KR102291982B1 - A sound absorbing panel - Google Patents

Abstract

The present invention can effectively improve sound absorption performance through mutual friction in which the film vibration of the sound-absorbing paper and the reciprocating motion of the sound passing through the micropores are combined by forming the sound-absorbing paper and the honeycomb, and using the mismatch of the acoustic impedance In this case, the sound-absorbing performance can be further improved, and the production and installation cost of the sound-absorbing panel can also be significantly reduced, so it relates to a sound-absorbing panel having a significant economic advantage,
a honeycomb 10 in which cells of a plurality of polygonal pillars are formed; And a sound-absorbing paper 20 formed on the upper surface of the honeycomb 10; includes, the air flow resistance of the sound-absorbing paper 20 is 0.3 × 10 ⁶ ~ 10 × 10 ⁶ Pa · s / ㎡, sound-absorbing paper The air flow resistance of (20) is a value obtained by dividing the flow resistance of the sound-absorbing paper 20 by the thickness of the sound-absorbing paper 20, and two or more honeycomb 10 and two or more sound-absorbing paper 20 are alternately The cells of the polygonal pillars of the honeycomb 10 positioned above and the cells of the polygonal pillars of the honeycomb 10 located below are alternately stacked as hexagonal pillars, but the honeycomb 10 located below The cells of the hexagonal pillars positioned at the top and bottom rotated by 90° do not match up and down.

Description

Sound absorbing panel {A sound absorbing panel}

The present invention relates to a sound-absorbing panel that can be expanded into various types of products as well as improving sound-absorbing performance by providing a honeycomb and sound-absorbing paper.

In the past, most sound absorbing materials were installed and used in places where damage is expected due to noise, such as high-speed / general roads around residential areas, places handling various musical instruments or songs, and such conventional sound absorbing materials are mainly glass fiber, polyester, and polyurethane. Since it uses chemical materials such as foam or rock wool, it is not environmentally friendly, and the period of use is limited due to the durability problem of the sound absorbing material.

Thus, a resonance-type sound-absorbing cell that does not use a sound-absorbing material has been developed, and the resonance-type sound-absorbing cell is seated on a lower surface plate, a side plate formed at a predetermined height along the edge of the lower surface plate, and the upper end of the side plate, A top plate on which a circular perforation is formed was included.

However, the resonance type sound-absorbing cell does not use a sound-absorbing material, so it is environmentally friendly, but it is composed only of a combination of a perforated top plate and a cavity, so there is a problem that there is a significant limit to improving the sound-absorbing performance.

In addition, there are problems in that the structure is complicated, and the manufacturing cost is excessive, and the scalability to various products is poor.

Republic of Korea Patent Publication No. 10-2010-0036654 Republic of Korea Patent No. 10-1664013

The present invention is to solve the above problems, ^{and by forming a sound-absorbing paper and a honeycomb having an air flow resistance of 0.3×10 6} to 10×10 ⁶ Pa·s/m2, the membrane vibration and micropores of the sound-absorbing paper It is possible to effectively improve the sound absorption performance through the mutual friction action combined with the reciprocating motion of the passing sound, and when using the mismatch of the acoustic impedance, the sound absorption performance can be further improved, and the production and installation cost of the sound absorption panel is also considerably higher. It is an object to provide a sound-absorbing panel having a significant economic advantage by being able to reduce.

In addition, even when a case or frame is provided, the sound-absorbing performance is still excellent, the use of an adhesive between the honeycomb and the sound-absorbing paper is unnecessary, and the expandability to various products such as partitions or wall hangings is excellent, and the fixture or Since the fixing part supports the honeycomb, it is possible to prevent the honeycomb that was vertically folded during transportation or storage from shrinking to its original folded state after being unfolded for use. There is another object to provide a sound-absorbing panel that can further improve the.

A sound-absorbing panel according to the present invention for achieving the above object, a honeycomb in which cells of a plurality of polygonal pillars are formed; and sound-absorbing paper formed on the upper surface of the honeycomb, wherein the airflow resistance of the sound-absorbing paper is 0.3×10 ⁶ to 10×10 ⁶ Pa·s/m2, and the airflow resistance of the sound-absorbing paper is the sound-absorbing paper It is a value obtained by dividing the flow resistance of the paper by the thickness of the sound-absorbing paper.

