KR100936786B1 - Semi-active noise absorber system and noise absorbing method using the semi-active noise absorber system - Google Patents

Abstract

PURPOSE: A semi-active sound absorbing system, and an absorbing method using the same are provided to maximize absorbing performance by absorbing noise according to a change of frequency. CONSTITUTION: A semi-active sound absorbing system comprises a porous sound absorbing panel(10), expansion support devices(20), a noise input device(31), and an expansion control device(30). The porous sound absorbing panel is installed separating from the front surface of a wall(12) for forming a rear air layer(13) between the wall and the porous sound absorbing panel. The expansion support devices are installed between the porous sound absorbing panel and the wall. And the expansion support devices are expanded so that the thickness of the rear air layer is changed. Noise is inputted to the noise input device. The expansion control device analyzes a frequency of the noise transferred from the noise input device, and generates an expansion or contraction signal of the expansion support devices according to the analyzed result.

Description

Semi-Active Noise Absorber System and Noise Absorbing Method using the Semi-Active Noise Absorber System

The present invention relates to a semi-active sound absorbing system and a sound absorbing method using the same, and more particularly, to provide a sound absorbing performance by arranging porous plates having sound absorbing performance at intervals on a rigid wall. In order to maximize the sound absorbing performance, the frequency characteristics of the noise to be absorbed are identified, and the gap between the porous plate and the rigid wall is adjusted according to the frequency characteristic of the noise to actively absorb the noise of a specific frequency. Iii) The present invention relates to a semi-active sound absorption system and a sound absorption method using the same.

As a sound absorbing technology used to prevent noise, there is a method of installing a sound absorbing material (mainly made in the shape of a plate) made of a porous material such as porous concrete on a wall such as an inner wall, an outer wall, or a door of a building.

1 is a schematic view showing a shape in which the porous sound absorbing material 100 is installed on the wall 110. As shown in the drawing, the conventional porous sound absorbing material 100 is formed in a plate shape, and the porous sound absorbing material 100 is formed by the spacer 121 so as to form an air layer 120 behind the wall 110. Installed at intervals with the wall 110 surface. In particular, the porous sound absorbing material 100 is generally made of a porous plate in which a plurality of pores 101 in the form of through holes are formed perpendicular to the plate.

According to the existing research results, when the porous sound absorbing material 100 in the form of a porous plate formed with a plurality of voids 101 as described above spaced at the wall 110, between the porous sound absorbing material 100 and the wall 110 It is known that the frequency of the sound for maximizing the sound absorption effect varies depending on the interval of the space, that is, the thickness of the rear air layer 120.

2 to 4, the radius of the pores 101 formed in the porous sound absorbing material 100, the distance between the pores 101, and the thickness of the porous sound absorbing material 100 are constant at 0.3 mm, 2 mm, and 1 mm, respectively, and the rear air layer When the thickness of 120 is changed to 50 mm (FIG. 2), 20 mm (FIG. 3), and 5 mm (FIG. 4), a graph showing the frequency relationship between sound absorption rate and noise is shown. As can be seen in the figure, when the thickness of the rear air layer 120 is changed, the frequency band of the sound in which the sound absorption effect is maximized (maximum sound absorption rate) is also changed.

However, in the related art, when the porous sound absorbing material 100 having the porous plate shape is installed at the wall 110, only one predetermined interval, that is, only one predetermined thickness of the air layer, can absorb sound of a specific frequency band. There was a limit that effective sound absorption performance could not be achieved when noise with different frequency occurred.

The present invention was developed to overcome the limitations of the prior art as described above, in the installation of a porous sound absorbing material in the form of a porous plate on the wall at intervals from the wall, grasp the frequency characteristics of the generated noise suitable for sound absorption of the corresponding frequency In order to automatically adjust the distance between the porous sound absorbing material and the wall so as to maximize the sound absorbing performance by allowing the sound absorbing to be efficiently absorbed according to the frequency band of the generated noise.

