RU2780309C1 - Method and system for automated monitoring of the equivalent sound level - Google Patents

Abstract

FIELD: measuring.

SUBSTANCE: invention relates to the field of metrology, in particular, to means of measuring noise. Method includes selecting a point characteristic by noise level; obtaining data by means of at least three noise meters distanced from each other by no more than 3 values of the sound wavelength at frequency of 1,000 Hz in an aerial environment under normal conditions at a given time pitch; transmitting telemetry data packets marked with time reference tags; obtaining an equivalent sound level at each stage, analysing and storing the data. The system comprises noise meters placed as described above on a support rack; wherein each noise meter includes a microphone linked with a digital processing unit configured to ensure the marking of telemetry data packets with time reference tags, and a data interface to an external computer network and the Internet; the outputs of the digital processing units are linked with the inputs of the data transmission tool linked with a data processing and storage tool via cable or wireless connection, wherein said data processing and storage tool constitutes a computer equipped with a software tool for calculating the equivalent sound level.

EFFECT: expanded range of technical means of automated monitoring of the equivalent sound level, ensuring full time coverage of the process characteristics of operation of a "noise-producing object", reliability, and monitoring cost reduction.

19 cl, 1 dwg

Description

The invention relates to the field of instrumentation, and in particular to automatic control and measuring means for monitoring noise, noise pollution of the territory, the impact of noise on the population, in particular the control of the noise impact of construction sites on the surrounding residential area.

The method provides for determining the general acoustic situation in a given place (in a certain area) and is used to determine the noise level in different periods of time (time intervals, parts of a day). It can be used to control the noise level at the border of residential development, to determine compliance with sanitary standards. The system ensures the implementation of the proposed method.

A known method of selective monitoring in real time and mapping of environmental noise and a device for its implementation according to US patent No. US 2015110276. selection of the contribution of specific sources. The device contains calibrated devices - sensors that monitor individual noise sources, information transmission means and a computing module. The disadvantage of this method is the need to identify each source and use a separate measuring device for it and, as a result of measurements, create a noise pattern only from the contribution of certain individual noise sources.

A known method for determining the noise level according to the patent of the Russian Federation No. 2534812, including the selection of characteristic points, the calculation of the noise level at the points characteristic of the noise level, a long-term noise measurement in order to identify the characteristic operating modes of the source at two points - at the source and far, and obtaining an amendment for the refined calculation. However, the known method does not provide the possibility of continuous monitoring of a given territory.

Closest to the proposed invention is a method for analyzing the noise level according to US patent US 2003204381, including data acquisition by means of a measuring device, signal transmission and processing for quite a long time. The method is carried out by a system for recording and analyzing the level of environmental noise. The system is capable of sampling, processing and storing 1-second equivalent sound level values for a limited time of two weeks. The disadvantage of the method and the system is the limited time measurements of two weeks, the complexity of the system and the high cost of monitoring equipment. Also, the disadvantage of this method is the lack of actions to verify the measurement data, and the impossibility of extracting tonal and impulse noise.

The objective of the invention is to create a method and system for qualitative monitoring of the noise impact of a "noise-producing object" on the surrounding "objects / residential development" with the exception of the possibility of falsifying information with "fitting" to existing norms and rules and ensuring the confirmation of the correctness of the results.

The technical result from the use of the invention is the expansion of the arsenal of technical means for automated monitoring of the equivalent sound level, providing full temporal coverage of the technological features of the "object that produces noise", reliability and reduced monitoring costs.

The specified technical result is achieved by the fact that automated monitoring of the equivalent noise level is carried out by a method including the selection of a point characteristic of the noise level, obtaining data using sound pressure measuring instruments, transmitting, processing, analyzing and storing data. At the selected characteristic point, data are obtained from at least three sound level meters located at a distance from each other of no more than 3 values of the wavelength of a sound wave at a frequency of 1000 Hz in the air under normal conditions, made to ensure continuous heating and maintenance of operability during temperature changes, telemetric data packets are received from each sound level meter with a given time step, the packets are marked with marks of the same time for all measuring instruments, and the packets are transmitted to a remote computer, where the equivalent sound level at each step is obtained as the value

where L _KT is the equivalent sound level,

L _w,i and L _w,j - sound levels corresponding to digital codes of sound level meters with numbers i and j, where i=1,2,3; j=2.3; i<j, which are selected by common time markers from the conditions:

- the absolute value of the difference between the readings of sound level meters with numbers i and j does not exceed 2.0 dB, that is, the condition is met

- the absolute value of the difference between the readings of sound level meters with numbers i and j is the minimum for any combination of pairs of different sound level meters:

produce the accumulation of the results obtained with the formation of databases.

A report on the equivalent sound level for a given time interval is generated based on the obtained databases.

Carry out the construction of time chronograms.

