KR101122731B1 - Soundproofing apparatus and method utiilizing an active sound field control device and a solar heat collector - Google Patents

Abstract

The present invention relates to an active sound field control soundproof device for reducing the sound diffracted by the sound incident on the top of the soundproof wall when passing through the moving noise source and a passive resonance noise reducer for reducing the noise.

The disclosed soundproofing device is characterized in that it comprises a resonance-type noise reducer for reducing the noise in the high-frequency region and an active sound field control unit for reducing the noise in the low-frequency region, soundproof wall, sound absorbing material and solar collector plate.

In addition, the present invention provides an effect that solves the construction problems or maintenance problems that must be installed spaced apart from the active sound field control unit, and the passive noise reducer that is large in size to reduce the noise of the long frequency band It provides the effect of minimizing, and provides the noise reduction effect of the broadband effect by using the active sound field control device and the resonance noise reducer in combination, and the power control through the switching control of the active sound field control device for each frequency band when using the active sound field control technology Provides the effect of reduced consumption.

In addition, the adaptive sound field control soundproofing method of the present invention includes a frequency band detection process for detecting a low frequency band when passing a moving noise source and controlling on / off switching of an active sound field controller, and detecting a frequency band and operating an active sound field controller. A second sound source output process for determining the amplitude and phase of the second sound source for minimizing diffraction sound pressure and outputting the second sound source, and the second sound source when the low frequency band of the mobile noise source is not detected after the second sound source output It characterized in that it comprises a second sound source output termination process for terminating the.

Active, sound field control, resonance type, sound insulation, sound absorption, active, noise, noise

Description

SOUND PROOFING APPARATUS AND METHOD UTIILIZING AN ACTIVE SOUND FIELD CONTROL DEVICE AND A SOLAR HEAT COLLECTOR}

The present invention relates to an active sound field control soundproof device for reducing the sound diffracted by entering the top of the soundproof wall when a moving noise source approaches and passes, and a passive resonance noise reducer for reducing the noise.

In general, a device using a sound barrier or a noise reducer is frequently used to block noise when passing through a moving noise source.

Existing resonant noise reducer is a technology to set the resonant frequency for the frequency band of noise to be reduced and to design the internal size and overall size and shape to match the set resonant frequency, and the existing sound absorbing noise barrier reduces the thickness of sound absorbing material. This technology is designed according to the frequency band of the noise to be reduced according to the sound absorbing material. In addition, the existing active noise reducer is a technology for outputting a second sound source to measure the diffraction sound pressure to cancel the diffracted sound to reduce the diffracted sound.

All three technologies have narrowband characteristics that reduce noise within the designed frequency range. As described above, when the frequency band of the noise is outside the predetermined frequency band in the designed narrow band, in the above-described three techniques, there is a sound absorbing position where the soundproof wall effect is rather deteriorated. In particular, in order to reduce noise in a long wavelength region, the size of the resonant noise reducer or the sound insulation wall must be increased according to the length of the wavelength, thus losing the meaning of the top noise reducer to improve the sound insulation effect at a lower cost. It is the same thing.

In general, the existing top device technology is numerically analyzed by considering only the noise source incident toward the top of the soundproof wall at a height close to the ground, such as electric noise caused by road noise or the wheel / rail contact of the railway. Most of this is. However, in the case of railroads, the main source of noise exists not only in the lower electric noise, but also in heights such as locomotives, power units, current collectors, and upper bodies.

Examples of the prior art for reducing the noise is the "active sound muffler and active sound muffler" of the Republic of Korea Patent No. 10-0521823 which measures the sound to diffract when passing the moving noise source and outputs a second sound source to reduce the sound pressure diffraction Method "(prior art 1).

1 and 2 relates to an active sound muffler for controlling noise source removal and sound field according to the prior art 1.

As shown in Figs. 1 and 2, the active sound muffler 10 of the prior art includes a control microphone 11 for measuring a sound source, a control circuit 12 for controlling an additional sound source, and a control loudspeaker 13 that is an additional sound source. It is configured to include).

The control microphone 11 is disposed above the soundproof wall S at a predetermined position described later to detect sound pressure or sound intensity of the diffracted sound.