In this case, the honeycomb may be vertically folded, and a through hole may be formed in the honeycomb, and the through hole may be formed by punching after the honeycomb is vertically folded.

The sound-absorbing panel may be stacked at least two or more up and down, and the cell shape of the polygonal pillar of the honeycomb of the sound-absorbing panel located above and the cell shape of the polygonal pillar of the honeycomb of the sound-absorbing panel located below may be different .

The sound-absorbing panel can be stacked at least two or more up and down, and the cells of the polygonal pillars of the honeycomb of the sound-absorbing panel located above and the cells of the polygonal pillars of the honeycomb of the sound-absorbing panel located below are the same as hexagonal pillars, The sound-absorbing panel located below rotates 90°, so the cells of the hexagonal pillars located up and down may not match up and down.

In addition, the sound-absorbing panel may be stacked at least two or more up and down, and the cell size of the polygonal pillar of the honeycomb of the sound-absorbing panel located above is larger than the cell size of the polygonal pillar of the honeycomb of the sound-absorbing panel located below. Can be, the sound-absorbing paper of the sound-absorbing panel located at the top can be extended to the front and rear sides and/or left and right sides of the honeycomb of the sound-absorbing panel is extended to the front and rear and/or left and right, which is located below.

At least two or more sound-absorbing panels in which the through-holes are formed may be stacked up and down, and a first support bar penetrating through the through-holes of the sound-absorbing panel located at the top; a second support bar penetrating the through hole of the sound-absorbing panel located at the bottom; and a connector elastically supporting the first support bar and the second support bar.

A sound-absorbing panel according to another embodiment of the present invention, a honeycomb in which cells of a plurality of polygonal pillars are formed; Sound-absorbing paper formed on the upper surface of the honeycomb; a case in which the honeycomb and the sound-absorbing paper are seated, and four fasteners are formed into which cells of the polygonal pillars positioned at four corners of the honeycomb are fitted; and a front panel positioned on the upper surface of the sound-absorbing paper and fitted on the upper end of the case, wherein the airflow resistance of the sound-absorbing paper is 0.3×10 ⁶ ∼10×10 ⁶ Pa·s/m2, and the air of the sound-absorbing paper The flow resistance is a value obtained by dividing the flow resistance of the sound-absorbing paper by the thickness of the sound-absorbing paper.

The sound-absorbing panel according to another embodiment of the present invention includes two vertical bars having a “c” shape in cross section, and two horizontal bars having a “c” shape in cross section formed between both ends of the two vertical bars. frame to; Protrusions formed in the longitudinal direction on the bottom surface of the two vertical bars; It is formed at both ends of the vertical bar, the “┛”-shaped fixing part is fitted between the side and the protrusion of the vertical bar; a front panel formed between the protrusions of the two vertical bars; Sound-absorbing paper formed on the upper surface of the front panel; a honeycomb formed on the upper surface of the sound-absorbing paper, the cells of a plurality of polygonal pillars are formed therein, and the cells of the polygonal pillars positioned at four corners are fitted to the four fixing parts, respectively; and a rear panel formed on the upper surface of the honeycomb, wherein the airflow resistance of the sound-absorbing paper is 0.3×10 ⁶ to 10×10 ⁶ Pa·s/m2, and the airflow resistance of the sound-absorbing paper is the sound absorption It is a value obtained by dividing the flow resistance of the paper by the thickness of the sound-absorbing paper.

In this case, a first locking protrusion may be formed on the side surface, a second locking protrusion may be formed on the upper end of the protrusion, and a cross-section of the fixing part may have a “┻” shape.

The present invention is to form a sound-absorbing paper and a honeycomb having an air flow resistance of 0.3×10 ⁶ to 10×10 ⁶ Pa·s/m2, thereby reducing the membrane vibration and micropores of the sound-absorbing paper rather than simple friction between the perforation and sound energy. It is possible to effectively improve the sound-absorbing performance through the mutual frictional action combined with the reciprocating motion of the passing sound, and it is possible to significantly reduce the manufacturing and installation cost of the sound-absorbing panel, thereby having a significant economic advantage.

In addition, even when a case or frame is provided, the sound-absorbing performance is still excellent, the use of an adhesive between the honeycomb and the sound-absorbing paper is unnecessary, and the expandability to various products such as partitions or wall hangings is excellent, and the fixture or Since the fixing part supports the honeycomb, it is possible to prevent the honeycomb that was vertically folded during transportation or storage from shrinking to its original folded state after being unfolded for use. There is an effect that can further improve.