Step-by-step measured sound levels are stored and used to generate, at the request of the user, reports on equivalent noise levels for any monitoring time interval in the form of graphs, tables, text.

Each telemetry data packet contains the maximum instantaneous sound levels over a 1 s time interval.

Each telemetry packet contains time-averaged sound levels.

Each telemetry data packet contains sound pressure levels in octave bands.

Each telemetry packet contains sound pressure levels in 1/3-octave frequency bands.

Data transmission is simultaneously carried out to an external computer network and/or to a personal computer and/or to an industrial computer.

The databases are stored in the data storage service.

The system for automated monitoring of the equivalent sound level, contains means for measuring sound pressure, a means for transmitting data, means for processing and accumulating data, characterized in that the means for measuring sound pressure includes at least three sound level meters located at a distance of no more than 3 values from each other sound wave length of 1000 Hz in air under normal conditions, made to ensure continuous heating and maintenance of operability during temperature changes, at least one support post for mounting sound level meters, each sound level meter includes a microphone associated with a digital processing unit, made with the possibility of marking telemetric data packets with common time stamps and data interface to an external computer network and the Internet, the outputs of the digital processing units are connected to the inputs of the data transmission facility, which is connected to the facility via a cable or wireless connection data processing and accumulation, which is a computer equipped with a software tool for calculating the equivalent sound level.

The computer is designed to bring the results of measurement of sound level meters to a common time, identify anomalous data in case of sharp differences in the results of measurements of sound level meters from each other and calculate the final levels based on the totality of data from all measuring instruments, as well as transferring databases to the data storage service.

Class 1 sound level meters are used, averaging-integrating according to GOST R53188.1 (IEC 61672-1) with octave and 1/3-octave class 1 filters according to IEC 61260-1.

The sound level meters are equipped with wind protection devices.

The sound level meters are equipped with bird protection devices.

Sound level meters are equipped with fastening elements.

The sound level meters are designed to ensure continuous heating and maintenance of performance at ambient temperature fluctuations.

The sound level meters are powered by the PoE method through a PoE injector.

The system is equipped with a means of data transfer to a personal or industrial computer.

The sound level meters are mounted on a single rack, or each sound level meter is mounted on a separate rack.

The invention is illustrated by the drawing, which shows a diagram of a system for automated monitoring of the equivalent sound level.

The invention can be carried out as follows.

A reference point characteristic of the noise level is selected depending on the purpose of the measurement in accordance with the applicable regulatory documentation, for example, in accordance with paragraph 8.2 of the MUK 4.3.3277-21 “Noise level control in residential areas, in residential and public buildings and premises” . The criterion is the noise level at the control point, which is characteristic of the object under study, for example, the noise generated by machines, mechanisms and installations emitting noise into the environment during the construction process, to which the residential area, building, etc. is exposed. Or the criterion is that the contribution of the source under study to the noise at the control point is the most significant.

At the selected point, which is characteristic in terms of noise level, a measuring device is placed, which is a means of measuring sound pressure. Empirically, at least the optimal use of at least three measuring instruments has been established, each of which provides reception and conversion of acoustic signals into digital codes corresponding to the time-averaged sound level with time corrections in accordance with GOST R53188.1 (IEC 61672-1) and sound pressure levels in frequency bands an octave and one third of an octave in accordance with GOST Ρ 8.714 (IEC 61260), according to the newly introduced GOST Ρ 70024.1. Sound level meters are used as measuring instruments, and the most optimal use of sound level meters that meet the requirements for first class sound level meters, in accordance with GOST R53188.1, GOST R53188.1 (IEC 61672-1) and GOST Ρ 8.714-2010 (IEC 61260), GOST P 70024.1. All three measuring instruments are placed in close proximity to each other, in a line or radially, at a distance of not more than 3 times the length of a sound wave at a frequency of 1000 Hz in air under normal conditions. With a given time step, an independent digital code representing the sound level value is obtained from each sound level meter. The data received with a given time step is transmitted to a computer in the form of telemetry data packets. Packages are marked with marks of the same time for all means of measurement. A common time is ensured by the fact that each measuring instrument is connected to the Internet or to a common timer, and uses the common time of the Internet or the timer, respectively. The memory of each measuring device contains the individual calibration parameters of the measuring path entered during calibration, which are assigned to each packet of transmitted data in order to comply with the requirements of procedures and regulatory documents in the field of ensuring the uniformity of measurements. In this way, the possibility of falsifying the information received is excluded and confirmation of the correctness of the results is achieved. At each step corresponding to a given time interval, the sound level is calculated from the data obtained as the value

where L_ _CT is the equivalent sound level at the control point,

L _w,i and L _w,j - sound levels corresponding to digital codes of sound level meters with numbers i and j, where i=1,2,3; j=2.3; i<j, which are selected by common time markers from the conditions:

a) The absolute value of the difference between the readings of sound level meters with numbers i and j does not exceed 2.0 dB, that is, the condition is met

