KR100899929B1 - Sound wall of small wind load - Google Patents

Abstract

The present invention relates to a noise control technology in the environmental field, and more particularly, to a sound barrier that can reduce wind load.

The present invention provides a soundproof wall that solves the above technical problems, and forms a wind gap between the soundproof plate and the soundproof plate or inside the soundproof plate. The airflow is structured to absorb sound, allowing the wind to pass smoothly, and the sound to be absorbed while passing through the airflow, thereby preventing noise from penetrating the rear of the soundproof wall.

The soundproof wall which can reduce the wind load of the present invention is a part of the wind is discharged to the rear of the soundproof wall through the wind when the wind blows to the front or the rear, while the wind load is greatly reduced, the sound insulation performance is not degraded, and the sound passing directly through the soundproof wall is small. . Therefore, the sound insulation wall of the present invention can be made high because the wind load is less, and the noise reduction effect can be obtained as much. And if the soundproof wall of the same height, since the soundproof wall of the present invention receives less wind load, it is not necessary to strengthen the support and the foundation by that much, thus reducing the construction cost of the soundproof wall.

Wind, wind load, sound absorption, sound insulation, diffraction, sound insulation board, sound insulation wall.

Description

Soundproof wall that can reduce wind load {Sound Wall of Small Wind Load}

The present invention relates to a noise control technology in the environmental field, and more particularly, to a sound barrier that can reduce wind load.

In order to reduce road traffic noise, soundproof tunnels have recently been attempted, but are not universalized due to various problems such as mining and internal dust generation, and soundproof walls are most commonly installed. A typical soundproof wall is shown in FIG. Similarly, the foundation 300 is formed of concrete at the end of the road, and the pillars 200 are erected at regular intervals on the foundation, and the soundproof plate 100 is installed on the pillars.

The sound insulation panel 100 has a sound insulation performance of a certain level or more to prevent noise from directly penetrating the soundproof wall, and the sound is absorbed from the side of the soundproof wall where the noise is incident to increase the noise by the reflected sound on the opposite side of the soundproof wall. It is manufactured to prevent it.

The soundproof plate 100 used for the soundproof walls is classified into a sound absorbing type and a reflective type depending on whether or not the surface absorbs sound.

The sound-absorbing soundproof panel is provided with a flaw material such as glass wool with a certain space on the surface of the metal plate having a certain sound insulation performance, and a metal plate with holes or slits formed on the front of the sound absorbing material to protect the sound absorbing material. Is produced by.

In addition, the reflective soundproof board is a soundproof board that reflects most of the sound incident on the surface, and includes a transparent soundproof board using a transparent material such as polycarbonate, a conventional concrete soundproof board, and a wooden soundproof board. Such a reflective soundproofing plate is basically a reflective soundproofing board in which sound incident on the surface is mostly reflected. The extent to which sound is absorbed at the interface between two different media (such as air and concrete) is determined by the acoustic impedance of the two media (density x sound velocity in the media). As most of the sound is reflected, the sound absorption is as low as 0.02. As described above, the reflection type sound insulation board has a problem in that noise is increased due to the reflection sound on the opposite side of the sound barrier.

The noise reduction mechanism by soundproof wall is negative diffraction attenuation. The principle of diffraction attenuation is as follows.

If there are no obstacles between the sound source and the sound collection point, the sound wave is transmitted from the sound source to the sound collection point directly in the transmission path d as shown in FIG. However, when there is an obstacle with sufficient sound insulation between the sound source and the sound collection point, the sound generated from the sound source reaches the sound collection point along the diffraction path A + B passing through the top of the obstacle, and the sound is reduced.

A barrier in which such a barrier is artificially installed for the purpose of noise reduction is called a soundproof wall, and the amount of attenuation of the soundproof wall is determined by the path difference δ. If the sound source and the sound collection point are constant, the path difference depends solely on the height of the sound barrier. The amount of diffraction attenuation of the sound barrier against road traffic noise is calculated by the following equation.

