JP5350914B2 - Noise monitoring system and noise monitoring method - Google Patents

Description

  The present invention relates to a noise monitoring system and a noise monitoring method for monitoring noise generated in construction work within a control value.

Especially at construction sites in urban areas, in the past, in order to disclose information to the neighborhood, etc., a signboard that shows the work schedule and work contents in the site can be installed, a viewing window is attached to a part of the temporary enclosure, In order to manage environmental problems such as noise in adjacent areas, a measurement unit for sound source exploration as described in Patent Document 1 is always installed.
The measurement unit described in Patent Document 1 includes two microphone pairs that are arranged at predetermined intervals on two straight lines that intersect with each other, and a fifth microphone that is not on a plane formed by these two microphone pairs. It has a microphone group consisting of

JP 2003-111183 A

By the way, the measurement unit described in Patent Document 1 requires at least five microphones to collect and measure noise from a noise source and to identify a noise source that emits noise to the neighborhood. However, there has been a desire to reduce the number of microphones used in order to reduce costs.
On the other hand, by reducing the number of microphones used, there is a desire not to reduce the performance of identifying a noise source that is generating noise to the neighborhood.
For this reason, it has been desired to develop a technique capable of not only reducing the number of microphones used to reduce costs but also exhibiting excellent sound source identification performance.

  An object of the present invention is to provide a noise monitoring system and a noise monitoring method that can reduce the cost and are excellent in the sound source identification performance of the noise exceeding the control reference value.

In order to solve the above problems, the invention according to claim 1 is a noise monitoring system, comprising: a plurality of noise sources arranged in a predetermined block among areas virtually divided into a plurality of blocks; Detection and measurement means disposed in at least two places in the area for detecting and measuring generated noise and enabling detection and measurement of noise from the predetermined block in which each noise source is disposed ;
Extracting means for frequency-analyzing the noise detected and measured by the detection measuring means, and extracting sound pressure data consisting of a dominant frequency band;
Comparing the sound pressure data of the noise from the predetermined blocks obtained by said detection measurement means and the extraction means, specifying the analysis sound pressure data at the maximum tone and becomes a point of the block of the predetermined block Specific means to
Comparison determination means for comparing and determining the sound pressure data for analysis in the block of the point that becomes the maximum sound source specified by the specifying means, and a preset management reference value,
When the comparison determination unit determines that the sound pressure data for analysis in the block at the point that becomes the specified maximum sound source is a value that exceeds the management reference value, an output unit that outputs the comparison determination result is provided. It is characterized by.

Nearby points invention according to claim 2, in the noise monitoring system according to claim 1, together with is arranged close to a point in the area, for detecting measuring noise generated from a plurality of noise sources in the area It is characterized by having a detection measuring means.

The invention according to claim 3 is a noise monitoring method, wherein a plurality of noise sources are arranged in a predetermined block among areas virtually divided into a plurality of blocks ,
Detecting and measuring means for detecting and measuring noise generated from the plurality of noise sources is arranged at least in two areas in the area that can detect and measure noise from the predetermined block where each noise source is arranged. And
Analyzing the frequency of the noise detected and measured by the detection and measurement means, and extracting the sound pressure data consisting of the dominant frequency band by the extraction means,
Comparing the sound pressure data of the noise from the predetermined blocks obtained by said detection measurement means and the extraction means, specifying the analysis sound pressure data at the maximum tone and becomes a point of the block of the predetermined block Identified by means,
The comparison determination means compares and determines the sound pressure data for analysis in the block of the point that becomes the maximum sound source specified by the specifying means, and the management reference value set in advance,
When it is determined by the comparison determination means that the sound pressure data for analysis in the block at the point that becomes the specified maximum sound source is a value that exceeds the management reference value, the comparison determination result is output by the output means. Features.

According to the present invention, noise can be monitored in real time, and when a noise exceeding an arbitrarily set management reference value occurs, it is instantaneously determined which of the plurality of noise sources is the cause. can do.
As a result, for example, at a construction site, the operation method can be improved by an operator of a construction machine that is immediately generating noise, so that noise can be appropriately managed. Further, since real-time monitoring of noise is possible, it is possible to quickly determine whether it is a problem with the operation method of the construction machine or the like or the problem with the construction machine itself. Therefore, it is possible to comply with the environmental standard law and the noise regulation law, and to carry out construction work with the transmission noise to the neighboring private house below the control standard value.