The control circuit 12 has a phase opposite to the phase of diffraction sound from the control loudspeaker 13 to minimize the signal detected by the control microphone 11 based on the output of the control microphone 11. Generates sound

The control loudspeaker 13 is installed on the side of the sound muffled side in the soundproof wall (S). The driving operation of the control loudspeaker 13 is controlled by the control circuit 12. The control loudspeaker 13 may optionally be installed on the upper surface of the soundproof wall.

In the above-described prior art, a microphone or a speaker needs to be installed around the soundproof wall S, so there is a construction problem or a maintenance problem where the existing soundproofing device and the soundproof wall S are installed.

In addition, the above-mentioned conventional technology has another problem in that a technique for controlling and minimizing the sound pressure at the top of the soundproof wall with an active sound field control technology requires additional power supply and the required amount increases proportionally according to the number of speakers or the number of sensors. .

In addition, the above-described conventional technology has another problem that the reduction effect on the noise source incident from the upper side is not considered high because only the noise source at the bottom is considered when the moving noise source passes.

The present invention is to solve the problems of the prior art, it is an object to solve the construction problems or maintenance problems that must be installed spaced apart from the soundproof wall microphone or speaker.

In another aspect, the present invention is to solve the above problems of the prior art, another object of the present invention is to solve another problem of increasing the size of the passive noise reducer in order to minimize the noise of a long frequency band.

In addition, the present invention is to solve the above-mentioned problems of the prior art, another object of the present invention is to solve the problem that can reduce noise only in narrow band by using an active sound field control device or a resonance type noise reducer separately. .

In addition, the present invention is to solve the above-mentioned problems of the prior art, it is another object to solve the problem that the reduction effect on the noise source incident from the upper side is not considered high considering only the noise source at the bottom when passing the moving noise source.

In another aspect, the present invention is to solve the above-mentioned problems of the prior art, another object of the present invention is to solve another problem of high power consumption by always operating when using an active sound field control device.

Eco-friendly soundproof wall technology using the adaptive sound field control soundproof device and solar collector plate of the present invention for achieving the above object, includes a resonance noise reducer and monitoring unit, an active sound field control unit, a soundproof wall, sound absorbing material and solar collector plate Characterized in that the configuration.

The resonance type noise reducer includes a perforated surface of the resonance type noise reducer in order to reduce noise in the mid-frequency region of the noise source when the mobile noise source passes, and the inside of the resonance type noise reducer is divided into a plurality of parts. It includes an inner space, characterized in that it is configured to include an appearance close to the circular columnar shape in order to reduce the energy transmitted when the sound is diffracted and not absorbed by the resonance noise reducer.

In addition, the resonance type noise reducer sets the mobile noise source and the measurement unit through a local measurement or a virtual simulation space or a program for measuring the noise by installing the measurement unit up to several tens of meters from the ground where noise is required when the mobile noise source passes. In order to analyze the noise through the simulation to reduce the noise, the size of the resonance-type noise reducer and the internal space and the shape of the frame is characterized in that it is selectively configured.

The monitoring unit is installed at the beginning of the sound barrier, characterized in that configured to measure the approach of the moving noise source.

The active sound field control unit may include a measuring unit, a processing unit, a control unit, an output unit, and a switching unit to reduce the diffraction sound pressure.

The active sound field controller detects the sound pressure diffraction and transmits the detected signal to the processing unit, and analyzes the signal received by the measuring unit to transmit an on / off switching control signal of the active sound field controller to the switching unit. To determine the amplitude and phase of the second sound source to minimize the diffracted sound source, and to control the amplitude and phase of the second sound source based on the processing unit for transmitting a second sound source control signal to the control unit, the signal received from the processing unit And a control unit for transmitting a second sound source output signal to the output unit, and an output unit for receiving a second sound source output signal from the control unit and outputting a second sound source.