As can be seen from the above equation, the amount of attenuation of the soundproof wall is determined solely by the path difference path difference δ. That is, the larger the path difference, the larger the amount of diffraction reduction. Therefore, in order to obtain high damping amount, the soundproof wall should be installed high. That is, the most basic matter in the design of a soundproof wall is to determine the height of a soundproof wall.

Since the effect of the soundproof wall is basically determined by the height of the soundproof wall as described above, to achieve a noise reduction effect above a certain level, the soundproof wall should be installed high. In particular, if there are high-rise apartments in the area adjacent to the road, high-rise households that are not covered by the sound-proof walls have no sound insulation effect.

In general, the soundproof wall is constructed by continuously installing soundproof plates having a predetermined sound insulation ability or more without gaps in order to block sound passing directly through the wall. If there is a gap between the sound insulation boards, the noise leaks into this gap, which greatly reduces the noise reduction effect of the soundproof wall.

When the wind blows on the high soundproof walls without gaps as described above, the soundproof walls are subjected to a large wind load, which may overturn the soundproof walls. If the high-level sound barrier is overturned, there is a risk of causing injury to people, and it is possible to paralyze road traffic by disabling traffic. Therefore, in the case of a high soundproof wall, the shore 200 and the foundation 30 must be made very strong to withstand the wind load of the expected maximum wind speed, and there is a problem in that construction cost increases.

 In addition, due to the problems of the wind load as described above, the height of the soundproof wall is limited to a certain level, and thus, when the height of the soundproof wall is limited, the noise blocking effect of the soundproof wall is also limited accordingly.

Until now, most of the noise barriers have been studied to increase the noise reduction effect, and no noise barrier has been attempted to reduce the wind load.

As described above, the conventional sound barrier forms a sealed large barrier, and wind loads generated when the wind blows to the front or the rear have been a problem. Therefore, there is a problem in that the construction cost increases because the height of the soundproof wall is not limited to increase the noise blocking effect sufficiently, and the support and the foundation must be firmly supported to withstand the maximum wind load.

In order to reduce the adverse effect of the wind load on the soundproof wall as described above, a soundproof wall receiving less wind load is required. At the same time, the sound barrier must have sufficient sound insulation performance to minimize the effect of noise passing directly through the sound barrier.

The present invention provides a soundproof wall that solves the above technical problems, and forms a wind gap between the soundproofing plate and the soundproofing plate or inside the soundproofing plate.

The airflow is a structure capable of sound absorption, so that the wind passes smoothly, and the sound is absorbed while passing through the airflow, thereby preventing noise from passing through the windshield to the rear of the soundproof wall.

The soundproof wall which can reduce the wind load of the present invention does not significantly increase the wind pressure because a part of the wind is discharged to the rear surface of the soundproof wall through the wind when the wind blows to the front or rear, thus the wind load acting perpendicular to the soundproof wall is greatly reduced.

The sound insulation wall of the present invention has a significant reduction in wind load, but the sound insulation performance is not lowered as described above, and the effect of sound passing directly through the sound insulation wall like a normal sound insulation wall is negligible.

Therefore, the sound insulation wall of the present invention can be made high because the wind load is less, and the noise reduction effect can be obtained as much. In particular, when installed near the road where the high-rise apartments are located, there is a noise reduction effect by the soundproof wall up to the high-rise generation. And if the soundproof wall of the same height, since the soundproof wall of the present invention receives less wind load, it is not necessary to strengthen the support and the foundation by that much, thus reducing the construction cost of the soundproof wall.

As shown in FIG. 3, the soundproof wall capable of reducing the wind load of the present invention is a soundproof wall provided with a plurality of air intensities 10 and 10-1 between the soundproof plate 100 and the soundproof plate 100 or each of the soundproof plate 100. to be.

