KR100860197B1 - Sound-absorbing materials for diminishing noise - Google Patents

Abstract

A sound absorbing member for attenuating noise is provided to attenuate noise of a governor by using a sound absorbing layer made of polyurethane foam and a noise insulation layer made of aluminum and surrounding the sound absorbing layer. A sound absorbing member for attenuating noise comprises a peripheral pipe(1) of a governor, a sound absorbing layer(10), and a noise insulation layer(20). The sound absorbing layer surrounds the peripheral pipe of the governor. The sound absorbing layer is made of polyurethane foam having density of about 150kg/m3. The noise insulation layer is made of aluminum of 0.5mm and surrounds the sound absorbing layer. A waterproof layer is provided between the peripheral pipe of the governor and the sound absorbing layer. A rubber cover(21) surrounds the outer peripheral portion of the noise insulation layer.

Description

Sound-absorbing materials for diminishing noise}

The present invention relates to a sound absorbing material, and more particularly to a sound absorbing material for noise attenuation that can obtain a large noise reduction effect.

Constant pressure is a device that lowers the pressure of LNG from high pressure to low pressure suitable for supply to consumers.

The constant pressure generator generates noise as the high pressure LNG is converted into low pressure LNG as energy released by the pressure drop of the LNG is released as sound energy. In addition, around the constant pressure, the noise due to the flow resistance of the gas supplied through the diaphragm or the tube of the constant pressure, the fluid noise due to the increase in the LNG flow rate due to the pressure difference between the LNG input and output of the constant pressure, And noise caused by excessive supply compared to the pipe diameter.

The noise generated around the regulator and the regulator is averaged at least 90dB to 130dB. Noise experiments show that humans cannot communicate with ambient noise above 90dB. And, according to the noise tolerance standard, humans should not be exposed to noise of more than 115dB. Therefore, workers wear earplugs when performing maintenance work on the pressure regulator. However, current earplugs cannot completely block the loudspeakers and loud noises from around them. Accordingly, the workers who maintain and maintain the regulator are not completely protected from the loud noise generated around the regulator and the regulator during the maintenance operation of the regulator.

In addition, the loud noise generated from the pressure regulator and the surroundings of the pressure regulator also affects the lives of the residents of the supply management station where the pressure regulator is installed, which causes the complaints.

In order to reduce the noise problem of the pressure regulator, the supply control station in which the pressure regulator is installed is equipped with silencers in the vicinity of the pressure regulator.

Accordingly, an object of the present invention is to provide a sound absorbing material for noise attenuation, which can obtain a large noise reduction effect.

In order to achieve the above object, the sound absorbing material for noise attenuation according to an embodiment of the present invention includes a peripheral pipe of the pressure regulator; It is provided with a sound-absorbing layer formed of a polyurethane foam having a density of 150 kg / ㎥ wrap around the outside of the peripheral pipe of the constant pressure.

The sound absorbing material for noise reduction further includes a sound insulating layer surrounding the outside of the sound absorbing layer.

The sound insulation layer is formed of 0.5 mm aluminum.

The sound absorbing material for noise reduction further includes a waterproof layer between the peripheral pipe of the pressure regulator and the sound absorbing layer.

Sound absorbing material for noise damping according to an embodiment of the present invention and the peripheral pipe of the pressure regulator; A sound absorbing layer surrounding the outside of the peripheral pipe of the pressure regulator; A sound insulation layer formed of aluminum surrounding the outside of the sound absorbing layer is provided.

The sound absorbing layer is formed of any one of 150 kg / m 3 polyurethane foam, 28 kg / m 3 polyurethane foam, 70 kg / m 3 polyurethane foam-memory foam, and 8 kg / m 3 density melanin foam. do.

The sound absorbing material for noise reduction further includes a waterproof layer between the peripheral pipe of the pressure regulator and the sound absorbing layer.

The sound absorbing material for noise attenuation according to the first embodiment of the present invention is formed of a polyurethane foam having a density of 150 kg / m 3 showing an average flaw rate among commercialized materials, and is provided with a sound absorbing layer surrounding the peripheral pipe of the pressure regulator. A big attenuation effect of the noise can be obtained.

In addition, the sound absorbing material for noise attenuation according to the second embodiment of the present invention is a sound absorbing layer formed of a polyurethane foam having a density of 150 kg / m 3 showing an average flaw rate, and a sound insulating layer formed of 0.5 mm aluminum to surround the outside of the sound absorbing layer. By providing a larger attenuation effect of the noise of the constant pressure than the attenuation effect of the static pressure of the first embodiment of the present invention can be obtained.