The adaptive sound field control soundproofing method of the present invention is active when detecting a frequency band and amplitude to reduce noise when approaching a moving noise source or when a frequency band and amplitude of noise is detected for a predetermined time or more when approaching a moving noise source. Frequency band detection process to control the on / off switching of the sound field control section, and to control the amplitude and phase of the second sound source and to output the second sound source in order to minimize the sound pressure diffraction after detecting the frequency band and turning on the active sound field controller. And a second sound source output process of terminating the output of the second sound source when the second sound source is not detected and the frequency band is not detected after the second sound source is output.

The present invention is to solve the problems of the prior art described above, and an object of the present invention is to provide an effect of solving a construction problem or a maintenance problem in which a microphone or a speaker is spaced apart from a soundproof wall.

In another aspect, the present invention is to solve the above-mentioned problems of the prior art, and another object of the present invention is to provide an effect of minimizing a passive noise reducer that is large in size to minimize noise in a long frequency band.

In addition, the present invention is to solve the above-mentioned problems of the prior art, it is another object to provide a noise reduction effect of a wide range by using a combination of an active sound field control device and a resonance noise reducer.

In addition, the present invention is to solve the above-mentioned problems of the prior art, it is another object to provide a noise reduction effect for the noise source incident from the upper side as well as the lower noise source when the moving noise source passes.

In another aspect, the present invention is to solve the problems of the prior art, it is another object to provide an effect of reducing power consumption through the switching control of the active sound field control device for each frequency band when using the active sound field control technology.

Prior to the description of the specific content for the practice of the invention the definition of the terms used in the present invention are as follows.

The moving noise source refers to generating noise while moving like a car, a train or an airplane.

Diffraction sound refers to the sound that noise passes over the soundproof wall.

Hereinafter, an eco-friendly soundproofing wall technology using an adaptive sound field control soundproof device and a solar collector plate according to an embodiment of the present invention will be described with reference to the drawings.

3 is a perspective view of a soundproofing device including an active sound field control unit 100 and a resonance type noise reducer 200, a soundproof wall 300, a solar collector plate 400, and a sound absorbing material 500, and FIG. 3 is a front view and a side view of the soundproofing device of FIG. 5, and FIG. 5 is a perspective view and a front view and a side view of the resonance type noise reducer 200, and FIG. 6 is the active sound field control unit inside the resonance type noise reducer 200. It is a block diagram of (100).

The active sound field control unit 100 analyzes the diffraction sound measured by the measuring unit 110 and the measuring unit 110 for measuring the sound diffracted when the moving noise source passes, and the active unit to the switching unit 150 A control unit 120 for transmitting an on / off switching control signal of the sound field control unit 100, a control for receiving a signal of the sound pressure analyzed from the processing unit 120 and transmitting a second sound source output signal to the output unit 140 The control unit 130, an output unit 140 for receiving a second sound source output signal from the control unit 130, and outputting a second sound source, and the on / off switching of the active sound field control unit 100 from the processing unit 120. And a switching unit 150 for receiving a control signal and controlling on / off switching of the active sound field control unit 100.

In addition, the active sound field control unit 100 may be configured in the resonance type noise reducer 200 according to an embodiment of the present invention.

The monitoring unit (not shown) is separately installed at the start position of the soundproof wall 300 and configured to detect the noise detection time of the moving noise source or the frequency amplitude of the moving noise source for at least 1 second when the moving noise source approaches. do.

In addition, the monitoring unit (not shown) is composed of a spectrum analyzer or a comparator, such as when approaching the moving noise source detects the frequency band and amplitude of the moving noise source, or when approaching the moving noise source for more than a certain time the frequency band and amplitude of the moving noise source When sensing, the conductive sound field controller 100 is electrically connected to the processing unit 120 so as to control on / off switching of the active sound field control unit 100.

The measurement unit 110 monitors the sound pressure diffracted to the upper portion of the soundproof wall 300 when the moving noise source passes, and the like, such as an error microphone capable of transmitting the monitored diffraction sound pressure to the processing unit 120. It is configured to include.

In addition, the measurement unit 110 is the output unit 140 and the measurement unit 110 in the resonance noise reducer 200 in a place where it is possible to minimize the sound pressure diffraction when passing the moving noise source. It is configured to be installed.