In the present invention, as a means for achieving the above object, in order to form a rear air layer between the porous sound absorbing material in the form of a porous plate and the wall, the porous sound absorbing material is installed at intervals on the front surface of the wall, the rear air layer in the expansion By stretching the support device to adjust the thickness of the rear air layer, by analyzing the frequency band of the noise measured by the noise input device to calculate the thickness of the rear air layer that can maximize the sound absorption rate by the porous sound absorbing material, By allowing the stretchable support device to expand and contract to the calculated thickness, a sound absorption system and a sound absorption method for maximizing the sound absorption effect of the generated noise are provided.

In the present invention, as a specific means for achieving the above object, made of a porous plate of a porous material, a plurality of through-hole-shaped pores are formed perpendicular to the plate, the wall to form a rear air layer between the walls A porous sound absorbing plate and spaced at the front of the; An elastic support device configured to be stretched so that the porous sound absorbing plate is installed on the wall at intervals, and the thickness of the rear air layer formed between the porous sound absorbing plate and the wall is variable; A noise input device through which noise is input; Analyzing the frequency of the noise transmitted from the noise input device, and based on the diameter of the pores formed in the porous sound absorbing plate, the distance between the pores and the thickness of the porous sound absorbing plate itself, it is possible to achieve the optimal sound absorption rate for the frequency of the measured noise A semi-active sound absorbing system, comprising: a stretch control device for controlling the stretch support device by determining a thickness of the rear air layer to transmit a signal to the stretch support device to make the determined thickness of the back air layer. Is provided.

In the present invention, a porous sound absorbing plate made of a porous plate made of a porous material and formed with a plurality of pores in the form of through-holes perpendicularly to the plate is provided between the porous sound absorbing plate and the wall by a stretchable support. Installing at intervals on the front surface of the wall to form a rear air layer; Transmitting a signal of the noise measured by the noise input device through which the noise is input to the expansion and control device; The frequency of the noise transmitted from the noise input device is analyzed by the expansion and control device, and is optimized for the frequency of the measured noise based on the diameter of the pores formed in the porous sound absorbing plate, the distance between the pores, and the thickness of the porous sound absorbing plate itself. Determining a thickness of the rear air layer that can exhibit a sound absorption rate of; And transmitting a signal controlling the stretch support device from the stretch control device to the stretch support device to cause the stretch support device to stretch to create a determined thickness of the rear air layer. There is provided a semi-active sound absorption method characterized by exhibiting performance.

According to the present invention, by adjusting the thickness of the rear air layer formed between the porous sound absorbing material and the wall in the form of a porous plate, by analyzing the frequency of the sound to make noise to achieve a high sound absorption rate, to maximize the sound absorption performance of the porous sound absorbing material do.

In particular, even when the frequency of the generated noise is changed, since the thickness of the rear air layer can be automatically adjusted accordingly, there is an advantage that it is possible to continuously exhibit excellent sound absorption performance even with the frequency change of the noise.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described. The present invention has been described with reference to the embodiments shown in the drawings, which are described as one embodiment by which the technical spirit of the present invention and its core configuration and operation are not limited.

FIG. 5 shows a schematic diagram of a semi-active sound absorbing system according to the invention, and FIG. 6 shows a cross section along line A-A of FIG. 5.

As shown in the figure, the semi-active sound absorbing system according to the present invention includes a porous sound absorbing plate 10 which is provided at intervals on the front surface of the wall 12 so that a rear air layer 13 is formed between the walls 12. do. The porous sound absorbing plate 10 is made of a porous plate formed with a plurality of pores 11 in the form of through holes perpendicular to the plate, and may be made of a porous material such as porous concrete. However, it is not limited to porous concrete.

In the semi-active sound absorbing system according to the present invention, the porous sound absorbing plate 10 is spaced apart from the wall 12 so that the rear air layer 13 is formed between the rear surface of the porous sound absorbing plate 10 and the front surface of the wall 12. At the same time, the elastic support device 20 that can be stretched so as to vary the thickness of the space between the porous sound-absorbing plate 10 and the wall 12, that is, the rear air layer 13 is provided. That is, the porous sound absorbing plate 10 is installed on the wall 12 at intervals by using the stretchable support device 20.