производят накопление результатов измеренных уровней (или вычисленных) с формированием базы данных. Базы данных сохраняют с возможностью формирования отчетов об эквивалентных уровнях звука за интервал времени в пределах диапазона мониторинга, осуществляют построение временных хронограмм.b) The absolute value of the difference between the readings of sound level meters with numbers i and j is the minimum for any combination of pairs of different sound level meters:

produce the accumulation of the results of the measured levels (or calculated) with the formation of a database. Databases are stored with the ability to generate reports on equivalent sound levels for a time interval within the monitoring range, time chronograms are built.

Step-by-step histories of measured sound levels are stored and used to generate, at the user's request, reports on equivalent sound levels at any time interval within the range of the monitoring period in the form of graphs, tables, text.

Data transfer occurs, if necessary, simultaneously to an external computer network and/or industrial computer.

Storage and archiving is carried out on a remote computer or in a data storage service, for example, according to GOST Ρ ISO / IEC 17826-2015.

The formation of telemetry data packages containing calibration parameters, maximum instantaneous (peak) sound levels in a time interval of 1 s, time-averaged sound levels, sound levels with standardized time corrections, sound pressure levels in octave and 1/3-octave frequency bands is carried out via the sound level meter interface module software. This mode of measurements with the use of time corrections F and I ensures the identification of the impulse and tonal nature of the noise, and also ensures the impossibility of falsifying the measurement results.

To implement the method, an automated monitoring system for the equivalent noise level is used, the schematic diagram of which is shown in the drawing.

The system contains at least three sound level meters, each of which is equipped with a digital converter 1, which provides measurement of sound levels and sound pressure levels in octave and one-third octave frequency bands according to the first accuracy class according to GOST R53188.1 (IEC 61672-1) and GOST Ρ 8.714-2010 (IEC 61260). Converter 1 sound level meter (microphone) is connected to the block 2 digital processing. The outputs of the blocks 2 are connected to the inputs of the switching device 3 connected via cable or wirelessly using a router 4 with a receiving device - a computer 5. The device is equipped with an interface 6, as well as means of communication with external consumers 7 of the final information.

It has been empirically established that for outdoor monitoring for more than 24 hours, the use of at least three transducers is optimal. The converters are placed at a small distance from each other. Empirically established that the distance is selected from the interval 0-3 values of the length of the sound wave frequency of 1000 Hz in the air under normal conditions.

The digital processing unit 2 is connected to the converter 1, and is designed to supply power to the digital converter via the Ethernet line of an external PoE injector, as well as to convert the converter 1 interface into an Ethernet local computer network interface, and to protect the digital converter 1 from adverse environmental conditions. . Block 2 is configured to mark telemetric data packets with common time stamps. To do this, the block is supplied with built-in software recorded on the microprocessor. Block 2 execution example - EPS-ETH-04 device. The outputs of the blocks 2 are connected to the input of the switching device 3, which supplies power through the block 2 to the digital converters 1 via the Ethernet line, and also provides the connection of the digital converters 1 of the digital converters with the Internet or with an external computer. An example of a POW-ETH-05 switching device.

The device receiving the measurement results - an external computer 5, which is a means of processing and accumulating data, receives data both directly via cable and using wireless communication. The connection can be made with an external computer, or via the Internet.

To operate the device, software is used to configure the interface translators built into the case of block 2. The software is installed on an external computer connected to the components of the device of the automated monitoring system of the equivalent noise level through the switching device 3.

The receiving device is configured to transfer, for storage of the measurement results, the generated databases to the data storage service in accordance with GOST ISO/IEC 17826-2015. The service also provides access to this data to users.

Computer 5 is equipped with software tools that provide the calculation of L _KT according to the above formula, and is also equipped with software tools for bringing the measurement results to a common time, as well as for detecting anomalous data, such as sharp differences in the measurement results of sound level meters, and for calculating the final levels from the totality of data all measuring instruments.

The digitizers 1 are equipped with wind protection, preferably caps made of faux fur, long pile fabric. It is possible to use foam rubber wind protection. Means of protection from birds are made in the form of sharp protrusions, needles. The sound level meter is equipped with a mounting element, for example in the form of a bracket, for mounting on a support column.

The transducer 1 and block 2 are placed in a case, on top of which a microphone windshield is placed, and thus the electrical power consumed by the electronics of the sound level meters is dissipated in the form of heat inside the case and maintains operability during temperature changes.

Switching device 3 supplies power to the sound level meter via the Ethernet line and combines several sound level meters and an external receiving device (computer) into a local network, connects them to Internet access devices, and provides communication with the data storage service.

