CN110779617B - Low-frequency noise test analysis system and analysis method thereof - Google Patents

Abstract

The invention discloses a low-frequency noise test analysis system and an analysis method thereof. The device comprises a shell and a laser lamp, wherein a data processing module and a controller are respectively arranged in the shell, a bracket is arranged on the upper surface of the shell, and a first universal rotating mechanism is arranged on the bracket; five sounding pipes are arranged on the first universal rotating mechanism, the lengths of the five sounding pipes are equal, the diameters of pipe holes are equal, and the pipe center lines are parallel; the front end surfaces of the five sounding pipes are also located in the same vertical plane; a noise sensor is arranged in each sounding pipe, the laser lamp is also arranged in the fifth sounding pipe, and the center line of light emitted by the laser lamp and the pipe center line of the fifth sounding pipe are on the same straight line.

Description

Low-frequency noise test analysis system and analysis method thereof

Technical Field

The invention relates to the technical field of multi-noise-source noise source transmission path searching, in particular to a low-frequency noise test analysis system and an analysis method thereof.

Background

In workshops, a plurality of machine tables emit noise at the same time, but sometimes a region S with small noise is needed outside the workshops and inside the workshops, the current approach is generally to make the region with small noise into a soundproof room by using a soundproof board, so that the cost for building the soundproof room is high, and the occupied space of the soundproof board for the soundproof room is large. If a multi-noise-source transmission path is found, noise at the region S can be largely shielded as long as a soundproof board is mounted on this multi-noise-source transmission path.

Disclosure of Invention

The invention provides a low-frequency noise test analysis system and an analysis method thereof, which are simple in structure and convenient to use, and can detect a noise source transmission path emitted by multiple noise sources.

The technical problems are solved by the following technical proposal:

the low-frequency noise test analysis system comprises a shell and a laser lamp, wherein a data processing module and a controller are respectively arranged in the shell, a bracket is arranged on the upper surface of the shell, and a first universal rotating mechanism is arranged on the bracket;

five sounding pipes are arranged on the first universal rotating mechanism, the lengths of the five sounding pipes are equal, the diameters of pipe holes are equal, and the pipe center lines are parallel; the front end surfaces of the five sounding pipes are also located in the same vertical plane; the first sounding pipe of the five sounding pipes is arranged right above the fifth sounding pipe, and the second sounding pipe is arranged right below the fifth sounding pipe; the third sounding pipe is arranged right and left of the fifth sounding pipe, and the fourth sounding pipe is arranged right and left of the fifth sounding pipe; the first sounding pipe and the second sounding pipe are arranged symmetrically up and down relative to the fifth sounding pipe, and the third sounding pipe and the fourth sounding pipe are arranged symmetrically left and right relative to the fifth sounding pipe;

a noise sensor is respectively arranged in the fifth sounding pipe, the first sounding pipe, the second sounding pipe, the third sounding pipe and the fourth sounding pipe, the laser lamp is arranged in the fifth sounding pipe, and the central line of light emitted by the laser lamp and the pipe center line of the fifth sounding pipe are on the same straight line;

the control end of the first universal rotating mechanism, the control end of the laser lamp, the data processing module and each noise sensor are respectively connected with the controller.

In use, the low frequency noise test analysis system is first placed in the region S where little noise is required.

Then simultaneously starting the noise sensors in the first sound measuring tube, the second sound measuring tube, the third sound measuring tube and the fourth sound measuring tube, and uploading the noise information detected by each noise sensor at the same moment to the controller;