Hereinafter, exemplary embodiments of the present invention will be described with reference to FIGS. 1 to 8.

Sound absorbing material for noise damping according to an embodiment of the present invention is formed to surround the peripheral pipe of the pressure regulator.

1 is a view showing a sound absorbing material for noise damping according to a first embodiment of the present invention.

Referring to FIG. 1, the sound absorbing material for noise damping according to the first embodiment of the present invention includes a sound absorbing layer 10 formed of a polyurethane foam having a density of 150 kg / m 3 surrounding the outside of the peripheral pipe 1 of the pressure regulator. .

The sound absorbing material for noise attenuation according to the first embodiment of the present invention is commercialized in order to select the sound absorbing layer 10 of the optimal material which can obtain a large attenuation effect of the noise of the price ratio regulator. Polyurethane foam, 150 kg / m 3 density polyurethane foam, 70 kg / m 3 density polyurethane foam-memory foam, and 8 kg / m 3 density melanin foam were used as sound absorbing layer 10 to An experiment was conducted to measure the noise. Sound absorbing material for noise attenuation according to the first embodiment of the present invention is the first microphone (MIC1), the rear end of the constant pressure regulator to the front end of the constant pressure regulator (pipe to which the LNG supplied to the constant pressure moves) in order to measure the noise around the constant pressure and the pressure regulator The second microphone MIC2 and the third microphone MIC3 were installed in the pipe in which the LNG output from the pressure regulator moves, and the noises around the pressure regulator and the pressure regulator were measured.

Table 1 is a table showing the noise measured from the first to third microphones in the experiment according to the first embodiment of the present invention.

Sound absorbing material MIC1 MIC2 MIC3 Sound absorption No sound absorption layer 96 dB 117 dB 100 dB - Polyurethane foam with a density of 28㎏ / ㎥ 89 dB 101 dB 97 dB 16% Polyurethane foam with a density of 150㎏ / ㎥ 90 dB 95 dB 97 dB 23% Polyurethane foam-memory foam with a density of 70㎏ / ㎥ 89 dB 102 dB 97 dB 15% Melanin foam of 8㎏ / ㎥ density 90 dB 104 dB 96 dB 13%

Referring to Table 1, the average noise measured by the first microphone MIC1 is 96 dB and the second microphone MIC2 is measured when the sound absorbing layer 10 is not provided outside the peripheral pipe 1 of the pressure regulator. One average noise was 112 dB as shown in FIG. 2A, and the average noise measured by the third microphone MIC3 was 100 dB.

To calculate the average noise, the first highest measured noise (SIL ₁ ) measured by the microphone is the highest measured noise, and the difference between the highest measured noise (SIL ₁ ) and the second highest measured noise (SIL ₂ ) (SIL _1- SIL ₂ ) Then, if the difference between the highest measured noise (SIL ₁ ) and the second highest measured noise (SIL ₂ ) (SIL ₁ -SIL ₂ ) is less than or equal to 1, 2 is greater than or equal to 2 and less than or equal to 4 and less than or equal to 1 Is added to the highest measured noise (SIL ₁ ) and is not taken into account if it is 10 or more. The new highest measured noise (SIL ₁ ) is then added to the highest measured noise (SIL ₁ ) plus 1, 2, or 3 depending on the difference between the highest measured noise (SIL ₁ ) and the second highest measured noise (SIL ₂ ) (SIL ₁ -SIL ₂ ). Update to (SIL ₁ ) and repeat the above process with three times higher measurement noise to second higher measurement noise (SIL ₂ ). When the difference between the updated highest measured noise (SIL ₁ ) and the updated second highest measured noise (SIL ₂ ) is 10 or more, the process is no longer repeated, and the currently updated highest measured noise is determined as the average noise.

