KR102094961B1 - Sound absorbing board - Google Patents

Abstract

The present invention relates to a sound absorption board. A plurality of porous sound absorption plates (120) having a plate shape and including a protrusion (122) and a groove (124) which are formed on at least one side with regular patterns are provided to be stacked as a protrusion (122) formed on one of the sound absorption plates (120) is placed towards another sound absorption plate (120). Meanwhile, a punching plate (160) in which sound absorption holes (162) are punched with regular patterns is placed between the stacked sound absorption plates (120) to enable a sound wave that has passed through a sound absorption plate (120) at one side to be absorbed via an air layer formed by the groove (124) during a procedure in which the sound wave is getting exhausted while moving to a sound absorption plate (120) at the other side through the sound absorption holes (162) formed on the punching plate (160).

Description

Sound absorbing board

The present invention relates to a sound-absorbing board, and particularly to a sound-absorbing board that has a multi-layered structure and a sound-absorbing space is formed inside to maximize sound absorption performance.

In construction sites with heavy traffic, roadsides and residential areas, sound barriers with a certain height and length are installed to suppress the propagation of vehicle noise or noise generated at construction sites. The conventional soundproof wall has a structure in which a soundproof plate is stacked and installed on a prop, and the soundproof plate is formed by filling a sound absorbing material such as glass fiber, asbestos, etc. in order to show a buffering and sound absorbing effect inside a case of a plank shape. It is common.

(Document 1) Republic of Korea Utility Model Publication No. 20-0272866 (April 20, 2002)

The present invention has the purpose of improving the performance of the sound absorbing material so as to maximize the sound absorption performance, and its purpose is to obtain a sound absorption board that can be used universally in various fields requiring sound absorption performance as well as a sound insulation plate.

In the present invention, a plurality of porous sound absorbing plates having a protrusion and grooves formed in a certain pattern on at least one surface formed in a plate shape are provided, and the protrusions formed on one sound absorbing plate are disposed and stacked toward another sound absorbing plate, and the perforated plate is formed by stacking the sound absorbing holes in a certain pattern. The sound absorbing board disposed between the stacked sound absorbing plates passes through the sound absorbing holes formed in the perforated plate and passes through the sound absorbing holes formed in the perforated plate and proceeds to the other sound absorbing plate. To achieve the purpose of.

According to the present invention, as the air layer is formed in the space formed inside the sound absorbing board, the sound waves are exhausted while rubbing with the air, and as the sound waves pass through the sound absorbing holes formed in the perforated plate, shrink and expand, vibration increases. Since the time for some sound waves to stay in the space is increased, it is possible to obtain a sound absorbing board in which an improved sound absorbing performance is realized, which effectively increases sound absorption by increasing friction with air.

1 is an exemplary view of a sound absorbing board according to the present invention,
Figure 2 is an exploded view of the sound absorbing board according to the present invention,
Figure 3 is another embodiment of the sound absorbing board according to the present invention,
Figure 4 is another embodiment of a perforated plate applied to the sound absorbing board according to the present invention,
5 is an exemplary view of the sound absorbing board to which the perforated plate of FIG. 4 is applied.

In the present invention, to improve the performance of the sound absorbing material to maximize the sound absorption performance, the purpose is to obtain a sound absorbing board that can be used universally in various fields that require sound absorption performance as well as a sound insulation board.

A plurality of porous sound absorbing plates having protrusions and grooves formed in a certain pattern on at least one surface formed in a plate shape are provided, and the protrusions formed on one sound absorbing plate are disposed and stacked toward the other sound absorbing plates, and the perforated plate having the sound absorbing holes perforated in a predetermined pattern is stacked. A sound absorbing board that is disposed between the sound absorbing plates and passes through the sound absorbing holes formed in the perforated plate to pass through the sound absorbing plate formed in the perforated plate and proceeds to the other sound absorbing plate to pass through the air layer formed by the grooves and absorb sound.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings FIGS. 1 to 5.

1 is an exemplary view of the sound absorbing board according to the present invention, and FIG. 2 is an exploded view of the sound absorbing board according to the present invention.

As illustrated, the sound absorbing board 100 according to the present invention includes a perforated plate 160 formed in a plate shape, similar to the sound absorbing plate 120 formed in a plate shape.