Looking in more detail, the stretchable support device 20 is a device that can be stretched, for example, such as a hydraulic jack, one side is attached to the front surface of the wall 12 and the other side is attached to the porous sound absorbing plate 10, the porous sound absorbing plate While supporting the 10, the porous sound-absorbing plate 10 is to be installed on the wall 12 at intervals. As will be described later, the stretchable support device 20 extends or contracts in response to a signal from the stretch control device 30, so that the rear surface and the wall 12 of the porous sound absorbing plate 10 are adapted to the characteristics of the sound to be noised. The distance between the front surface of the (the thickness of the rear air layer) will be changed.

On the other hand, the semi-active sound absorbing system according to the present invention, by analyzing the noise input device 31 and the signal transmitted from the noise input device 31, the noise is input and analyzes the frequency band of the generated noise, According to the result includes a stretch control device 30 for generating a stretch or contraction signal of the stretch support device (20).

The noise input device 31 may be configured as a device for converting the input noise into an electrical signal and transmitting the sound when a sound is input, such as a microphone device. Therefore, to measure the noise using the noise input device (31). The noise signal input to the noise input device 31 is transmitted to the expansion control device 30. The expansion control device 30 may be configured, for example, by a computer, and analyzes the frequency of noise transmitted from the noise input device 31, and specifies the specification of the porous sound absorbing plate 10 installed on the wall 12. That is, based on data such as the diameter of the pores 11 formed in the porous sound absorbing plate 10, the distance between the pores 11, the thickness of the porous sound absorbing plate 10 itself, etc., it is possible to achieve an optimal sound absorption rate for the frequency of the measured noise. Determine the thickness of the air layer behind it.

Specifically, the theoretical background for determining the thickness D of the rear air layer will be described.

7 shows the thickness D of the rear air layer, the thickness t of the porous sound absorbing plate 10, the distance b between the pores 11 formed in the porous sound absorbing plate 10, the diameter d of the air gap 11, And a conceptual diagram for mathematically arranging the relationship between the angular frequency ω of sound.

In the present invention, in determining the thickness D of the rear air layer, an electro-acoustic model used when theoretically explaining the relationship between the porous sound absorbing plate and the pores formed therein is used. The electro-acoustic model introduces a circuit theory impedance calculation method to facilitate the calculation of acoustic impedance.

이며, ρ₀는 공기의 밀도로서 1.20 kg/㎥ 인 값이다. 또한 ω는 음파의 각 진동수(angular frequency)이고, η는 공기의 동적 점성(dynamic viscosity)로서 1.79×10^-5kg/(m·s) 인 값이다. c₀ 는 공기 중에서의 소리 속도인 340 m/s인 값이다. In FIG. 7, M means reactance, and R means resistance. Z _a means the impedance of the pores formed in the porous sound absorbing plate 10, and z _a denoted by the lowercase means the impedance of the porous sound absorbing plate 10 itself (the entire porous sound absorbing plate including the plate portion and the pores). Z (D) refers to the impedance of the rear air layer formed between the rear surface of the porous sound absorbing plate 10 and the front surface of the wall 12, and is summarized as in Equation 1 below. In Equation 1 j is

Ρ ₀ is the density of air, which is 1.20 kg / m 3. Ω is the angular frequency of sound waves, and η is the dynamic viscosity of the air, which is 1.79 × 10 ^-5 kg / (m · s). c ₀ is a value of 340 m / s, the sound velocity in air.

The relationship between the impedance z _a of the entire porous sound absorbing plate and the impedance Z _a of the pores formed in the porous sound absorbing plate and the reactance (M) and the resistance (R) from the conceptual diagram shown in FIG. Equation 5

In Equation 2 above, p represents the ratio of the area occupied by the pores in the plate, which is defined as in Equation 6. β is an acoustic Reynolds number, which is a parameter for stress caused independently by the pressure caused by the sound and the viscosity of the sound, and is defined as in Equation 7 below.

Therefore, the total impedance Z _all in the circuit shown in FIG. 7 can be represented by Equation 8.

If the sound absorption coefficient α of the sound absorption system is derived from Equations 1 to 8 as shown in Equation 9 below.