In addition, the measuring unit 110 installs the measuring unit 110 from the ground to several tens of meters when the mobile noise source passes to minimize the sound diffracted through the second sound source signal output from the output unit 140. To measure the frequency band and amplitude of the noise, or to move to a simulated simulation space or simulation program, set the noise source and the measurement unit 110, where it is easy to measure the sound diffracted through the simulation analysis of the noise. It is configured to be attachable.

In the embodiment of the present invention, the measuring unit 110 is attached to the resonance type noise reducer 200.

The processor 120 analyzes the sound pressure diffracted from the measurement unit 110 and transmits a second sound source control signal for controlling the amplitude and phase of the second sound source to the controller 130 to minimize the diffracted sound pressure. do.

In addition, the processing unit 120 transmits a switching control signal to the switching unit 150 by analyzing the amplitude of the frequency band and the frequency band of the noise source through the signal received from the measuring unit 110 when the moving noise source passes. Can be configured.

In addition, the processor 120 may determine the frequency (90 Hz ~ 330 Hz) band and the amplitude of the selective region during the passage of a moving noise source through a spectrum analyzer, a comparator or a band pass filter as in the embodiment of the present invention. Can be configured.

In addition, the processing unit 120 is the active sound field when the monitoring unit (not shown) is installed at the start position of the soundproof wall 300 exceeds the frequency and amplitude of the moving noise source or the noise detection time of the moving noise source. The on / off switching control signal of the controller 100 may be configured to be transmitted to the switching unit 150.

The control unit 130 receives the second sound source control signal received from the processing unit 120, amplifies the amplitude of the second sound source and controls the phase so as to cancel the sound pressure diffracted by the noise source and the output unit 140 Is configured to transmit a second sound source output signal.

In addition, the controller 130 may be configured to include amplification and phase control characteristics such as an amplifier capable of controlling phase and amplitude.

The output unit 140 is configured to include a speaker as in the embodiment of the present invention to output a second sound source through the second sound source output signal received from the control unit 130.

In addition, the output unit 140 has a predetermined inclination angle between the 90 ~ 145 degrees the highest noise reduction effect according to the frequency band and the sound receiving position of the noise to be reduced in one embodiment of the present invention the resonance noise It may be configured inside the reducer 200.

The switching unit 150 is configured to receive power from the solar collector plate 300, the switching unit 150 is the active sound field control unit in accordance with the on / off switching control signal of the processing unit 120 ( 100) on / off.

The resonance type noise reducer 200 may include a punching hole 210, and may include a polygonal shape close to a cylindrical shape in order to reduce diffraction of the noise source when passing through the moving noise source.

In addition, since the resonance type noise reducer 200 is attached to the upper end of the soundproof wall, it may be configured to include a weather resistant material such as polycarbonate resin that can be used for various weather changes without yellowing phenomenon even if used for a long time.

In addition, the resonance-type noise reducer 200 is configured to include a perforated surface shape with a hole in the outer surface in order to improve the performance of reducing the noise corresponding to the high-frequency region when passing through the moving noise source.

In addition, the resonance type noise reducer 200 may be designed as a regular hexagonal pillar having six inner spaces and a width and a side of 15m to 20cm of 1.4m to 2.7m as one embodiment of the present invention.

In addition, the resonance type noise reducer 200 is installed through the local measurement or virtual simulation space or a program to measure the frequency band of the noise by installing a measuring unit from the ground to the place where the noise reduction is required when passing the mobile noise source. By setting the moving noise source and the measurement unit through the simulation analysis, the size of the resonance type noise reducer and the internal space and the shape of the frame is characterized in that it is selectively configured.

In addition, the resonance type noise reducer 200 is the overall size and shape, so that a plurality of internal spaces different from the embodiment of the present invention to increase the noise reduction according to the frequency band and the sound receiving position of the noise to be reduced Can be designed as.

The drilling hole 210 includes a plurality of drilling holes 210 to match the resonance frequency for the frequency band of the noise to be reduced when passing through the moving noise source, the diameter of each of the drilling holes 210 is designed result It can change depending on the value.

The soundproof wall 300 is installed at a position that requires soundproofing when passing the moving noise source.

In addition, the sound barrier 300 may be designed in consideration of the height of the sound barrier 300 in consideration of the frequency band to reduce the sound absorbing position and noise.