Although the wind ducts 10 and 10-1 may be formed in various shapes, it is easy to manufacture the sound insulation board in a slit shape along the longitudinal direction of the sound insulation board 100. In the case of the slit-like wind, a sound absorbing material is provided on the upper and lower surfaces of the wind (10, 10-1), and the wind passes smoothly through the wind, and the sound passes through the wind and is absorbed by the sound absorbing material and disappears to prevent leakage. Do not

The sound absorption type sound insulation board used for the soundproof wall of this invention is manufactured as follows. That is, the soundproof plate 100 is combined with the soundproof plate and the perforated plate as reinforcing materials (the reinforcing material may be formed integrally with the soundproof plate by bending the edges of the soundproof plate, as in the case of a normal sound absorbing soundproof plate) and the sound absorbing material on the rear surface of the soundproof plate. 4, but as shown in FIG. 4, a plurality of perforation holes 11 are formed on the reinforcement of the upper and lower surfaces for coupling the sound insulation plate and the perforated plate to absorb sound waves, and the inside of the perforated hole has a predetermined number. The sound absorbing material 12 of thickness is inserted and manufactured. The reinforcing material may be horizontal as shown in (b) of the drawing, or may be inclined as shown in (a) of the drawing, which will be described later.

The method of forming the wind duct 10 between the soundproofing plate 100 and the soundproofing plate 100 is as follows. That is, as shown in FIG. 5, the sound insulation plate 100 manufactured as described above is provided with a spacer 13 having a predetermined thickness between the sound insulation plate 100 and the sound insulation plate 100, and the sound insulation plate 100 continues along the support post. When stacked up, a slit-like wind 10 having a distance equal to the thickness of the spacer 13 is formed between the sound insulation plate and the sound insulation plate. The wind duct 10 may be horizontal as shown in (a) of the drawing according to the shape of the sound insulation board, or may be inclined as shown in (b) of the drawing.

The spacer 13 may be provided to protrude the corner portions of the sound insulation board to the upper part or the lower part of the sound insulation plate, so that the windshield 10 may be formed by itself.

When the windshield is leveled by leveling the reinforcement materials at the top and bottom of the soundproof panel horizontally, the length of the windshield is short, so that sound may not be sufficiently absorbed by the sound absorbing material while passing through the windshield, and thus may not be sufficiently wound. When the upper and lower surfaces of the sound insulation board are made to be inclined to incline the wind, the wind is lengthened, and thus the sound is sufficiently absorbed by the sound absorbing material while the sound passes through the wind, so that the sound is sufficiently wound. When the thickness of the soundproof wall is constant, the greater the inclination of the wind, the longer the wind, and the less the influence of noise leaking through the wind.

The narrower the gap, the more the sound leaked through the wind is attenuated. However, when the wind is narrow, it is difficult to escape the wind, so the reduction of the wind load is lowered. Therefore, the noise reduction amount and the wind load reduction amount can be appropriately adjusted by appropriately adjusting the interval of the air temperature according to the condition of the soundproofing wall.

As shown in FIG. 6, a portion of the sound insulation board 100 may be cut to form a slit-like wind 10-1 directly on the sound insulation board itself. In addition, instead of forming a long slit-like wind, a plurality of circular winds 10-2 having a circular cross section may be attached to the sound insulation board.

In the case of reflective soundproofing boards such as transparent soundproofing boards, concrete soundproofing boards, and wooden soundproofing boards, it is difficult to form airflow directly into the soundproofing boards because the thickness is thinner and difficult to process compared to the sound-absorbing soundproofing walls made of metal plates. In this case, as illustrated in FIG. 7, the wind duct 10-3 may be formed on the connection member connecting the soundproof plate and the soundproof plate.

Like the normal soundproof wall and the soundproof wall of the present invention, the wind is perpendicular to the soundproof wall with the wind velocity (10, 10-1, 10-2, 10-3) (the vertical component of the wind soundproof wall when the wind is inclined with the soundproof wall). In case of fire, the flow of air is as shown in FIG.

In the case of a normal soundproof wall without air temperature, as shown in (a) of the drawing, the direction of wind is changed at a right angle (90 °) in the soundproof wall, and the dynamic load of the wind (1 / 2ρv ² , where ρ is the density of air 1, 2 In kg / m ³ and v, both wind speeds (m / sec) act as wind pressures (p, Pascal) and apply a horizontal load on the front of the soundproof wall.