The sound absorbing plate 120 is formed of a porous material. Synthetic resin fibers or glass fibers are formed into a certain thickness and compressed to be formed into a plate shape, so that sound waves can pass through. The sound wave vibrates the air filled in the space in the process of passing through the sound absorbing plate 120, and as a result, sound energy is converted into thermal energy while friction is generated, and noise is absorbed.

The sound absorbing plate 120 has protrusions 122 and grooves 124 formed on one or both surfaces in a constant pattern. The protrusion 122 may protrude in the form of an embossing, but is not limited thereto. For example, it may be formed in various shapes such as a hemispherical shape, a square shape, and a trapezoid shape. In addition, it may protrude in a rod shape having a certain length. The grooves 124 are naturally formed at adjacent positions by the protrusions 122 formed in a constant pattern.

A plurality of sound absorbing plates 120 are provided and stacked. At this time, the projections 122 formed on one of the sound absorbing plates 120 are disposed and stacked toward the other sound absorbing plate 120. Therefore, when the protrusions 122 are formed on the sound absorbing plates 120 to be stacked, the protrusions 122 are disposed to face each other. Between the sound absorbing plates 120 stacked in accordance with this configuration, an empty space is naturally formed by the grooves 124.

The perforated plate 160 may be formed of PP (polypropylene) or a metal material, and is formed to a thickness of several mm. In the case of a metal material, aluminum is preferable. This is based on the fact that it can help the sound waves to be transformed into thermal energy by causing fine vibrations due to sound waves or air pressure.

The perforated plate 160 is perforated with a sound absorbing hole 162 in a constant pattern. The sound absorbing holes 162 are clustered in a certain area, and such clusters may be formed in a certain pattern, or may be formed entirely on the perforated plate 160. What is formed as the former is illustrated in the drawing.

The perforated plate 160 is disposed between the sound absorbing plates 120 to be stacked. That is, the sound absorbing plate 120, the perforated plate 160, and the sound absorbing plate 120 are sequentially arranged. As a result, a space is formed inside the sound absorbing board 100 according to the present invention, and the space is partitioned by the perforated plate 160. At this time, the sound wave passes through one of the sound absorbing plates 120 and enters the perforated plate 160 into the space, and then proceeds to the other of the sound absorbing plates 120. In the configuration in which the protrusions 122 formed on the sound absorbing plate 120 stacked as shown in the configuration face each other, the space is divided in half, and the sound waves pass through the sound absorbing plate 120, pass through the space, pass through the perforated plate 160, After passing through the space again, it is exhausted while proceeding to the sound absorbing plate 120. Particularly, as the sound waves hit the surface of the perforated plate 160 and cause diffuse reflection in the process of passing through the perforated plate 160 in the space, the time at which some sound waves stay in the space increases, and also compressed in the process of passing through the sound absorbing hole 162. When the phenomenon such as expansion is caused, vibration of the sound wave is maximized, and friction with the air is also increased, so that the sound absorption performance can be improved.

Here, the sound absorbing hole 162 is formed such that the diameter decreases from one surface of the perforated plate 160 toward the other surface and the diameter increases to alternate with each other. That is, the sound absorbing holes 162 are formed in a funnel shape, and the larger diameters of the adjacent sound absorbing holes 162 are formed to face each other. Accordingly, in the process of passing through the sound absorbing hole 162, sound waves pass through a small outlet through a large inlet and a large outlet through a small diameter in accordance with the shape of the sound absorbing hole 162. do. As a result, the vibration of sound waves passing through the sound absorbing hole 162 can be increased to maximize friction with the air filled in the space, so that the sound absorption performance can be improved.

Figure 3 is another embodiment of the sound absorbing board according to the present invention.

As illustrated, the sound absorbing board 100 according to the present invention may be stacked by having two or more sound absorbing plates 120. A perforated plate 160 is disposed between the sound absorbing plates 120 to be stacked. As a result, the space can be formed in multiple layers on the sound absorbing board 100.

On the other hand, in the above configuration, the sound absorbing plate 120 disposed at the front and the sound absorbing plate 120 disposed at the rear are formed with only one protrusion 122, and the sound absorbing plate 120 disposed in the middle has protrusions 122 on both sides. It is preferred that the structure is formed. In this configuration, the sound absorbing plate 120 disposed at the front and the sound absorbing plate 120 disposed at the rear are disposed such that the protrusions 122 face the sound absorbing plate 120 disposed therebetween.