In Equation 9, when the acoustic absorption rate α becomes maximum, the denominator is minimum. When noise is generated using the porous sound absorbing material 10, the thickness t, the distance between the voids b, and the diameter d of the porous sound absorbing material 10 are predetermined values, and values vary according to circumstances. The only variable is the angular frequency (ω) for the sound and the thickness (D) of the background air layer to be determined. In other words, when a general expression (1) to 8, _all R is not a function of the D and ω in equation 9, _all R is a fixed value. Therefore, when the acoustic absorption rate α becomes the maximum, when the denominator of Equation 9 becomes the minimum, that is, when M _all is zero as shown in Equation 10. Therefore, the relational expression of Equation (11) holds for the maximum value α _max of the acoustic absorption rate α.

Meanwhile, in Equation 10, ω ₀ is a frequency to be controlled, that is, a measurement frequency for a sound to be noise. By substituting Equation 5 into Equation 10, Equation 12 can be derived, and D can be calculated through Equation 12.

In summary, the expansion control device 30 performs a known Fast Fourier Transform (FFT) operation on the noise signal input from the noise input device 31 to express the noise signal in frequency. The frequency band with the strongest strength is identified by converting to. The strongest frequency found in this way is ω ₀ in the above equation.

Subsequently, the expansion and contraction control device 30 has a known thickness t of the porous sound absorbing plate 10, a distance b between the pores 11 formed in the porous sound absorbing plate 10, and a diameter d of the air gap 11. When the user inputs the values of, the values are substituted into equations (7) and (12) to calculate the thickness (D) of the rear air layer that maximizes the sound absorption efficiency for the measured frequency ω ₀ . will be.

When the thickness D of the rear air layer suitable for sound absorption of the corresponding frequency is calculated and determined based on the measured frequency characteristic of the noise, the expansion control device 30 sends an operation signal to the expansion support device 20. Send it. The expansion and contraction support device 20 expands and contracts according to the signal of the expansion and contraction control device 30, thereby changing the thickness of the rear air layer to match the calculated value. That is, the stretch control device 30 stretches the stretch support device 20 in response to a signal, so that the distance between the rear surface of the porous sound absorbing plate 10 and the front surface of the wall 12 is equal to the determined thickness of the air layer behind the optimum. Adjust as much as possible.

According to the present invention, by analyzing the frequency characteristics of the generated noise by the expansion and contraction control device 30, it is possible to automatically adjust the thickness of the rear air layer so as to exhibit the optimal sound absorption rate for the frequency. Therefore, even if noise of different frequencies occurs, the sound absorption performance can be maximized. In other words, even if the noise is different in frequency according to the time, the thickness of the rear air layer is changed to exhibit the optimal sound absorption rate according to the frequency of the noise, the sound absorption performance is maximized.

As described above, the present invention is free from the passive sound absorbing form of the sound, and has a configuration of actively changing the sound absorbing state in accordance with the characteristics of the noise, thereby exhibiting excellent sound absorbing performance.

1 is a schematic view showing a shape in which a porous sound absorbing material is installed on a wall according to the prior art.

2 to 4 are graphs showing the change in sound absorption rate according to the thickness of the rear air layer formed between the porous sound absorbing material and the wall, respectively.

5 is a schematic diagram of a semi-active sound absorption system according to the present invention.

FIG. 6 is a cross-sectional view taken along the line A-A of FIG. 5.

7 is a conceptual diagram for mathematically arranging the relationship between the thickness of the rear air layer, the thickness of the porous sound absorbing plate, the distance between pores formed in the porous sound absorbing plate, the diameter of the air gap, and the angular frequency of sound.