The solar collector plate 400 may be attached to the side of the noise source of the soundproof wall 300 when the mobile noise source passes, and the solar collector plate 400 may be attached to maintain a predetermined inclination angle to receive sunlight. In addition, the solar collector plate 400 may be installed at a predetermined distance apart to secure a safety distance when the mobile noise source passes.

In addition, the solar collector plate 400 is configured to supply power to the active sound field control unit 100 and, if necessary, power to the sound absorbing material 500.

The sound absorbing material 500 is attached to the side of the noise source of the sound barrier 300, the sound absorbing material 500 is configured to include an environmentally sound absorbing material.

In addition, the sound absorbing material 500 may be configured to include a plant sound absorbing material to maintain a four-season recording when a special filter for absorbing and removing fine dust is built-in.

The processing unit 120 of the active sound field control unit 100 may determine the phase and amplitude of the second sound source that can minimize the sound pressure diffraction through the following equation.

In the case of Equation 1, the noise is measured by picking an arbitrary point on the surface of the resonance noise reducer 200 to measure the sound pressure diffraction. In this case, the measurement unit 110 indicates that it is measured through at least one. In this case, Min means that the sum of the squares of the sound pressures Ptot measured by the at least one measurement unit 110 becomes the minimum.

The sound pressure Ptot measured by the measuring unit 110 may be calculated as shown in Equation 2, which is a sound pressure formed by adding a sound pressure Pscreen and a resonance noise reducer formed in a space where a soundproof wall exists. Pedge) and sound pressure (Psec) formed by the second sound source controlled by the control element αk.

The amplitude and phase of the second sound source are adjusted so that the sum of each Ptot (m) of Equation 2 is minimized.

In the present invention described above, the noise of a long wavelength low frequency such as a freight train, a high-speed train, or a green light train used in Korea may be targeted.

Characteristics of the frequency band and the noise height of the trains used in Korea are shown in FIGS. 8A and 8B.

Referring to a and b of FIG. 8, the intensity of noise according to the frequency band and the measurement height of the noise can be seen.

The present invention described above uses a noise reduction frequency band of the resonance type noise reducer 200 as well as a noise frequency band which can be reduced in the resonance type noise reducer 200 by using the active sound field control unit 100 in combination. It can be extended to an additional low frequency region (90Hz ~ 330Hz) to reduce the noise of the wide-band range, to reduce the noise to the sound absorbing position higher than the height of the soundproof wall 300, and higher than the height of the soundproof wall 300 Noise can be reduced from the location to the incident noise source.

The noise reduction effect for each frequency band improved through the present invention described above can be seen through FIGS. 9A and 9B.

9A and 9B, the x-axis represents frequency and the y-axis represents noise improvement.

In addition, the solid line in the graph of FIG. 9A shows the improvement of the noise when only the resonance type noise reducer is used, and the dotted line is the graph showing the noise level when the resonance type noise reducer and the active sound field control device are used together. .

In the graph of FIG. 9B, the noise improvement level of FIG. 9A is illustrated by the actual noise measuring device. The solid line of FIG. 9A represents the thin solid line of FIG. 9B, and the dotted line of FIG. 9A represents the thick dotted line of FIG. 9B.

Referring to Figure 7 will be described in detail the process of outputting the second sound source when detecting the noise source of the present invention.

When approaching a moving noise source, the monitoring unit (not shown) determines a frequency band (90 Hz to 330 Hz, hereinafter, 'target frequency') and amplitude detection of the target frequency band or noise detection for one second or longer to reduce noise. If the target frequency is not detected, the monitoring unit continuously determines the detection of the target frequency (S10; frequency detection determination).

When the target frequency band for reducing noise is detected in the frequency detection determination process, the processing unit 120 performs the on switching of the active sound field controller 100. (S20; active sound field controller operation)

When the target frequency band is detected in the process of S20, the active sound field controller is turned on, and the processor 120 determines the amplitude and phase of the second sound source for reducing the noise of the target frequency band. Second source phase and amplitude control)

When the phase and amplitude of the second sound source are determined, the processor 120 transmits a second sound source control signal to the amplification unit 130, and the amplification unit 130 that receives the second sound source control signal receives a second sound source. It is to control the amplitude and phase of the, and to output the second sound source output signal to the output unit 140. The output unit 140 receiving the second sound source output signal outputs a second sound source (S40; second sound source output).