On the other hand, in the case of a soundproof wall with abundance, as shown in (b) of the drawing, the wind does not change at right angles from the soundproof wall, but the wind direction changes from the front side of the soundproof wall to be inclined toward the windiness, passing through the soundproof wall through the wind, and thus the direction is changed. Only the vertical component of the wind acts as a wind pressure on the sound barrier. Therefore, the wind load of the soundproof wall is significantly lower than that of the normal soundproof wall without the wind.

Figure 9 shows the appearance of noise and wind passing through the wind, the wind is smoothly discharged to the rear of the soundproof wall through the wind (10), but the noise passes through the wind is mostly absorbed by the sound absorbing material around the vanishing and disappears very Only weak noise leaks to the back of the sound barrier, resulting in noise passing through the wind.

The insertion loss (in decibels (dB)), which is the amount that noise is reduced as it passes through the wind, is calculated by the following equation.

In the above formula, α is the sound absorption rate of the sound absorbing material (in case of 50mm glass wool thickness, which is most used as sound absorbing material, it is about 0.9 for STC standard frequency 500Hz sound), and P is the sound absorption in the section of permete. The length of the side that occurs, twice the slit length in the case of slit-like wind, L is the length of the wind (in m), and S is the cross-sectional area of the wind (unit: ㎡, the length of the slit multiplied by the distance between the slits).

As can be seen from the above equation, the longer the length L of the wind, the larger the insertion loss, and the larger the cross-sectional area of the wind, that is, the slit spacing, the lower the insertion loss. Therefore, in order to sufficiently reduce the noise leaked into the wind, it is necessary to increase the wind speed by sharpening the slope of the wind and narrow the interval between the slits. However, the long and narrow wind speed can reduce the effects of sound that directly penetrates the soundproof wall, but it is difficult for the wind to pass through the wind and the wind load is not greatly reduced. Therefore, considering the characteristics of the area where the sound barrier is to be installed, the reduction of wind load and the sound insulation performance of the sound barrier can be optimally compromised.

The soundproof wall which can reduce the wind load of this invention is used to reduce the noise pollution, such as road noise and factory noise. The soundproof wall of the present invention can be particularly useful for noise prevention of high-rise apartments built in the area adjacent to the road.

1 is a shape of a normal soundproof wall.

2 shows a negative diffraction path by the sound barrier.

3 is a block diagram of a sound barrier according to the present invention.

4 is a shape of a sound insulation board applied to the present invention.

5 is a wind diagram formed between the soundproof plate and the soundproof plate.

6 is the wind velocity formed in the soundproof board member.

7 is a wind diagram of a reflective sound insulation board.

8 is a flow chart of wind in a soundproof wall.

9 is an aspect of wind and noise passing through the wind.

※ Important Component Number

100: soundproof board, 200: prop, 300: foundation

11 hole perforation, 12 sound absorbing material 13 spacer

Claims (5)

In the normal soundproof wall consisting of a soundproof plate 100, a strut 200, and the foundation 300, the soundproof plate 100 is inserted between the two struts successively to the top, The sound insulation plate 100 is a rectangular flat soundproof wall, and the upper and lower reinforcement of the sound insulation plate 100 is perforated with a number of holes that can absorb sound waves, the inside of the upper and lower reinforcement of the perforated sound insulation plate 100 Soundproof plate 100 is filled with a sound absorbing material; Inserting a spacer (13) between the sound insulation plate (100) and the sound insulation plate (100); By stacking the sound insulation plate 100 continuously along the posts and assembling, a sound absorbing air flow 10 is formed between the sound insulation plate and the sound insulation plate by the thickness of the spacer 13. Soundproof wall that can reduce wind load. The method of claim 1, The soundproof plate 100 is made to be inclined at a predetermined angle of the reinforcement of the upper and lower so that the cross-section is a parallelogram shape as a whole; The wind duct 10 is characterized in that the wind duct 10 is formed to be inclined at a predetermined angle with respect to the soundproof plate, Soundproof wall that can reduce wind load. delete delete delete

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