1 is an exploded perspective view of a sound-absorbing panel according to the present invention.
2 is a schematic perspective view of a honeycomb according to the present invention;
Figure 3 is a photograph of the experimental apparatus for obtaining the flow resistance of the sound-absorbing paper according to the present invention.
Figure 4 is a sound-absorbing performance graph of the sound-absorbing panel of the air flow resistance of the sound-absorbing paper according to the present invention is 0.1 × 10 ^{6 Pa · s / ㎡.}
Figure 5 is a sound-absorbing performance graph of the sound-absorbing panel of the air flow resistance of the sound-absorbing paper according to the present invention is 0.3 × 10 ^{6 Pa · s / ㎡.}
Figure 6 is a sound-absorbing performance graph of the sound-absorbing panel of the air flow resistance of the sound-absorbing paper according to the present invention is 2.7 × 10 ^{6 Pa · s / ㎡.}
7 is a graph of the sound-absorbing performance of the sound-absorbing panel of which the airflow resistance of the sound-absorbing paper according to the present invention is 10 × 10 ^{6 Pa · s/m 2 .}
Figure 8 is a sound-absorbing performance graph of the sound-absorbing panel of the air flow resistance of the sound-absorbing paper according to the present invention is 13 × 10 ^{6 Pa · s / ㎡.}
Figure 9 is a sound-absorbing performance graph of the sound-absorbing panel of the different size of the through hole according to the present invention.
10 is an exploded perspective view of a sound-absorbing panel in which two honeycombs are stacked according to the present invention.
11 is an exploded perspective view of a sound-absorbing panel according to another embodiment of the present invention.
12 is a perspective view of a sound-absorbing panel according to another embodiment of the present invention.
13 is an exploded perspective view of a sound-absorbing panel according to another embodiment of the present invention.
14 is a partial cross-sectional view of a sound-absorbing panel according to another embodiment of the present invention.
15 is a partial cross-sectional view of a sound-absorbing panel having a stopping protrusion according to another embodiment of the present invention.

In describing a preferred embodiment of the present invention in detail, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

Figure 1 is an exploded perspective view showing a sound-absorbing panel formed with a honeycomb and sound-absorbing paper according to the present invention, Figure 2 is a schematic perspective view showing when the honeycomb according to the present invention is folded and unfolded, Figure 3 is in the present invention This is a picture of the experimental device to obtain the flow resistance of the sound-absorbing paper.

The sound-absorbing panel according to the present invention, a honeycomb 10 in which cells of a plurality of polygonal pillars are formed; And a sound-absorbing paper 20 formed on the upper surface of the honeycomb 10; includes, the air flow resistance of the sound-absorbing paper 20 is 0.3 × 10 ⁶ ~ 10 × 10 ⁶ Pa · s / ㎡, sound-absorbing paper The air flow resistance of (20) is a value obtained by dividing the flow resistance of the sound-absorbing paper 20 by the thickness of the sound-absorbing paper 20, and two or more honeycomb 10 and two or more sound-absorbing paper 20 are alternately The cells of the polygonal pillars of the honeycomb 10 positioned above and the cells of the polygonal pillars of the honeycomb 10 located below are alternately stacked as hexagonal pillars, but the honeycomb 10 located below The cells of the hexagonal pillars positioned at the top and bottom rotated by 90° do not match up and down.

Cells of a plurality of polygonal pillars (empty spaces of polygonal pillars) are formed inside the honeycomb 10 , and the polygonal pillars may have various shapes such as a square pillar, a hexagonal pillar, or an octagonal pillar, and the honeycomb 10 . The silver is preferably made of paper so that it can be folded vertically, and a through hole 30 may be formed in the honeycomb 10 , and the through hole 30 is formed by punching after the honeycomb 10 is vertically folded. can be (see FIG. 2).

A sound-absorbing paper 20 is formed on the upper surface of the honeycomb 10, and the sound-absorbing paper 20 may be attached to the front surface of the honeycomb 10 by an adhesive, and the sound-absorbing paper 20 and the honeycomb 10. When combined with the case or frame to be described later, there is no need to combine the sound-absorbing paper 20 and the honeycomb 10 with an adhesive.