In the second sound source output process, the measurement unit 110 continuously detects the target frequency band. If the target frequency continues to be detected, the second sound source repeats operation from the amplitude and phase control operation (S50; target frequency detection process).

If the target frequency is not detected in the target frequency detection process, the measurement unit 110 controls the off of the active sound field controller 100 by the switching unit 150 (S60; active sound field controller off operation).

When the active sound field controller is turned off, the output unit 140 ends the output of the second sound source. (S70; end of the second sound source output)

1 and 2 are views showing the configuration of an active sound muffler using the active sound field control device of the prior art,

3 is a perspective view of the soundproofing device according to the present invention;

4 is a side view and a front view of the soundproofing device according to the present invention;

5 is a perspective view, side view, and front view of a resonance noise reducer according to the present invention;

6 is a block diagram of an active sound field control unit combined with a resonance type noise reducer according to the present invention;

7 is a flowchart according to an embodiment of the present invention.

8a and 8b is a graph showing the noise according to the measurement position when passing the trains used in the country for the present invention.

9A and 9B are graphs showing noise reduction effects when the soundproofing apparatus is used.

DESCRIPTION OF THE RELATED ART [0002]

100: active sound field control unit 110: measuring unit

120: processor 130: controller

140: output unit 150: switching unit

200: resonance noise reducer 210: punched hole

300: soundproof wall

400: solar collector

500: sound absorbing material

Claims (9)

In the soundproofing device to reduce the noise and minimize the diffraction sound when passing through various mobile noise sources, A soundproof wall composed of a sound absorbing panel or a sound absorbing material capable of reducing the amplification of the sound by transmitting the reflected sound back; A resonance type noise reducer attached to an upper portion of the soundproof wall; A solar collector plate attached to the soundproof wall to generate power; A switching unit provided inside the resonance noise reducer to cancel noise by controlling an amplitude and a phase of a second sound source output according to a sound pressure signal detected from a moving noise source, and switching a power supply from the solar current collector; An active sound field control unit installed at a start position of the soundproof wall and including a monitoring unit detecting a frequency band and an amplitude of the noise when the moving noise source approaches, and a processing unit controlling on / off of the switching unit based on a detection signal of the monitoring unit Eco-friendly soundproofing device using an adaptive sound field control soundproof device and a solar collector, characterized in that consisting of. delete delete delete The method of claim 1, The surface of the resonance noise reducer is an eco-friendly soundproofing device using an adaptive sound field control soundproof device and a solar collector plate, characterized in that it comprises a cylindrical column or a polygonal shape. The method of claim 1, The solar contact plate maintains a predetermined inclination angle to receive an energy source from the sun and is attached to the soundproof wall to supply power to the soundproofing device. Soundproofing. The method of claim 1, The soundproof wall is made of an adaptive sound field control soundproof device and a solar collector, characterized in that it comprises an environmentally sound-absorbing panel or sound absorbing material that can reduce the amplification of the sound is reflected back when passing through the moving noise source. Eco-friendly soundproofing device. In the soundproofing method for reducing the noise and minimizing the diffraction sound when passing through various moving noise sources, Detects the frequency band and amplitude for switching on / off the power supply of the active sound field controller when approaching the moving noise source, and according to the frequency band of the moving noise source to be reduced by the monitoring unit installed at the start of the soundproof wall when the moving noise source passes. A frequency band for switching on / off the power supply of the active sound field controller, or switching the power supply of the active sound field controller on / off when a frequency band and amplitude of noise are detected by the monitoring unit for a predetermined time or more; Amplitude detection process, A second sound source output process of determining an amplitude and a phase of a second sound source for outputting a second sound source for minimizing sound pressure that turns on and diffracts the active sound field controller when detecting a frequency band; And a second sound source output process of terminating the output of the second sound source when the frequency band is not detected after the second sound source is output. delete

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