It is the schematic which shows the outline | summary of the noise monitoring system of this invention. It is the schematic which shows a noise monitoring object area. It is the schematic which shows the noise monitoring object area different from FIG.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a schematic diagram showing an example of a noise monitoring system according to the present invention.
In FIG. 1, reference numeral 1 denotes a system main body.
The system main body 1 includes a microphone 2 appropriately disposed in an area 20, and
A sound level meter 3 connected to the microphone 2;
An A / D exchange unit 4 for converting sound pressure data of noise measured by a sound level meter from analog to digital;
A processing CPU 5 (Central Processing Unit) for processing and executing various programs;
RAM (Random Access Memory) (not shown)
A storage device 6 for storing various data and programs;
Input means (not shown) for inputting various information in the system main body 1;
Output means 7 and 8 arranged in the vicinity of the plurality of noise sources 21 and 22 in the area 20 and outputting the obtained information;
A communication unit 9 is provided for exchanging information between the system main body 1 and the outside.

  The microphone 2 is an electroacoustic transducer that converts an acoustic signal into an electrical signal. As shown in FIG. 1 and FIG. 2, the microphone 2 is installed outdoors, and therefore has a cover 2a for preventing birds, rain, and wind. It is attached. In particular, it is preferable to keep windproof because noise caused by wind can be prevented.

The configuration of the sound level meter 3 is not limited in any way, but in the present embodiment, the noise level (LA) and the sound pressure level (Lp) can be measured. A sound level meter is used.
The microphone 2 and the sound level meter 3 are connected by a cable.
Further, the noise measurement by the sound level meter 3 can be performed instead by the processing CPU 5 using a similar program.

The storage device 6 is composed of a hard disk device, and the storage device 6 includes a data storage unit and a program storage unit.
In the data storage unit, a noise source information storage unit that stores information on the noise sources 21 and 22 such as the type of the noise sources 21 and 22 (for example, construction machines) and position information,
A sound pressure data storage unit for storing sound pressure data of detected and measured noise,
A maximum sound source point data storage unit for storing sound pressure data for analysis (described later) of a point to be the maximum sound source;
A management standard value storage unit for storing a noise management standard value based on the Environmental Standards Law and the Noise Regulation Law;
Various information such as a comparison / determination result storage unit for storing a comparison / determination result (to be described later) between the sound pressure data for analysis of the point that becomes the maximum sound source and the management reference value is converted into data.
In addition, the program storage unit includes a specific program for specifying sound pressure data for analysis of the point that is the maximum sound source,
A comparative judgment program for comparing and comparing the sound pressure data for analysis of the point that will be the maximum sound source and the management reference value,
An output program for outputting the comparison determination result by the output means 7 and 8 is stored.

  The output means 7 is constituted by a display. The display 7 is preferably provided at a position that can be seen by the operators of the construction machines 21 and 22, and it is desirable that the display 7 can be confirmed while in the cockpit.

  Further, the output means 8 is constituted by an alarm device. The alarm device 8 emits light and sound, and is preferably provided at a position where the operator of the construction machines 21 and 22 can see or hear an alarm sound, and can be confirmed while in the cockpit. desirable.

The system main body 1 is connected to an administrator computer 10 installed outside the area 20 or in a remote place via the communication unit 9.
The administrator computer 10 includes a speaker 11 that outputs sound in the area 20 and a printer 12 that prints information transmitted from the system main body 1, and the sound in the area 20 is real-time. The form 13 can be created.

  Further, the system body 1 is connected to a remote controller 14 via the communication unit 9, and various programs of the system body 1 can be executed from outside the area 20 using the remote controller 14. Further, by providing the remote controller 14 with a function of emitting light and sound, it can be used as an alarm device similar to the output device 8.

In addition, each component of the system main body 1 excluding the microphone 2 and the output means 7 and 8 may be disposed in the area 20 or, for example, a worker's place outside the area 20. It may be arranged at a place.
In addition, each component of the system main body 1 except for the microphone 2 and the output means 7 and 8 may be provided as a single device in a single case, or may be provided in a single case. It does not have to be.