then comparing the noise intensity of each piece of uploaded noise information by a data processing module, and if the noise intensity A1 detected by the noise sensor in the first sound measuring tube is larger or smaller than the noise intensity A2 detected by the noise sensor in the second sound measuring tube, controlling the first universal rotating mechanism to rotate to the right or to rotate to the left until the noise intensity detected by the noise sensor in the first sound measuring tube is equal to the noise intensity detected by the noise sensor in the second sound measuring tube by the controller; similarly, if the noise intensity A3 detected by the noise sensor in the third sound measuring tube is greater than or less than the noise intensity A4 detected by the noise sensor in the fourth sound measuring tube, the controller controls the first universal rotating mechanism to rotate to the right or to rotate to the left until the noise intensity detected by the noise sensor in the third sound measuring tube is equal to the noise intensity detected by the noise sensor in the fourth sound measuring tube;

stopping rotation of the first universal rotation mechanism when a1=a2=a3=a4; then, a noise sensor in a fifth sounding pipe is started to detect the noise intensity A5, and the laser lamp is turned on at the same time, so that a path irradiated by light emitted by the laser lamp is a path which needs to be passed when the multi-noise source is transmitted by the multi-noise source, and a multi-noise source transmission path is found.

After the noise source transmission path of the multi-noise source is found, the noise at the region S can be largely shielded by arranging a sound insulation board or a sound attenuation board on the noise source transmission path of the multi-noise source. This scheme need not to separate regional S department into the sound insulation room with the acoustic celotex board, has reduced the use of acoustic celotex board, just also reduced the occupation area of acoustic celotex board and reduced the cost of sound insulation processing, simple structure, convenient to use can detect out the synthetic noise sound source transmission path that many noise sources sent.

Preferably, a sound insulation plate is arranged at the right end opening of each sound measurement tube, and a sound elimination layer is further arranged on the inner tube wall of each sound measurement tube.

The noise elimination layer reduces the echo of noise in the sounding pipe, and the reliability is good.

A wireless module connected with the controller is also arranged in the shell.

The wireless module can enable the low-frequency noise test analysis system to be in wireless connection with an external computer or an intelligent terminal, and is convenient for controlling and managing the low-frequency noise test analysis system.

An analysis method according to a low-frequency noise test analysis system comprises a multi-noise-source combined noise source transmission path searching method, wherein the multi-noise-source combined noise source transmission path searching method is realized as follows:

the low frequency noise test analysis system is first placed at the area S where little noise is required.

Then simultaneously starting the noise sensors in the first sound measuring tube, the second sound measuring tube, the third sound measuring tube and the fourth sound measuring tube, and uploading the noise information detected by each noise sensor at the same moment to the controller;

then comparing the noise intensity of each piece of uploaded noise information by a data processing module, and if the noise intensity A1 detected by the noise sensor in the first sound measuring tube is larger or smaller than the noise intensity A2 detected by the noise sensor in the second sound measuring tube, controlling the first universal rotating mechanism to rotate to the right or to rotate to the left until the noise intensity detected by the noise sensor in the first sound measuring tube is equal to the noise intensity detected by the noise sensor in the second sound measuring tube by the controller; similarly, if the noise intensity A3 detected by the noise sensor in the third sound measuring tube is greater than or less than the noise intensity A4 detected by the noise sensor in the fourth sound measuring tube, the controller controls the first universal rotating mechanism to rotate to the right or to rotate to the left until the noise intensity detected by the noise sensor in the third sound measuring tube is equal to the noise intensity detected by the noise sensor in the fourth sound measuring tube;

stopping rotation of the first universal rotation mechanism when a1=a2=a3=a4; then, a noise sensor in a fifth sounding pipe is started to detect the noise intensity A5, and the laser lamp is turned on at the same time, so that a path irradiated by light emitted by the laser lamp is a path which needs to be passed when the multi-noise source is transmitted by the multi-noise source, and a multi-noise source transmission path is found.

The invention can achieve the following effects:

according to the invention, the area S is not required to be partitioned into the soundproof house by using the soundproof plate, so that the use of the soundproof plate is reduced, the occupied area of the soundproof plate is reduced, the cost of soundproof treatment is reduced, the structure is simple, the use is convenient, and the transmission path of the combined noise source emitted by multiple noise sources can be detected.

Drawings

Fig. 1 is a schematic diagram of a connection structure according to the present invention.

