KR101186673B1 - A sound reduction apparatus having triangle shape - Google Patents

Abstract

PURPOSE: A composite triangular damper is provided to improve noise reducing effects without the height increase of a soundproof wall. CONSTITUTION: A composite triangular damper comprises a sound absorbing unit, a local reaction unit, and a path difference guide unit. The sound absorbing unit has sound absorbing layers(120) for absorbing sound waves. The local reaction unit is formed on the top of the sound absorbing unit and has resonance layers(220) for guiding the resonance of sound waves. The path difference guide unit is formed on the top of the local reaction unit and has guide ways(320) for guiding the path difference of sound waves.

Description

Compound Triangle Attenuator {A sound reduction apparatus having triangle shape}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an attenuator, and more particularly, to a composite triangle attenuator capable of effectively attenuating noise by maximizing diffraction effects in low, mid, and high frequency ranges.

At the edge of the road, sound barriers are installed to minimize the spread of noise outside the road. The conventional soundproof walls are formed by sandwiching rectangular sound insulation plates between posts spaced at equal intervals along the road, thereby preventing noise generated from the vehicle from being transmitted out of the road.

On the other hand, conventional noise barriers are limited in width and height due to wind pressure and installation section limitation. Therefore, it is often difficult to effectively prevent the propagation of noise. Most of the noise is absorbed or reflected by the soundproof wall as it propagates radially straight from the noise source using air as a medium, but part of the soundproof panel is hit by the soundproof panel and then passes over the soundproof wall. Alone could not effectively block the noise.

Patent Publication No. 10-2012-0014372 (February 17, 2012) "Noise Attenuator" has been proposed to solve this problem. This is to block the noise by attenuating the noise passing over the soundproof wall by installing it on the top of the soundproof wall. When the noise generated in the noise source area is directly introduced, the sound is absorbed through the perforated plate of the upright structure. The sound absorbed through the soundproof wall was absorbed by introducing the noise through the upper perforated plate of the horizontal structure when the diffraction phenomenon of the noise occurred.

Accordingly, there have been efforts to improve and develop such a noise attenuator to effectively absorb and attenuate noise, and to effectively block noise generated when installed in a soundproof wall.

An object of the present invention is to obtain an attenuator capable of effectively absorbing and attenuating noise in various sound bands by simply installing it on a soundproof wall so as to increase the damping effect of the noise even without raising the height of the soundproof wall.

The present invention proposes an attenuator that can effectively reduce noise in various sound bands by absorbing sound waves, inducing resonance, and generating a path difference so as to interfere with each other to achieve the above object.

According to the attenuator according to the present invention, it is possible to effectively absorb and attenuate noises of various sound ranges, and by installing the upper side of the soundproof wall, the noise blocking function of the soundproof wall can be improved, and the height of the soundproof wall as the noise blocking function is improved. Since it is possible to lower the economical, and further lowering the height of the soundproof wall also increases the stability to wind pressure can contribute to improving the stability of the soundproof wall.

1 is a perspective view of an attenuator according to the present invention,
2 is an accurate view of the attenuator according to the present invention,
3 is an exemplary view showing a state where a flaw material is filled in a sound absorbing layer and a resonance space of an attenuator according to the present invention;
4 is an exemplary view showing that sound waves are absorbed and exhausted by an attenuator according to the present invention;
5 is an exemplary view showing a state configured by connecting the attenuator according to the present invention,
6 is an exemplary view in which the attenuator according to the present invention is installed on a soundproof wall.

In the present invention, in order to obtain an attenuator that can effectively reduce the noise of various bands by absorbing sound waves, inducing resonance, and generating a path difference so as to interfere with each other.

A sound absorbing portion having a sound absorbing layer for absorbing sound waves therein; A local reaction part formed on the sound absorption part and having a resonance layer formed therein to induce resonance of sound waves; It proposes a complex triangle attenuator formed to a constant thickness, including; a path difference induction part is formed on the local reaction portion to form an induction path for inducing a path difference of sound waves.

Hereinafter, the present invention will be described in detail with reference to FIGS. 1 to 6.

1 is a perspective view of an attenuator according to the present invention, FIG. 2 is an accurate view of the attenuator according to the present invention, FIG. 3 is an exemplary view showing a state where a flaw material is filled in a sound absorbing layer and a resonance space of the attenuator according to the present invention. It is an exemplary view showing that sound waves are absorbed and exhausted by the attenuator according to the present invention.