As the sound-absorbing paper 20, it is preferable to use a Korean paper having an ^{air flow resistance of 0.3×10 6} to 10×10 ^{6 Pa·s/m 2 .} The air flow resistance of the sound-absorbing paper 20 is a value obtained by dividing the flow resistance of the sound-absorbing paper 20 by the thickness of the sound-absorbing paper 20, and as shown in FIG. 3, the sound-absorbing paper is installed in the circular tube, and the sound-absorbing paper is divided The flow resistance of the sound-absorbing paper 20 (a value obtained by dividing the pressure difference between the two sides divided by the sound-absorbing paper by the flow rate) can be obtained from the pressure difference and flow velocity between the two sides.

Figure 4 shows a graph of the sound absorption performance according to the low frequency band of the sound-absorbing panel of which the airflow resistance of the sound-absorbing paper according to the present invention is 0.1 × 10 ⁶ Pa·s/m2, and Figure 5 is the airflow resistance of the sound-absorbing paper according to the present invention Figure 6 shows a graph of the sound absorption performance according to the low frequency band of the sound-absorbing panel of 0.3 × 10 ⁶ Pa · s / ㎡, Figure 6 is the air flow resistance of the sound-absorbing paper according to the present invention is 2.7 × 10 ⁶ Pa · s / ㎡ It shows the sound-absorbing performance graph according to the low-frequency band of the sound-absorbing panel, and Figure 7 shows the sound-absorbing performance graph according to the low-frequency band of the sound-absorbing panel of which the airflow resistance of the sound-absorbing paper according to the present invention is 10 × 10 ⁶ Pa · s / ㎡ 8 is a graph showing the sound-absorbing performance according to the low-frequency band of the sound-absorbing panel of which the airflow resistance of the sound-absorbing paper according to the present invention is 13×10 ^{6 Pa·s/m2.} The x-axis is the frequency, and the y-axis is the sound absorption coefficient.

4 to 8, if the airflow resistance of the sound-absorbing paper 20 is ^{less than 0.3×10 6} Pa·s/m2 or more than 10×10 ⁶ Pa·s/m2, the sound-absorbing performance in the low-frequency band This falls, and the airflow resistance of the sound-absorbing paper 20 is 0.3×10 ⁶ to 10×10 ⁶ Pa·s/m 2 , and the sound absorption performance is improved in the low frequency band. This is due to the combination of the cell of the sound-absorbing paper 20 and the honeycomb 10 in the air flow resistance of the sound-absorbing paper 20 is 0.3 × 10 ⁶ to 10 × 10 ^{6 Pa·s/m2, thousands or tens of thousands of} This is because it acts like a micro-resonator is formed. That is, as the membrane vibration of the sound-absorbing paper 20 and the reciprocating motion of the sound passing through the micropores are soft, the membrane vibration of the sound-absorbing paper 20 and the sound passing through the micropores are not simple friction between the perforation and the sound energy. It effectively improves sound absorption performance through mutual frictional action combined with reciprocating motion.

9 is a graph showing the sound-absorbing performance according to the low-frequency band of the sound-absorbing panel having different sizes of passage holes according to the present invention.

The airflow resistance of the sound-absorbing paper 20 is 2.3×10 ⁶ Pa·s/m2, and the sound-absorbing performance when the through-hole 30 is formed is improved than when the through-hole 30 is not formed, and the through-hole 30 is not formed. When the size of (30) is the largest (5.5 mm), it can be seen that the sound absorption performance is the best.

10 is an exploded perspective view showing a sound-absorbing panel in which two honeycombs and two sound-absorbing papers are alternately stacked according to the present invention.

At least two sound-absorbing panels including a honeycomb 10 in which cells of a plurality of polygonal pillars are formed and a sound-absorbing paper 20 formed on the upper surface of the honeycomb 10 are stacked up and down, and positioned vertically The sound-absorbing panel can be combined with an adhesive, and the cell shape of the polygonal pillars of the honeycomb 10 of the sound-absorbing panel located above (for example, hexagonal pillars) and the honeycomb 10 of the sound-absorbing panel located below. The cell shape of the polygonal poles (eg, octagonal poles) may be different from each other, and in this case, the acoustic impedance will be mismatched and the sound absorption performance will be improved.