Further, as shown in FIG. 2, the area 20 is a construction site in the present embodiment, and the noise sources 21 and 22 are construction machines, respectively.
In this embodiment, the area 20 is a construction site, but is not limited to this, and can be changed as appropriate. Similarly, the noise sources 21 and 22 are not limited to construction machines. Absent.

In addition, the area 20 is configured so that the position information of the noise sources 21 and 22 can be easily grasped by virtually dividing the area 20 into a plurality of blocks, for example.
In this case, position information of a plurality of blocks configured by partitioning the area 20 is stored in advance in the storage device 6 of the system main body 1 by being input by an input unit.

And the construction machine which is the said noise sources 21 and 22 is arrange | positioned in the predetermined location in the said area 20, The installation location information of the construction machines 21 and 22 in the said area 20 is input with an input means. Is stored in advance in the storage device 6 of the system main body 1.
When the area 20 is virtually divided into a plurality of blocks, it is input in advance in which block the construction machines 21 and 22 are arranged and stored in the storage device 6.

Here, the noise monitoring system of the present embodiment is configured by detecting and measuring noise by the microphone 2 and the sound level meter 3 and executing various programs using each data stored in the system main body 1. Yes.
That is, the noise monitoring system of the present embodiment detects and measures noise generated from a plurality of noise sources 21 and 22 arranged at predetermined locations in the area 20 and also detects noise from each noise source 21 and 22. Detection and measurement means arranged at least in two areas in the area 20 to enable detection and measurement, respectively;
Comparing the sound pressure data of the noise obtained by this detection and measurement means, specifying the sound pressure data for analysis of the point that becomes the maximum sound source,
Comparison determination means for comparing and determining the sound pressure data for analysis of the point that becomes the maximum sound source specified by the specifying means, and a preset management reference value,
Output means 7 and 8 for outputting a result of the comparison determination when the comparison determination means determines that the sound pressure data for analysis at the specified maximum sound source is a value exceeding the management reference value. I have.

The detection and measurement means is constituted by at least the microphone 2.
As described above, the microphones 2 are arranged in at least two locations in the area 20 that can detect and measure the noise from the noise sources 21 and 22, respectively.
That is, when the microphones 2 and 2 are arranged at least at two locations in the area 20 and the noise sources 21 and 22 are viewed from the locations where the microphones 2 and 2 are disposed, The noise sources 21 and 22 are arranged at positions where they can be seen without being obstructed by an obstacle.

The specifying means is executed by the processing CPU 5 according to a specifying program stored in the storage device 6 using the derived sound pressure data for analysis.
That is, the specifying program specifies the sound pressure data of the obtained noise having the largest waveform amplitude, and is configured by, for example, an analysis method based on the delayed sum beamforming method.
An analysis method based on this delayed sum beamforming method will be described.
That is, the phase difference (time difference) between the sound pressure data obtained by the microphones 2 and 2 depends on the distance between the noise sources 21 and 22 and the microphones 2 and 2. For example, there is a slight time difference between the arrival time of noise from the noise source 21 to the one microphone 2 and the arrival time of noise from the noise source 21 to the other microphone 2 shown in FIG. It depends on the distance to each microphone 2, 2.
For this reason, it is assumed that the sound pressure data obtained from the microphones 2 and 2 is transmitted from the arrangement locations of the noise sources 21 and 22, and the sound pressure data obtained from the respective microphones 2 and 2 is When superimposing in consideration of the phase difference, the sound pressure increases when the phase is assumed to be the same as that of the noise sources 21 and 22 (distance interval is correct), and there is a phase difference (distance interval is incorrect). The sound pressure is reduced. In other words, this is because the signals having the same phase have a reinforcing property.

The comparison / determination means uses the sound pressure data for analysis of the point that becomes the specified maximum sound source and the management reference value data stored in the storage device 6, and also performs comparison determination stored in the storage device 6. It is executed by the processing CPU 5 according to a program.
That is, the comparison / determination program determines whether the sound pressure data for analysis at the point that is the specified maximum sound source exceeds or falls below the management reference value by comparing both values.