The POW-ETH-05 device has several connectors that support both data switching and power supply of connected devices (PoE), and also has a connector that does not support Power over Ethernet technology. It is used to connect to Internet access devices or to an external computer.

The operation of the device consists in collecting acoustic signals, converting them into digital codes, transmitting, processing and accumulating data, forming a database, saving it, generating a report at the request of the consumer, building time chronograms, graphs, tables.

The application of the proposed method with its implementation through the proposed system ensures continuous long-term measurements and the transfer of measured values to the monitoring data storage service. Qualitative monitoring of the noise impact of the "object that produces noise" on the surrounding "objects / residential development" is carried out, eliminating the possibility of falsifying information with "adjustment" to existing norms and rules and ensuring the confirmation of the correctness of the results with full temporal coverage and taking into account all the technological features of the operation of the noise-producing object .

Claims (26)

1. A method for automated monitoring of the equivalent sound level, including selecting a point characteristic of the noise level, obtaining data using sound pressure measuring instruments, processing, analyzing and storing data, characterized in that at the selected characteristic point, data are obtained from at least three of sound level meters located at a distance from each other of no more than 3 values of the sound wave length of a frequency of 1000 Hz in the air under normal conditions, made to ensure continuous heating and maintenance of operability at temperature changes, telemetry data packets are received from each sound level meter with a given time step, packets are marked with marks of a single time for all measuring instruments and the packets are transmitted to a remote computer, where the equivalent sound level at each step is obtained as the value

where

- equivalent sound level, Lsh,i and Lsh,j - sound levels corresponding to digital codes of sound level meters with numbers i and j, where i=1,2,3; j=2.3; i<j, which are selected by common time markers from the conditions: - the absolute value of the difference between the readings of sound level meters with numbers i and j does not exceed 2.0 dB, that is, the condition is met

- the absolute value of the difference between the readings of sound level meters with numbers i and j is the minimum for any combination of pairs of different sound level meters:

produce the accumulation of the results obtained with the formation of databases. 2. The method according to claim. 1, characterized in that the report on the equivalent sound level for a given time interval is formed on the basis of the received databases. 3. The method according to claim 1, characterized in that time chronograms are constructed. 4. The method according to claim 1, characterized in that step-by-step measured sound levels are stored and used to generate, at the user's request, reports on equivalent noise levels for any monitoring time interval in the form of graphs, tables, text. 5. The method according to p. 1, characterized in that each packet of telemetry data contains the maximum instantaneous sound levels over a time interval of 1 s. 6. Method according to claim 1, characterized in that each telemetry data packet contains time-averaged sound levels. 7. Method according to claim 1, characterized in that each telemetry data packet contains sound pressure levels in octave frequency bands. 8. Method according to claim 1, characterized in that each telemetry data packet contains sound pressure levels in 1/3-octave frequency bands. 9. Method according to claim 1, characterized in that the data is simultaneously transferred to an external computer network and/or to a personal computer and/or to an industrial computer. 10. The method according to claim 1, characterized in that the databases are stored in a data storage service. 11. A system for automated monitoring of the equivalent sound level, containing means for measuring sound pressure, a means for transmitting data, means for processing and accumulating data, characterized in that the means for measuring sound pressure includes at least three sound level meters located at a distance of no more than 3 sound wave lengths of 1000 Hz in air under normal conditions, designed to provide continuous heating and maintain operability during temperature changes, at least one support stand for mounting sound level meters, with each sound level meter including a microphone associated with a digital processing unit , made with the possibility of marking telemetric data packets with common time stamps and data interface to an external computer network and the Internet, the outputs of the digital processing units are connected to the inputs of the data transmission means, which is connected to the environment by means of a cable or wireless connection. data processing and accumulation means, which is a computer equipped with a software tool for calculating the equivalent sound level. 12. The system according to claim 11, characterized in that the means of processing and accumulating data is designed to provide the possibility of bringing the measurement results of sound level meters to a common time, identifying anomalous data in case of sharp differences in the measurement results of sound level meters from each other and calculating the final levels based on the totality of data from all measuring instruments, as well as transferring databases to the data storage service. 13. The system according to claim 11, characterized in that the sound level meters of the 1st class are used, averaging-integrating with octave and 1/3-octave filters of class 1. 14. The system according to claim 11, characterized in that the sound level meters are equipped with wind protection. 15. The system according to claim 11, characterized in that the sound level meters are equipped with bird protection. 16. The system according to claim 11, characterized in that the sound level meters are equipped with fastening elements. 17. The system according to claim 11, characterized in that the sound level meters are powered using the PoE method through a PoE injector. 18. The system according to claim 11, characterized in that it is equipped with a means of transferring data to a personal or industrial computer. 19. The system according to claim 11, characterized in that the sound level meters are installed on a single rack, or each sound level meter is installed on a separate rack.

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