The sound absorbing board 100 formed as described above increases the number of sound absorbing plates 120 disposed between the sound absorbing plate 120 disposed at the front and the sound absorbing plate 120 disposed at the rear, and between each sound absorbing plate 120. By arranging the perforated plate 160, the air layer is formed in multiple layers as necessary. As a result, since the sound absorbing performance is improved by the number of air layers, it is possible to form the sound absorbing board 100 that can actively respond according to the level of generated noise.

4 is another embodiment of a perforated plate applied to the sound absorbing board according to the present invention, and FIG. 5 is an exemplary view of the sound absorbing board to which the perforated plate of FIG. 4 is applied.

The sound absorbing hole 162 formed in the perforated plate 160 according to the present invention has been previously described that the diameter of the perforated plate 160 may be alternately arranged such that the diameter decreases and the diameter increases toward the other surface. .

Here, the sound-absorbing hole 162 formed as described above may be formed to protrude from the surface of the perforated plate 160 with a smaller diameter to form a protrusion 164. The protrusion 164 helps to increase the space between the stacked sound absorbing plates 120. Therefore, the air layer can be formed to be larger, thereby increasing friction between sound waves and air, thereby contributing to the improvement of sound absorption performance. Furthermore, it is disposed between the sound absorbing holes 162 in which the protrusions 164 are formed, so that sound waves can be guided to the sound absorbing holes 162 in which the protrusions 164 are not formed. Sound waves are naturally induced to the sound absorbing holes 162 in which the protrusions 164 are not formed along the outer circumferential surface of the protrusions 164. Therefore, more sound waves can be concentrated and passed through the sound absorbing hole 162 in which the protrusion 164 is not formed. That is, as more sound waves are concentrated and compressed, they pass through the sound absorbing hole 162 and then expand, so that the sound absorption performance is improved because the vibration of the sound waves is increased to increase friction with the air.

Meanwhile, the diameter of the protruding portion 164 decreases toward the end, and the outer circumferential surface of the protruding portion 164 is formed to have a concave curved surface at a point connected to the surface of the perforated plate 160. Accordingly, sound waves traveling on the outer circumferential surface of the protrusion 164 smoothly progress along the curved surface, and are smoothly guided to the sound absorbing hole 162 not formed with the protrusion 164.

As described above, the sound absorbing board 100 according to the present invention allows the sound waves to be exhausted while rubbing with the air as the air layer is formed in the space formed therein, and the sound absorbing holes 162 formed on the perforated plate 160 As the vibration increases while shrinking and expanding as it passes, and the time for which some sound waves stay in the space increases, friction with the air increases, so that sound absorption is effectively achieved. As a result, a sound absorbing board 100 with improved sound absorption performance is implemented.

100: sound absorbing board, 120: sound absorbing plate,
122: projection, 124: home,
160: perforated plate, 162: sound-absorbing ball,
164: protrusion.

Claims (5)

A plurality of porous sound absorbing plates 120 formed in a pattern in which projections 122 and grooves 124 are formed on at least one surface in a plate shape are provided, so that the projections 122 formed on one sound absorbing plate 120 have different sound absorbing plates 120 While being stacked towards and stacked,
The perforated plate 160 in which the sound absorbing holes 162 are perforated in a predetermined pattern is disposed between the stacked sound absorbing plates 120 so that the sound waves passing through the one side sound absorbing plate 120 are formed in the perforated plate 160. It passes through the air layer formed by the groove 124 in the process of exhausting while passing through the other side of the sound absorbing plate 120, but is absorbed,
The sound absorbing hole 162 is a sound absorbing board in which the diameter decreases from one surface of the perforated plate 160 toward the other surface and the diameter increases alternately. According to claim 1,
The sound absorbing hole 162 has a structure with a small diameter protruding to form a protrusion 164 so that the sound waves are concentrated and guided to the sound absorbing hole 162 formed between the protrusion 164 and the adjacent protrusion 164. The sound absorption board which becomes possible. According to claim 2,
The diameter of the protruding portion 164 is reduced toward the end, and the outer circumferential surface is formed with a concave curved surface at a point connected to the surface of the perforated plate 160, so that sound waves traveling on the outer circumferential surface of the protruding portion 164 are guided along the curved surface and the protruding portion 164 ) And the sound absorbing board formed so as to proceed smoothly to the sound absorbing hole 162 formed between the adjacent protrusions 164.

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