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

10 porous sound absorbing plate

20 telescopic support

30 Expansion Control

Claims (4)

It is made of a porous plate made of a porous material, a plurality of pores 11 in the form of through holes perpendicular to the plate is formed, the front surface of the wall 12 so that the rear air layer 13 is formed between the walls 12 Porous sound absorbing plate 10 is installed at intervals on the; Stretch support device that is stretched so that the porous sound absorbing plate 10 is installed on the wall 12 at intervals, and at the same time the thickness of the rear air layer 13 formed between the porous sound absorbing plate 10 and the wall 12 is variable ( 20); A noise input device 31 through which noise is input; Analyzing the frequency of the noise transmitted from the noise input device 31, based on the diameter of the pores 11 formed in the porous sound absorbing plate 10, the distance between the pores 11 and the thickness of the porous sound absorbing plate 10 itself And expand and contract a signal that stretches the stretch support device 20 to make the determined thickness of the rear air layer by determining the thickness D of the rear air layer that can exhibit an optimal sound absorption rate with respect to the measured noise frequency. Semi-active sound absorbing system comprising a; stretch control device for controlling the support (20). The method of claim 1, The expansion and contraction control device 30, the thickness of the porous sound-absorbing plate 10, the distance between the gaps 11 formed in the porous sound-absorbing plate 10, and the diameter of the gap 11, which is already known by the user Substituting the equations (7) and (12), the semi-active sound absorption system is characterized by calculating the thickness (D) of the rear air layer whose sound absorption efficiency is maximum with respect to the frequency ω ₀ of the measured noise. (Equation 7)

(Equation 12)

(Equations 7 and 12 above, D is the thickness of the rear air layer to maximize the sound absorption efficiency with respect to the measured frequency of noise ω ₀ , t is the thickness of the porous sound absorbing plate 10, b is a porous sound absorbing plate Distance between the pores 11 formed in the (10), d is the diameter of the pores 11 formed in the porous sound-absorbing plate 10, ρ ₀ is the value of the air density of 1.20 kg / ㎥, ω ₀ is measured Angular frequency of the noise, η is the dynamic viscosity of the air, 1.79 × 10 ^-5 kg / (m · s), c ₀ is the sound velocity in the air, 340 m / is s.) The porous sound-absorbing plate made of a porous plate made of a porous material and having a plurality of porous sound-absorbing plates 10 having a plurality of pores 11 in the form of through-holes perpendicularly to the plate by the elastic supporter 20 that can be expanded and contracted. Installing at intervals on the front surface of the wall (12) such that a rear air layer (13) is formed between the (10) and the wall (12); Transmitting a signal of the noise measured through the noise input device 31 through which the noise is input to the expansion and contraction control device 30; The frequency of the noise transmitted from the noise input device 31 is analyzed by the expansion control device 30 to determine the diameter of the pores 11 formed in the porous sound absorbing plate 10, the distance between the pores 11, and the porous sound absorbing plate. (10) determining, based on the thickness of itself, a thickness D of the rear air layer that can exert an optimal sound absorption rate for the frequency of the measured noise; And Transmitting a signal for controlling the stretch support device 20 from the stretch control device 30 to the stretch support device 20 so that the stretch support device 20 stretches to make the determined thickness of the rear air layer. Semi-active sound absorption method, including; to exhibit a sound absorption performance suitable for the measured noise. The method of claim 3, In the step of determining the thickness (D) of the rear air layer in the expansion control device 30, The expansion control device 30, the thickness of the porous sound-absorbing plate 10, the distance between the gaps 11 formed in the porous sound-absorbing plate 10 and the diameter of the air gap 11, which is already known given by the user, Substituting equations (7) and (12), the semi-active sound absorption method is characterized by calculating the thickness (D) of the rear air layer whose sound absorption efficiency is maximum with respect to the measured frequency ω ₀ . (Equation 7)

(Equation 12)

(Equations 7 and 12 above, D is the thickness of the rear air layer to maximize the sound absorption efficiency with respect to the measured frequency of noise ω ₀ , t is the thickness of the porous sound absorbing plate 10, b is a porous sound absorbing plate Distance between the pores 11 formed in the (10), d is the diameter of the pores 11 formed in the porous sound-absorbing plate 10, ρ ₀ is the density of the air is 1.20 kg / ㎥, ω ₀ is measured Is the angular frequency of the noise, η is the dynamic viscosity of the air, 1.79 × 10 ^-5 kg / (m · s), c ₀ is the sound velocity in the air, 340 m / is s.)

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