Referring to FIG. 2A, when the sound absorbing layer 10 is not provided outside the peripheral pipe 1 of the pressure regulator, when the average noise of the noise measured by the second microphone MIC2 is calculated, the second microphone MIC2 is calculated. The highest measured noise (SIL ₁ ) is 111dB and the second highest measured noise (SIL ₂ ) is 110dB. The difference between the highest measured noise (SIL ₁ ) and the second highest measured noise (SIL ₂ ) (SIL ₁ -SIL ₂ ) is 111 dB-110 dB = 1, so 3 dB equals 111 dB to the new highest measured noise (SIL ₁ ). Update 110dB, the third highest measurement noise, to the second highest measurement noise (SIL ₂ ). Subsequently, the difference between 114 dB, the highest measured noise (SIL ₁ ), and 110 (SIL ₁ -SIL ₂ ), the second highest measured noise (SIL ₂ ), is 114dB-110dB = 4, so 114dB is added to 114dB. Update to the new highest measurement noise (SIL ₁ ) and update the fourth highest measurement noise (108dB) to the second highest measurement noise (SIL ₂ ). Then, the update best measurement noise (SIL ₁₎ of 116dB and update the second-highest measured noise (SIL ₂₎ the 108 difference (SIL ₁ - SIL ₂₎ is 116dB - because 108dB = 8, adding 1 to 116dB Update 117dB to the new highest measurement noise (SIL ₁ ) and update the fifth highest measurement noise (106dB) to the second highest measurement noise (SIL ₂ ). And, updating the best measurement noise (SIL ₁₎ is 117dB with a second high measurement noise updating of (SIL ₂₎ of 106 primary-since more than that the (SIL ₁ SIL ₂₎ 10 without repeating the above procedure, a 117dB Determine the average noise.

When the sound absorbing layer 10 of polyurethane foam having a density of 28 kg / m 3 was installed outside the peripheral pipe 1 of the pressure regulator, the average noise measured by the first microphone MIC1 was 89 dB, and the second microphone MIC2. The average noise measured by) was 101 dB as shown in FIG. 2B, and the average noise measured by the third microphone MIC3 was 97 dB. When the sound absorption layer 10 of the polyurethane foam of 28 kg / m <3> density was provided outside the periphery piping 1 of a constant pressure regulator, the average sound absorption rate was 16%.

When the sound absorbing layer 10 of polyurethane foam having a density of 150 kg / m 3 was installed outside the peripheral pipe 1 of the constant pressure regulator, the average noise measured by the first microphone MIC1 was 90 dB, and the second microphone MIC2. The average noise measured by) is 95 dB as shown in FIG. 2C, and the average noise measured by the third microphone MIC3 was 97 dB. The average sound absorption rate when the sound absorption layer 10 of the polyurethane foam of 150 kg / m <3> density was provided in the outer side of the piping 1 of a constant pressure regulator was 23%.

When the sound absorbing layer 10 of the polyurethane foam-memory foam having a density of 70 kg / m 3 was installed outside the peripheral pipe 1 of the pressure regulator, the average noise measured by the first microphone MIC1 was 89 dB, and the second The average noise measured by the microphone MIC2 was 102 dB as shown in FIG. 2D, and the average noise measured by the third microphone MIC3 was 97 dB. When the sound absorption layer 10 of the polyurethane foam-memory foam of 70 kg / m <3> density was provided outside the periphery piping 1 of a constant pressure regulator, the average sound absorption rate was 15%.

When the sound absorbing layer 10 of melanin foam having a density of 8 kg / m 3 was installed outside the peripheral pipe 1 of the pressure regulator, the average noise measured by the first microphone MIC1 was 90 dB, and the second microphone MIC2. The average noise measured was 104 dB as shown in FIG. 2E, and the average noise measured by the third microphone MIC3 was 96 dB. The average sound absorption rate when the sound absorption layer 10 of the melanin foam of 8 kg / m <3> density was provided outside the periphery piping 1 of a constant pressure regulator was 13%.

Therefore, the sound absorbing material for noise attenuation according to the first embodiment of the present invention is formed of a polyurethane foam having a density of 150 kg / m 3 representing an average flaw rate among the materials, and the sound absorbing layer 10 surrounding the peripheral pipe 1 of the pressure regulator. ). As a result, the sound absorbing material for noise attenuation according to the first embodiment of the present invention can obtain a large damping effect of the noise of the price ratio regulator.

On the other hand, the experiments showed that the sound absorbing layer 10 has a larger sound insulation effect as the thickness is thicker. Therefore, the sound absorbing layer 10 of the sound absorbing material for noise damping according to the first embodiment of the present invention may be used by overlapping several layers of polyurethane foam having a density of 150 kg / m 3.

3 is a view showing a sound absorbing material for noise reduction according to a second embodiment of the present invention.

Referring to FIG. 3, the sound absorbing material for noise damping according to the second embodiment of the present invention includes a sound absorbing layer 10 surrounding the outside of the peripheral pipe 1 of the pressure regulator and a 0.5 mm aluminum covering the outside of the sound absorbing layer 10. It is provided with a sound insulating layer 20 formed.