At least two or more sound-absorbing panels are stacked up and down, and the cells of the polygonal pillars of the honeycomb 10 of the sound-absorbing panel located above and the polygonal pillars of the honeycomb 10 of the sound-absorbing panel located below are hexagonal pillars. is the same, but the sound-absorbing panel located below rotates 90°, so the cells of the hexagonal pillars located up and down may not match up and down. In this case, the vertically folded honeycomb and the horizontally folded honeycomb are stacked vertically to make the structure more robust.

At least two or more sound-absorbing panels are stacked up and down, and the cell size of the polygonal pillars of the honeycomb 10 of the sound-absorbing panel located on the upper side is higher than the cell size of the polygonal pillars of the honeycomb 10 of the sound-absorbing panel located below. It may be large, and in this case, the acoustic impedance will be mismatched and the sound absorption performance will be improved compared to the case where the upper and lower cell sizes are the same.

At least two sound-absorbing panels are stacked up and down, and the sound-absorbing paper 20 of the sound-absorbing panel located at the top is extended to the front and rear and/or left and right and the front and rear sides of the honeycomb 10 of the sound-absorbing panel located below and/ Alternatively, it may be formed to extend to the left and right sides, and the extended sound-absorbing paper 20 is adhered to the side of the laminated honeycomb 10 to make it structurally more robust.

In addition, the sound-absorbing panel is stacked at least two or more up and down, the first support bar 31 passing through the through hole 30 of the sound-absorbing panel located at the top; a second support bar (32) penetrating the through hole (30) of the sound-absorbing panel located at the lowermost part; and a connecting body 33 elastically supporting the first support bar 31 and the second support bar 32 .

Various materials such as paper, synthetic resin, wood or metal may be used for the first support bar 31 and the second support bar 32 , and both ends of the first support bar 31 and the second support bar 32 may be separated from each other. The connector 33 supports elastically, and as the connector 33, a rubber band, a spring having rings formed at both ends, or a “C”-shaped clip with elastic force may be used, and the first support bar 31 and the first support bar 31 may be used. It is possible to transform into a connecting body 33 of various shapes that can act between the two support bars 32 . Since the connector 33 acts as an elastic force on the laminated honeycomb 10 , it is structurally more robust.

11 is an exploded perspective view of a sound-absorbing panel including a case, a honeycomb, a sound-absorbing paper, and a front panel in which a fixture is formed according to another embodiment of the present invention.

A sound-absorbing panel according to another embodiment of the present invention, a honeycomb 10 in which cells of a plurality of polygonal pillars are formed; Sound-absorbing paper 20 formed on the upper surface of the honeycomb 10; A case 40 in which the honeycomb 10 and the sound-absorbing paper 20 are seated, and four fixtures 41 into which the cells of the polygonal pillars located at the four corners of the honeycomb 10 are fitted, respectively; And located on the upper surface of the sound-absorbing paper 20, the front panel 50 fitted to the upper end of the case 40; includes, the airflow resistance of the sound-absorbing paper 20 is 0.3 × 10 ⁶ ~ 10 × 10 ⁶ Pa·s/m 2 , and the airflow resistance of the sound-absorbing paper 20 is a value obtained by dividing the flow resistance of the sound-absorbing paper 20 by the thickness of the sound-absorbing paper 20 .

As the case 40 on which the honeycomb 10 and the sound-absorbing paper 20 are seated, various materials such as plastic, FRP, tempered glass or metal may be used, and the case 40 of various sizes may be used as needed. . Four fasteners 41 are formed on the bottom surface near the four corners of the case 40, and the cells of the polygonal poles near the four corners of the honeycomb 10 are fitted in the fastener 41, respectively, so that during transportation or storage After the vertically folded honeycomb 10 is unfolded for use, there is an effect that can prevent shrinkage to the original folded state. At this time, the height of the fixture 41 is preferably equal to or lower than the height of the honeycomb 10 .

The front panel 50 positioned on the upper surface of the sound-absorbing paper 20 is fitted and fixed to the top of the case 40 , and the material of the front panel 50 may be the same as or different from the material of the case 40 , and the front panel The sound-absorbing paper 20 and the honeycomb 10 positioned between the 50 and the case 40 do not need to be adhered.