As shown, the composite triangle attenuator according to the present invention is sequentially stacked on the sound absorbing unit 100, the local reaction unit 200 and the path difference induction unit 300 is installed on the top of the soundproof wall to attenuate the noise.

The sound absorbing part 100 is formed to be convex from side to side to form symmetrical symmetry, and a plurality of sound absorbing holes are perforated on the left and right wall surfaces, and a sound absorbing layer 120 for absorbing sound waves is formed therein.

The sound absorbing layer 120 may be filled with a sound absorbing material having a density of 32K or more while being formed with a thickness of 20 to 50T while the inside is empty. In the height direction, the center part is formed to be convex outward, so that the sound absorbing part 100 is formed to be convex from side to side. The sound absorbing layer 120 mainly serves to attenuate the noise by absorbing and exhausting the noise of the middle and high bands through the sound absorbing hole.

The local reaction part 200 is formed to be symmetrical on the sound absorbing part 100 and has a resonance layer 220 inducing resonance of sound waves therein, and a plurality of sound absorbing holes are formed on the left and right walls. Sound waves may be introduced into the resonance layer 220 through the sound absorbing hole. As the width increases from side to side, the left and right wall surfaces are inclined.

The resonance layer 220 formed as described above is formed to about 20 ~ 80T, the space is formed inside so that the sound waves introduced through the sound absorbing hole can be exhausted while interfering with each other. As the sound waves are diffusely reflected inside the resonance layer 220, the interference occurs and is exhausted, mainly attenuating low and mid-range noise.

The resonance layer 220 may be formed to have a V-shape. According to this configuration, the interference space 400, which is an empty space in which the resonance layer 220 is not formed in the center of the local reaction part 200, is naturally formed. In particular, as the resonance layer 220 is formed in a V-shape, the local reaction part 200 is naturally symmetrical, and the left and right widths increase toward the upper side to incline the left and right walls and form an inverted triangle as a whole. do.

The resonance layer 220 is preferably formed in such a way that a plurality of resonance spaces 222 partitioned in a predetermined size overlap in the width direction. At this time, the wall partitioning the resonance space 222 may be detachably installed, the sound absorbing hole is formed so that the resonance space 222 is configured to communicate with each other. Therefore, the sound waves are exhausted through the resonance space 222 sequentially, the noise attenuation efficiency is maximized.

On the other hand, the sound absorbing holes formed in the wall partitioning the resonance space 222 can be formed in various sizes. For example, the diameter of each wall is the same, but the diameter is different in the different walls, or the diameter of the sound-absorbing hole formed in each wall is formed in various sizes. This is a configuration that can be adopted to improve the sound absorption performance by the sound absorbing holes formed in various sizes sequentially obstruct the direction of sound waves.

In addition, the diameter of the sound absorbing hole formed in the wall partitioning the resonance space 222 is preferably formed in the range of 1 ~ 3mm, the area of the sound absorbing hole is preferably formed of 5 to 20% of the total area. If the diameter and the total area of the sound absorbing hole are small, the efficiency of sound waves decreases, and the efficiency is lowered. If the diameter and area of the sound absorbing hole are larger than necessary, the degree of obstruction of the sound waves is minimal and the efficiency is lowered. Its diameter and area are to be formed.

When the resonance space 222 is formed by overlapping a plurality of layers it is preferable to overlap in three. If the number of overlapping layers is too large, the resonance space 222 becomes too narrow. On the contrary, if the number of overlapping layers is too small, the exhaustion efficiency of the sound waves is reduced.

As described above, when the resonance space 222 is formed in triple, the sound absorbing material is filled in the resonance space 222 disposed in the center. Therefore, as the sound waves are sequentially introduced into the empty resonance space 222, the sound absorbing material filled resonance space 222 and the empty resonance space 222, exhaustion by interference and exhaustion by sound absorption can be effectively attenuated. Will be.

The path difference induction part 300 is formed on the local reaction part 200 and has a symmetrical shape, and a plurality of induction paths 320 are formed to attenuate the path difference in noise diffracted along the top of the soundproof wall. Configuration. The induction path 320 is formed to include a form perpendicular to the inclined shape, so that the sound waves are induced while the direction is changed along the induction path 320, and reflected and hit each other in the process of being induced as the direction is changed Interfere and exhausted.