The sound absorbing material for noise attenuation according to the second embodiment of the present invention has a sound absorbing layer 10 of the first embodiment of the present invention in order to obtain a larger attenuation effect of the static pressure noise than the damping effect of the static pressure noise of the first embodiment of the present invention. The experiment was performed to further surround the sound insulation layer 20 formed of 0.5 mm aluminum in the materials used in the experiment for selecting the noise and the noise around the regulator.

Table 2 is a table showing the noise measured from the first to third microphones in the experiment according to the second embodiment of the present invention.

Sound absorbing material MIC1 MIC2 MIC3 Sound absorption No sound absorption layer 96 dB 117 dB 100 dB - Polyurethane foam with a density of 28㎏ / ㎥ 91 dB 97 dB 95 dB 21% Polyurethane foam with a density of 150㎏ / ㎥ 89 dB 92 dB 95 dB 27% Polyurethane foam-memory foam with a density of 70㎏ / ㎥ 88 dB 96 dB 95 dB 22% Melanin foam of 8㎏ / ㎥ density 88 dB 97 dB 96 dB 21%

Referring to Table 2, the sound insulation layer formed of a sound absorbing layer 10 of 28 kg / m 3 polyurethane foam and a 0.5 mm aluminum covering the outside of the sound absorbing layer 10 outside the peripheral pipe 1 of the pressure regulator. 20), the average noise measured by the first microphone MIC1 is 91 dB, the average noise measured by the second microphone MIC2 is 97 dB as shown in FIG. 3A, and the third microphone MIC3. The average noise measured was 95 dB. When the sound absorbing layer 10 of 28 kg / m <3> density polyurethane foam and the sound insulation layer 20 formed from 0.5 mm aluminum which encloses the outside of the sound absorbing layer 10 are installed in the outer periphery of the constant pressure pipe 1. The average sound absorption of was 21%.

When the sound absorbing layer 10 made of polyurethane foam having a density of 150 kg / m 3 and the sound insulating layer 20 formed of 0.5 mm aluminum surrounding the outside of the sound absorbing layer 10 are provided outside the peripheral pipe 1 of the pressure regulator. The average noise measured by the first microphone MIC1 is 89 dB, the average noise measured by the second microphone MIC2 is 92 dB as shown in FIG. 3B, and the average noise measured by the third microphone MIC3 is 95 dB. When the sound absorbing layer 10 made of polyurethane foam having a density of 150 kg / m 3 and the sound insulating layer 20 formed of 0.5 mm aluminum surrounding the outside of the sound absorbing layer 10 are provided outside the peripheral pipe 1 of the pressure regulator. The average sound absorption of was 27%.

A sound absorbing layer 10 formed of a polyurethane foam-memory foam having a density of 70 kg / m 3 and a sound insulating layer 20 formed of 0.5 mm aluminum surrounding the outside of the sound absorbing layer 10 is disposed outside the peripheral pipe 1 of the pressure regulator. When installed, the average noise measured by the first microphone MIC1 is 88 dB, the average noise measured by the second microphone MIC2 is 96 dB, as shown in FIG. 3C, and the measured by the third microphone MIC3. The average noise was 95 dB. A sound absorbing layer 10 formed of a polyurethane foam-memory foam having a density of 70 kg / m 3 and a sound insulating layer 20 formed of 0.5 mm aluminum surrounding the outside of the sound absorbing layer 10 is disposed outside the peripheral pipe 1 of the pressure regulator. The average sound absorption rate at the time of installation was 22%.

When the sound absorbing layer 10 of melanin foam having a density of 8 kg / m 3 and the sound insulating layer 20 formed of 0.5 mm aluminum surrounding the outside of the sound absorbing layer 10 are provided outside the peripheral pipe 1 of the pressure regulator. The average noise measured by the first microphone MIC1 is 88 dB, the average noise measured by the second microphone MIC2 is 97 dB, as shown in FIG. 3D, and the average noise measured by the third microphone MIC3 is 96 dB. It was. When the sound absorption layer 10 of the melanin foam of density 8 kg / m <3> and the sound insulation layer 20 formed from 0.5 mm aluminum which encloses the outside of the sound absorption layer 10 are provided in the outer side of the peripheral piping 1 of a pressure regulator. The average sound absorption was 21%.

