an external motor, and the sound pressure level of the intake sound at that time was measured in terms of dB for each frequency and tracking data. At this time, the difference was displayed based on the sound pressure level of only the duct without the sound absorbing structure. Further, for comparison with the conventional example, it was assumed that the sound absorbing material was installed in the engine room, and the sound absorbing material of the conventional example 1 was installed about 1 m away from the engine and compared. Table 1 shows the test results.

[0052]

[Table 1]

As shown in Table 1, the various sound absorbing structures manufactured in the examples show excellent sound absorbing characteristics at the set frequency and the average of all frequencies compared to the conventional example, and require less space and tuning than the conventional resonator. It was confirmed that the sound absorbing structure was excellent in performance and mounting properties. In addition, it was confirmed that the comparative examples prepared with specifications out of the specified range of the present invention could not satisfy both performance and space.

[0054]

As described above, the sound-absorbing structure of the present invention is effective mainly for reducing the noise caused by the airflow flowing in the cylinder, and sets the sound-absorbing performance at a low frequency in the range of 50 to 500 Hz. And has excellent sound absorbing performance. Therefore, the sound-absorbing structure of the present invention is very effective as a sound-absorbing material for improving sound-absorbing performance in a low-frequency region in a space where space is limited. It can be suitably used as a sound absorbing material used in places.

[Brief description of the drawings]

FIG. 1 is an external view of a cylindrical duct.

FIG. 2 is a schematic diagram in which a sound absorbing structure is installed in a cylindrical duct.

FIG. 3 is a schematic diagram in which a sound absorbing structure is installed in a cylindrical duct by expanding an inner diameter of a cylinder.

FIG. 4 shows a configuration in which a sound absorbing structure is set in a square duct at a frequency of 2
FIG.

[Explanation of symbols]

 1 cylindrical duct 2 sound absorbing structure

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) G10K 11/16 E04B 1/84 F01N 1/24 F24F 13/02

Claims (6)

(57) [Claims] 1. A fiber assembly is installed at least at one or more sites inside a tube or inside a tube whose inner diameter is expanded regardless of the size or cross-sectional shape of the cross-sectional area, and the fiber assembly is located at a position closest to the open end of the tube. A sound-absorbing structure, wherein the distance between the open end side of the fiber assembly and the open end of the cylinder is not more than 1/4 wavelength of low frequency in the range of 1 to 500 Hz. 2. At least two or more fiber aggregates installed in the length direction in the cylinder, at least one of the fiber aggregates having an interval between the open ends of the fiber aggregates within a range of 50 to 500 Hz. The length is a half wavelength of the wavelength of the sound having the frequency set as described above, and a multiple or a common multiple of the length based on the open end side edge of the fiber assembly closest to the open end of the cylinder. The sound-absorbing structure according to claim 1, wherein the end of the fiber assembly is arranged at the position of (1). 3. The difference between a quarter wavelength at 40 ° C. and a quarter wavelength at −20 ° C. at the set frequency where the length of the fiber assembly in the length direction of the cylinder is the highest. The sound absorbing structure according to claim 1, wherein the sound absorbing structure is also long. 4. The fiber constituting the fiber aggregate has an average diameter of 10
Polyester fiber in the range of ~ 40 µm or average diameter 1
A polypropylene fiber or a mixture thereof having a surface density of 0.4 to 5 kg / m ^2.
The sound-absorbing structure according to any one of claims 1 to 3, wherein: 5. The method according to claim 1, wherein the intake air of the vehicle engine is used to reduce noise generated by an airflow flowing inside the cylindrical intake duct.
5. The sound-absorbing structure according to any one of 4. 6. A sound absorbing structure used for the purpose of reducing a sound generated by an airflow flowing inside a cylindrical intake duct by intake of a vehicle engine, wherein at least one or more fiber aggregates are used. It is a structure to be installed inside the duct, and the opening side edge of the fiber assembly is located within 5 cm from the opening of the duct.
When the length of one fiber assembly is in the range of 7 to 20 cm and two or more fiber assemblies are installed, the interval between the opening side edges of each fiber assembly is in the range of 17 to 90 cm, and at least one fiber assembly is provided. With the above-mentioned interval length, with reference to the opening side edge of the fiber assembly closest to the duct opening, the opening side edge is located at a position that is a multiple or a common multiple of the length, and the fiber assembly The fiber assembly has an average diameter of 10 to 40 μm.
m in the range of 1 to 15 μm
m, a polypropylene fiber or a mixture thereof, and the areal density is in a range of 0.4 to 5 kg / m ² .