The induction path 320 may communicate with the interference space 400. Therefore, the sound waves are introduced into the interference space 400 through the induction path 320 and are consumed by being interfered with each other, and some of the noise is consumed while interfering with the sound waves introduced while being reflected out of the interference space 400.

Here, the wall surface of the induction furnace 320 may be formed to include a bent portion 322 and the flat portion 324. The wall surface of the induction furnace 320 is formed as a plate, which can be detachably installed, and the plate forming the wall surface of the induction furnace 320 is formed in a concave shape to be formed as a bent portion 322. As a result, some of the sound waves passing through the induction path 320 reach the curved portion 322 and the traveling direction is changed or reflected, thereby maximizing interference.

The composite triangle attenuator according to the present invention formed as described above has a constant thickness and becomes symmetrical to form an inverted triangle as a whole. Therefore, when installed on the top of the soundproof wall, the outer wall is inclined in the direction of generating noise effectively absorbs the noise generated from the road. In addition, the convex and concave portions are alternately formed on the outer wall to effectively absorb and reflect noise generated in various directions while exhausting the sound absorbing part 100 and the local reaction part 200 and the path difference. The induction part 300 absorbs and exhausts sound waves while exerting a unique function, thereby effectively attenuating noise in various sound bands.

5 is an exemplary view showing a state in which the attenuator according to the present invention constitutes a set by connecting the attenuator according to the present invention, and FIG.

The triangle attenuator according to the present invention described above may be formed in a form in which the front surface is open and the back surface is blocked in a state in which the thickness is formed at a predetermined thickness, and a plurality of dogs are connected to each other in the thickness direction, thereby causing a local reaction with the sound absorbing part 100. The part 200 and the path induction part 300 may be installed in the soundproof wall in a state partitioned in the thickness direction.

The triangle attenuator is connected to each other by forming a hole penetrating in the thickness direction to the triangle attenuator to fix the bolts, which is installed in the top of the soundproof wall in order to form a set of about 10 in succession.

As described above, when the triangle attenuator according to the present invention is installed on the existing soundproofing wall or the new soundproofing wall, it is possible to effectively absorb and exhaust the noise diffracted on the top of the soundproofing wall. Therefore, the noise blocking effect obtained by raising the soundproof wall can be achieved by installing the triangle attenuator according to the present invention without raising the soundproof wall. As a result, it is possible to lower the height of the sound insulation wall, and it is economical, and further, by lowering the height of the sound insulation wall, it is possible to increase the stability against the wind pressure.

100: sound absorbing part, 120: sound absorbing layer,
200: local reaction part, 220: resonance layer,
222: resonance space, 300: path guidance unit,
320: induction furnace, 322: bend,
324: flat part, 400: interference space.

Claims (5)

A sound absorbing part 100 having a sound absorbing layer 120 for absorbing sound waves therein;
A local reaction part 200 formed on the sound absorbing part 100 and having a resonance layer 220 inducing resonance of sound waves therein;
Is formed on the local reaction unit 200 and formed in a constant thickness, including; path difference induction unit 300 formed with an induction path 320 for inducing the path difference of sound waves,
A plurality of dogs are arranged side by side in the thickness direction on the top of the soundproof wall absorbs and exhausts the sound wave through the sound absorbing part 100, the local reaction part 200 and the path difference induction part 300, characterized in that the attenuated noise Triangle Attenuator. The method according to claim 1,
The sound absorbing part 100, the local reaction part 200, the path difference induction part 300 is formed to be symmetrical,
The resonance layer 220 has a V-shape to form an interference space 400 in the center of the local reaction part 200, so that the induction path 320 communicates with the interference space 400 so that sound waves interfere with the interference space ( Complex triangle attenuator, characterized in that the interference in each other at 400). The method of claim 2,
The resonance layer 220 is formed to overlap a plurality of resonance space 222,
The resonance space (222) is in communication with the sound absorbing hole complex triangle attenuator, characterized in that exhausted through the resonance space (222) sequentially. The method of claim 3,
The resonance space 222 is a three-fold overlapped, complex triangle attenuator, characterized in that the sound absorbing material is filled in the center resonance space (222). The method according to claim 1,
The wall of the induction furnace 320 includes a curved portion 322 and a flat portion 324 to increase the interference by varying the direction of the sound wave propagation direction to increase the interference.

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