Accordingly, the sound absorbing material for noise damping according to the second embodiment of the present invention is a sound absorbing layer 10 formed of a polyurethane foam having a density of 150 kg / m 3 exhibiting an average flaw rate, and 0.5 mm aluminum to be formed of a sound absorbing layer 10. It is provided with a sound insulation layer 20 surrounding the outside of the. As a result, the sound absorbing material for noise attenuation according to the second embodiment of the present invention can obtain a greater attenuation effect of the noise of the pressure regulator than the attenuation effect of the static pressure noise of the first embodiment of the present invention.

Here, the sound insulation layer 20 of the sound absorbing material for noise attenuation according to the second embodiment of the present invention may not only obtain a larger attenuation effect of the noise of the pressure regulator, but also for noise attenuation according to the second embodiment of the present invention. The sound absorbing layer 10 of the sound absorbing material is protected.

Therefore, the sound absorbing material for noise attenuation according to the second embodiment of the present invention may increase the lifespan of the sound absorbing material for noise attenuation by providing a sound insulation layer 20 surrounding the outside of the sound absorbing layer 10.

On the other hand, according to the experiment, the thicker the sound insulation layer 20 was shown that the larger the sound insulation effect. Therefore, the sound insulation layer 20 of the sound absorbing material for noise reduction according to the second embodiment of the present invention is not limited to 0.5 mm aluminum. However, in consideration of the price and the like of the sound absorbing material for noise attenuation, 0.5 mm aluminum is preferable as the material of the sound insulation layer 20.

And, comparing Table 1 according to the experiment according to the first embodiment of the present invention and Table 2 according to the experiment according to the first embodiment of the present invention, if the sound absorbing material for noise attenuation is provided with a sound insulating layer 20, Regardless of the material of the layer 10, it can be seen that the damping effect of the static pressure noise is improved. Therefore, the sound absorbing material for noise damping according to the present invention does not limit the material of the sound absorbing layer 10 to a polyurethane foam having a density of 150 kg / m 3.

On the other hand, as the sound insulation layer 20 is formed of aluminum, during the operation of detaching the sound absorbing material for noise attenuation according to the second embodiment of the present invention to the peripheral pipe 1 of the pressure regulator, the workers are provided with the sound insulation layer 20, that is, aluminum. You can get hurt. Therefore, the sound absorbing material for noise damping according to the second embodiment of the present invention further includes a rubber cover 21 surrounding the outer portion of the sound insulation layer 20 as shown in FIG. 5. Accordingly, the workers may not be injured in the sound insulation layer 20 during the operation of detaching the sound absorbing material for noise damping according to the second embodiment of the present invention to the peripheral pipe 1 of the pressure regulator.

6 is a view showing a sound absorbing material for noise attenuation according to a third embodiment of the present invention.

Referring to FIG. 6, the sound absorbing material for noise damping according to the third embodiment of the present invention further includes a waterproof layer 30 between the peripheral pipe 1 of the pressure regulator and the sound absorbing layer 10.

Table 3 is a table showing the noise measured from the first to third microphones in the experiment according to the third embodiment of the present invention.

Sound absorbing material Water input MIC1 MIC2 MIC3 Sound absorption Polyurethane foam with a density of 150㎏ / ㎥ × 90 dB 95 dB 97 dB 23% Polyurethane foam with a density of 150㎏ / ㎥ ○ 90 dB 98 dB 96 dB 19%

Referring to Table 3, when the sound absorbing layer 10 of polyurethane foam having a density of 150 kg / m 3 is installed outside the peripheral pipe 1 of the pressure regulator, and the water is introduced into the sound absorbing layer 10, the first microphone The average noise measured by MIC1 was 90 dB, the average noise measured by the second microphone MIC2 was 98 dB as shown in FIG. 7, and the average noise measured by the third microphone MIC3 was 96 dB. That is, in the sound absorbing material for noise reduction, when water is injected into the sound absorbing layer 10, the average sound absorption rate is reduced. A large temperature difference occurs when the gas moves in the peripheral pipe 1 of the pressure regulator and when the gas does not move, and water is generated in the peripheral pipe 1 of the pressure regulator due to the temperature difference.

Therefore, the sound absorbing material for noise damping according to the third embodiment of the present invention further includes a waterproof layer 30 between the peripheral pipe 1 of the pressure regulator and the sound absorbing layer 10. As a result, in the sound absorbing material for noise attenuation according to the third embodiment of the present invention, moisture generated in the peripheral pipe 1 of the pressure regulator is prevented from being introduced into the sound absorbing layer 10, thereby obtaining a large attenuation effect of the static pressure noise.