  The output means 7 and 8 are constituted by the display 7 and the alarm device 8 as described above, and are executed by the processing CPU 5 according to the output program stored in the storage device 6 using the comparison determination result. It is.

  According to the noise monitoring system as described above, noise can be monitored in real time, and when noise exceeding the control standard value set arbitrarily is generated, which of the noise sources is the cause of the noise Can be determined instantly.

The noise monitoring method using the noise monitoring system as described above is as follows.
First, as shown in FIG. 2, a plurality of noise sources 21 and 22 are arranged at predetermined locations in the area 20. In the present embodiment, the area 20 is divided into a plurality of blocks, and the noise sources 21 and 22 are arranged in arbitrary blocks.

  Subsequently, the microphones 3 for detecting and measuring the noises generated from the plurality of noise sources 21 and 22 are provided at least at two locations in the area 20 where the noises from the noise sources 21 and 22 can be detected and measured, respectively. Arrange (detection specifying means).

Subsequently, noise detection measurement is started by the detection measurement means.
Then, by comparing the sound pressure data of the noise obtained by this detection and measurement means, the analysis sound pressure data of the point where the waveform amplitude is the largest and becomes the maximum sound source among these analysis sound pressure data is identified. Specify using a program (specifying means).
Note that the specific program for comparing the sound pressure data of the noise obtained by the detection and measurement means and specifying the sound pressure data for analysis of the point that becomes the maximum sound source is performed by the above-described delayed sum beamforming method. .

Subsequently, the analysis sound pressure data of the point that becomes the maximum sound source specified by the specifying means and the management reference value set in advance are compared and determined using a comparison determination program (comparison determination means).
Here, if the sound pressure data for analysis at the point that becomes the specified maximum sound source exceeds the management reference value, the process proceeds to the next procedure, but if it falls below, the process proceeds to the next procedure without proceeding to the next procedure. The procedure ends at the stage.

Then, when it is determined by the comparison determination means that the analysis sound pressure data at the point that becomes the specified maximum sound source is a value that exceeds the management reference value, the comparison determination result is output by the output means. In other words, a message indicating that the noise exceeds the management reference value is output to the display 7, and a warning that the noise exceeds the management reference value is transmitted visually and audibly by the alarm device 8.
In this way, the noise in the area 20 can be monitored.

  As for the comparison / determination unit, it may be directly compared with the management reference value when noise is detected and measured by the detection / measurement unit.

  According to the noise monitoring method as described above, it is possible to monitor noise in real time, and when noise exceeding an arbitrarily set management standard value occurs, which of the multiple noise sources is the cause of the noise Can be determined instantly.

As described above, in the microphones 2 and 2 according to the present embodiment, the microphones 2 and 2 are arranged in at least two places in the area 20, and the noise sources 21 are arranged from the arrangement places of the microphones 2 and 2. , 22, the noise sources 21 and 22 must be arranged so that they can be seen without being obstructed by an obstacle.
However, as shown in FIG. 3, a plurality of noise sources 31 and 32 are arranged in the area 30, and an obstacle 33 may be provided between the noise sources 31 and 32. Further, in such a case, when the microphones 2 are simply arranged at the two positions as described above, when the noise sources 31 and 32 are viewed from the microphones 2 and 2, they are hindered by the obstacle 33. There is.
Even if it is attempted to detect and measure noise in such a state, it is difficult to desire the accuracy of sound source identification due to a physical phenomenon such as diffraction. Therefore, as shown in FIG. 3, the number of microphones 2 (locations) is added. It is preferable to do.
That is, in FIG. 3, in addition to the first microphone 2 from the top (for convenience, microphone A) and the second microphone 2 from the top (microphone B), the first microphone 2 from the bottom (microphone C). Add
Thereby, from the microphone C, the noise source 31 can be seen without being obstructed by the obstacle 33, and the noise source 32 can be seen without being obstructed by the obstacle 33. Therefore, it is possible to satisfy the condition that the noises from the noise sources 31 and 32 are arranged in at least two places in the area 30 that can detect and measure the noise.