Between the case 40 and the front panel 50, two or more honeycomb 10 and two or more sound-absorbing paper 20 may be alternately stacked alternately. At this time, the height of the fixture 41 is preferably equal to or lower than the height of the entire stacked honeycomb 10, and the fixture 41 passes through the sound absorbing paper 20 located between the two honeycombs 10. A through hole may be formed so as to be able to, or a sound-absorbing paper 20 may be positioned between the fixtures 41 .

12 is a perspective view of a sound-absorbing panel including a frame, a fixing part, a front panel, a sound-absorbing paper, a honeycomb and a rear panel in which a protrusion is formed according to another embodiment of the present invention, and FIG. 13 is the sound-absorbing part of FIG. It shows an exploded perspective view after turning the panel up and down, and FIG. 14 is a partial cross-sectional view cut horizontally after turning the sound-absorbing panel of FIG. 12 up and down, and FIG. 15 is a vertical bar of FIG. It shows some cross-sectional views cut horizontally after the sound-absorbing panel is turned upside down.

Sound-absorbing panel according to another embodiment of the present invention, the cross section formed between the two vertical bars 61 and the both ends of the two vertical bars 61 having a “c” shape in cross section is a “c” shape a frame 60 comprising two transverse bars 66 in the shape; a protrusion 63 formed in the longitudinal direction on the bottom surface 62 of the two vertical bars 61; It is formed at both ends of the vertical bar 61, and is fitted between the side 64 and the protrusion 63 of the vertical bar 61, a “┛”-shaped fixing part 65; a front panel 50 formed between the protrusions 63 of the two vertical bars 61; Sound-absorbing paper 20 formed on the upper surface of the front panel 50; The honeycomb 10 is formed on the upper surface of the sound-absorbing paper 20, the cells of a plurality of polygonal pillars are formed therein, and the cells of the polygonal pillars positioned at four corners are fitted into the four fixing parts 65, respectively. ; and a rear panel 70 formed on the upper surface of the honeycomb 10; and, the airflow resistance of the sound-absorbing paper 20 is 0.3×10 ⁶ to 10×10 ⁶ Pa·s/m2, and the sound-absorbing paper The air flow resistance of (20) is a value obtained by dividing the flow resistance of the sound-absorbing paper 20 by the thickness of the sound-absorbing paper (20).

The frame 60 into which the fixing part 65, the front panel 50, the sound-absorbing paper 20, the honeycomb 10 and the rear panel 70 are fitted is made of various materials such as plastic, FRP, tempered glass or metal. may be used, and frames 60 of various sizes may be used as needed. At this time, the frame 60 has two vertical bars 61 having a “c” shape in cross section, and two horizontal bars having a “C” shape in cross section formed between both ends of the two vertical bars 61 . Including (66), the bottom surface 62 of the two vertical bars (61) is formed with a protrusion (63) in the longitudinal direction.

The fixing part 65 coupled to both ends of the vertical bar 61 has a “┛” shape in cross section, and can be fixed by being fitted from the top between the side surface 64 and the protrusion 63 of the vertical bar 61 ( 13 and 14). At this time, when the first locking jaw 68 is formed on the side surface 64 and the second locking jaw 69 is formed on the upper end of the protrusion 63, the cross section of the fixing part 65 is “┻” shape and (See FIG. 15 ), the fixing part 65 may be fixed by being fitted from the front or rear between the first locking jaw 68 and the second locking jaw 69 .

A front panel 50 is formed between the protrusions 63 of the two vertical bars 61 , and a sound-absorbing paper 20 is formed on the upper surface of the front panel 50 , and a honeycomb is formed on the upper surface of the sound-absorbing paper 20 . (10) is formed.

At this time, since the four fixing parts 65 are coupled to both ends of the two vertical bars 61, and the cells of the polygonal pillars near the four corners of the honeycomb 10 are fitted to the fixing part 65, respectively, transportation or There is an effect that can prevent the honeycomb 10 folded vertically during storage from being contracted to its original folded state after being unfolded for use. In this case, the height at which the fixing part 65 protrudes from the upper end of the protrusion 63 is preferably equal to or slightly smaller than the thickness of the rear panel 70 .

The rear panel 70 located on the upper surface of the honeycomb 10 is fitted and fixed to the frame 60 , and the material of the front panel 50 and the rear panel 70 may be the same as or different from the material of the frame 60 . And, the sound-absorbing paper 20 and the honeycomb 10 positioned between the front panel 50 and the rear panel 70 do not need to be bonded.