Although not shown in FIG. 5, the sound absorbing material for noise damping according to the third embodiment of the present invention may further include a sound insulating layer 20 surrounding the sound absorbing layer 10.

On the other hand, the sound absorbing material for noise attenuation according to embodiments of the present invention further includes a structure for freely detaching the sound absorbing layer 10 from the peripheral pipe 1 of the pressure regulator.

8 illustrates an example of a structure for freely detaching the sound absorbing layer 10 from the peripheral pipe 1 of the pressure regulator.

Referring to FIG. 8, the structure for freely detaching the sound absorbing layer 10 from the peripheral pipe 1 of the pressure regulator includes a ring 11 formed at one outside of the sound absorbing layer 10 and the other end of the sound absorbing layer 10. It is provided with a button 12 is inserted into the ring 11 and engaged with the ring (11). The button 12 has a first surface h1 that is lower than the height of the ring 11 and a second surface h2 that is higher than the height of the ring 11. Therefore, when the first surface h1 of the button 12 is inserted into the ring 11 first, the second surface h2 of the button 12 is engaged with the ring 11 and the sound absorbing layer 10 is connected to the peripheral pipe of the pressure regulator. Wrap (1). The button 12 is formed of an elastic member. Therefore, when pressure is applied to the second surface h2 of the button 12, the second surface h2 of the button 12 is lowered to release the engagement with the ring 11 while the sound absorbing layer 10 is close to the periphery of the pressure regulator. The pipe 1 is dropped.

An example of a structure for freely detaching the sound absorbing layer 10 from the peripheral pipe 1 of the pressure regulator is not limited to the example shown in FIG. 8, and the sound absorbing layer 10 may be freely detached from the peripheral pipe 1 of the pressure regulator. Any structure is possible as long as it is a structure of a shape.

1 is a view showing a sound absorbing material for noise reduction according to a first embodiment of the present invention.

2a to 2e are experimental data for selecting the material of the sound absorbing layer according to the first embodiment of the present invention.

3 is a view showing a sound absorbing material for noise attenuation according to a second embodiment of the present invention.

4A to 4D are experimental data for selecting a material of a sound absorbing layer according to a second embodiment of the present invention.

5 is a view showing another example of the sound absorbing material for noise damping according to the second embodiment of the present invention.

6 is a view showing a sound absorbing material for noise attenuation according to a third embodiment of the present invention.

Figure 7 is an experimental data carried out after administering water to the sound absorbing material for noise attenuation of the present invention.

8 is a view showing another example of the sound absorbing material for noise damping according to embodiments of the present invention.

<Explanation of symbols for the main parts of the drawings>

1: piping 10: sound absorption layer

11: hook 12: button

20: sound insulation layer 21: rubber cover

30: waterproof layer

Claims (9)

Peripheral piping of the pressure regulator; Sound absorbing material for noise damping characterized in that it comprises a sound absorbing layer formed of polyurethane foam of 150kg / ㎥ density surrounding the outside of the peripheral pipe of the constant pressure. The method according to claim 1, Sound absorbing material for noise damping, characterized in that it further comprises a sound insulation layer surrounding the outside of the sound absorbing layer. The method according to claim 2, The sound insulation layer is a sound absorbing material for noise damping, characterized in that formed of 0.5mm aluminum. The method according to claim 1 or 2, Sound absorbing material for noise attenuation, characterized in that it further comprises a waterproof layer between the peripheral pipe of the pressure regulator and the sound absorbing layer. Peripheral piping of the pressure regulator; A sound absorbing layer surrounding the outside of the peripheral pipe of the pressure regulator; Sound absorbing material for noise damping, characterized in that it comprises a sound insulation layer formed of aluminum surrounding the outside of the sound absorbing layer. The method according to claim 5, The sound-absorbing layer is formed of any one of 150 kg / m 3 polyurethane foam, 28 kg / m 3 polyurethane foam, 70 kg / m 3 polyurethane foam-memory foam, and 8 kg / m 3 density melanin foam. Sound absorbing material for noise attenuation, characterized in that. The method according to claim 5, The sound insulation layer is a sound absorbing material for noise damping, characterized in that formed of 0.5mm aluminum. The method according to claim 5, Sound absorbing material for noise attenuation, characterized in that it further comprises a waterproof layer between the peripheral pipe of the pressure regulator and the sound absorbing layer. The method according to claim 5, Sound absorbing material for noise reduction, characterized in that it further comprises a rubber cover surrounding the outer portion of the sound insulation layer.

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