Also, the noise monitoring system, in addition to the respective means including the detection measurement means or a specific means as described above, noise sensed measured by prior Symbol detection measuring means and frequency analysis, the frequency band to be dominant the sound pressure data formed that comprise an extraction means for extracting.
That is, if the frequency characteristics of the construction machines 21 and 22 that are noise sources are known, it is possible to separate the sound pressure data of each noise to some extent at the stage of extracting the outstanding frequency band. Furthermore, if the sound pressure data for analysis is derived by executing the processing CPU 5 according to the specific program using the sound pressure data of only the outstanding frequency band, the sound source specifying performance can be further improved.

Further, as shown in FIG. 2, the noise monitoring system is disposed at a point 23 adjacent to the area 20, and is adjacent to detect and measure noise generated from a plurality of noise sources 21 and 22 in the area 20. You may provide the point detection measurement means.
As a result, the sound source can be specified only when the noise at the neighboring point 23 is smaller than the noise within the area 20 and the noise at the neighboring point 23 exceeds the management reference value.
The proximity point detection and measurement means is composed of the microphone 2 and the sound level meter 3, and is connected to the A / D exchange unit in the same manner as the sound level meter 3 in the area 20.

According to the present embodiment, noise can be monitored in real time, and when noise exceeding an arbitrarily set management reference value is generated, which is the cause among a plurality of noise sources 21 and 22 (31, 32) It is possible to instantly determine whether it is a noise source.
As a result, in the area 20 (30), which is a construction site, the operator of the construction machines 21, 22 (31, 32) that is immediately generating noise can improve the operation method. It becomes possible to do. In addition, since real-time monitoring of noise is possible, whether it is a problem of the operation method of the construction machines 21, 22 (31, 32) or the construction machine 21, 22 (31, 32) itself. It is possible to judge quickly. Therefore, it is possible to comply with the environmental standard law and the noise regulation law, and to carry out construction work with the transmission noise to the neighboring private house below the control standard value.

1 System body 2 Microphone 3 Sound level meter 4 A / D exchange unit 5 Processing CPU
6 Storage device 7 Display (output means)
8 Alarm device (output means)
9 Communication unit 20 Area 21 Noise source 22 Noise source

Claims (3)

Among the areas virtually divided into a plurality of blocks, the noise generated from the plurality of noise sources arranged in the predetermined block is detected and measured, and the noise from the predetermined block in which each noise source is arranged is measured. Detection and measurement means arranged at least in two locations in the area, each enabling detection and measurement;
Extracting means for frequency-analyzing the noise detected and measured by the detection measuring means, and extracting sound pressure data consisting of a dominant frequency band;
Comparing the sound pressure data of the noise from the predetermined blocks obtained by said detection measurement means and the extraction means, specifying the analysis sound pressure data at the maximum tone and becomes a point of the block of the predetermined block Specific means to
Comparison determination means for comparing and determining the sound pressure data for analysis in the block of the point that becomes the maximum sound source specified by the specifying means, and a preset management reference value,
When the comparison determination unit determines that the sound pressure data for analysis in the block at the point that becomes the specified maximum sound source is a value that exceeds the management reference value, an output unit that outputs the comparison determination result is provided. A noise monitoring system characterized by While being positioned close to a point in the area, noise according to claim 1, characterized in that it comprises a plurality of detection measurement for neighbor point for detecting measuring noise generated from the noise source of the area Monitoring system. A plurality of noise sources are arranged in a predetermined block among areas virtually divided into a plurality of blocks ,
Detecting and measuring means for detecting and measuring noise generated from the plurality of noise sources is arranged at least in two areas in the area that can detect and measure noise from the predetermined block where each noise source is arranged. And
Analyzing the frequency of the noise detected and measured by the detection and measurement means, and extracting the sound pressure data consisting of the dominant frequency band by the extraction means,
Comparing the sound pressure data of the noise from the predetermined blocks obtained by said detection measurement means and the extraction means, specifying the analysis sound pressure data at the maximum tone and becomes a point of the block of the predetermined block Identified by means,
The comparison determination means compares and determines the sound pressure data for analysis in the block of the point that becomes the maximum sound source specified by the specifying means, and the management reference value set in advance,
When it is determined by the comparison determination means that the sound pressure data for analysis in the block at the point that becomes the specified maximum sound source is a value that exceeds the management reference value, the comparison determination result is output by the output means. A characteristic noise monitoring method.

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