Between the front panel 50 and the rear panel 70, two or more honeycomb 10 and two or more sound-absorbing paper 20 may be alternately stacked alternately. At this time, since the height at which the fixing part 65 protrudes from the lower end of the honeycomb 10 positioned at the top is preferably equal to or slightly smaller than the thickness of the rear panel 70, the height of the fixing part 65 is located at the top It is slightly higher than the height to the lower end of the honeycomb 10 . This is to couple the honeycomb 10 fitted to the vertical bar 61 to the fixing part 65 .

When describing the function and operation of the sound-absorbing panel according to the present invention, it is as follows.

In a simple sound-absorbing panel including a sound-absorbing paper 20 and a honeycomb 10 having an air flow resistance of 0.3×10 ⁶ ∼10×10 ⁶ Pa·s/m2, a sound-absorbing paper that is not a simple friction between perforation and sound energy The sound absorption performance can be effectively improved through the mutual friction action in which the membrane vibration of (20) and the reciprocating motion of the sound passing through the micropores are combined, and the sound absorption performance can be further improved when the mismatch of the acoustic impedance is used. , it has a significant economic advantage because it can significantly reduce the manufacturing and installation cost of the sound-absorbing panel.

In the sound-absorbing panel including the case 40, the honeycomb 10, the sound-absorbing paper 20 and the front panel 50 in which the fixture 41 is formed according to another embodiment of the present invention, the sound-absorbing performance is still excellent, and , the use of adhesive is unnecessary, and it has excellent expandability to various products such as partitions or wall hangings, and since the fixture 41 supports the honeycomb 10, the honeycomb 10 that was vertically folded during transportation or storage It can prevent shrinkage to its original folded state after being unfolded for use.

In addition, the frame 60, the fixing part 65, the front panel 50, the sound-absorbing paper 20, the honeycomb 10 and the rear panel ( 70), the sound-absorbing performance is still excellent, and the manufacturing cost of the sound-absorbing panel can be further lowered. It is excellent in extensibility and prevents the honeycomb 10 from being vertically folded during transportation or storage from being contracted to its original folded state after being unfolded for use because the fixing part 65 supports the honeycomb 10 . can

The above description is merely illustrative of the technical idea of the present invention, and various modifications and variations may be made by those of ordinary skill in the art to which the present invention pertains without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to illustrate, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

10: honeycomb 20: sound absorbing paper
30: through hole 31: first support bar
32: second support bar 33: connecting body
40: case 41: fixture
50: front panel 60: frame
61: vertical bar 62: bottom surface
63: protrusion 64: side
65: fixing part 66: horizontal bar
68: first engaging jaw 69: second engaging jaw
70: rear panel

Claims (5)

a honeycomb 10 in which cells of a plurality of polygonal pillars are formed; and
Includes; sound-absorbing paper 20 formed on the upper surface of the honeycomb 10;
The airflow resistance of the sound-absorbing paper 20 is 0.3×10 ⁶ to 10×10 ⁶ Pa·s/m 2 ,
The airflow resistance of the sound-absorbing paper 20 is a value obtained by dividing the flow resistance of the sound-absorbing paper 20 by the thickness of the sound-absorbing paper 20,
The honeycomb 10 can be vertically folded,
A through hole 30 is formed in the honeycomb 10,
The through hole 30 is formed by punching after the honeycomb 10 is vertically folded,
The sound-absorbing paper 20 is extended to the front and rear sides or left and right sides of the honeycomb 10 positioned below by extending back and forth or left and right,
The sound-absorbing paper 20 is a sound-absorbing panel, characterized in that the Korean paper.
According to claim 1,
The sound-absorbing paper 20 is a sound-absorbing panel, characterized in that attached to the upper surface of the honeycomb 10 by an adhesive.
3. The method of claim 1 or 2,
Two or more of the honeycomb 10 and two or more of the sound-absorbing paper 20 are alternately stacked,
Although the cells of the polygonal pillars of the honeycomb 10 located above and the cells of the polygonal pillars of the honeycomb 10 located below are the same as hexagonal pillars, the honeycomb 10 located below is 90° A sound-absorbing panel, characterized in that the cells of the hexagonal pillars positioned up and down by rotating do not match up and down. delete delete

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