Fig. 2 is a schematic cross-sectional connection structure of a fifth sounding pipe according to the present invention.

FIG. 3 is a schematic diagram of a connection structure in a use state when no acoustic panel is provided on a noise source transmission path of a multi-noise source according to the present invention.

Fig. 4 is a schematic diagram of a connection structure in a use state when a sound insulation board is disposed on a noise source transmission path of a plurality of noise sources according to the present invention.

Detailed Description

The invention is further described below with reference to the drawings and examples.

Embodiments, low frequency noise test analysis systems, are shown in FIGS. 1-4. The device comprises a shell 2 and a laser lamp 12, wherein a wireless module, a data processing module 3 and a controller 4 are respectively arranged in the shell, a bracket 1 is arranged on the upper surface of the shell, and a first universal rotating mechanism 8 is arranged on the bracket;

five sounding pipes are arranged on the first universal rotating mechanism, the lengths of the five sounding pipes are equal, the diameters of pipe holes are equal, and the pipe center lines are parallel; the front end surfaces of the five sounding pipes are also located in the same vertical plane; the first sounding pipe 13 of the five sounding pipes is arranged right above the fifth sounding pipe 11, and the second sounding pipe 7 is arranged right below the fifth sounding pipe; the third sounding pipe 15 is arranged right and left of the fifth sounding pipe, and the fourth sounding pipe 10 is arranged right and left of the fifth sounding pipe; the first sounding pipe and the second sounding pipe are arranged symmetrically up and down relative to the fifth sounding pipe, and the third sounding pipe and the fourth sounding pipe are arranged symmetrically left and right relative to the fifth sounding pipe;

a noise sensor 17 is arranged in the fifth sound measuring tube, a noise sensor 14 is arranged in the first sound measuring tube, a noise sensor 6 is arranged in the second sound measuring tube, a noise sensor 16 is arranged in the third sound measuring tube, a noise sensor 9 is arranged in the fourth sound measuring tube, a laser lamp is arranged in the fifth sound measuring tube, and the central line of light 18 emitted by the laser lamp and the tube center line of the fifth sound measuring tube fall on the same straight line;

the control end of the first universal rotating mechanism, the wireless module, the control end of the laser lamp, the data processing module and each noise sensor are respectively connected with the controller.

The fifth noise sensor in the sounding pipe measures the noise intensity A5 of the noise source of the multi-noise source.

A wireless module 5 connected with the controller is also arranged in the shell. A wireless module connected with the controller is also arranged in the shell. The wireless module can enable the low-frequency noise test analysis system to be in wireless connection with an external computer or an intelligent terminal, and is convenient for controlling and managing the low-frequency noise test analysis system.

The right end opening of each sounding pipe is provided with a sound insulation plate 22, and the inner pipe wall of each sounding pipe is also provided with a sound elimination layer 23. The noise elimination layer reduces the echo of noise in the sounding pipe, and the reliability is good.

According to the analysis method of the low-frequency noise test analysis system, the analysis method comprises a multi-noise-source transmission path searching method, and the multi-noise-source transmission path searching method is realized as follows:

in use, the low frequency noise test analysis system is first placed in the region S where little noise is required.

Then simultaneously starting the noise sensors in the first sound measuring tube, the second sound measuring tube, the third sound measuring tube and the fourth sound measuring tube, and uploading the noise information detected by each noise sensor at the same moment to the controller;

then comparing the noise intensity of each piece of uploaded noise information by a data processing module, and if the noise intensity A1 detected by the noise sensor in the first sound measuring tube is larger or smaller than the noise intensity A2 detected by the noise sensor in the second sound measuring tube, controlling the first universal rotating mechanism to rotate to the right or to rotate to the left until the noise intensity detected by the noise sensor in the first sound measuring tube is equal to the noise intensity detected by the noise sensor in the second sound measuring tube by the controller; similarly, if the noise intensity A3 detected by the noise sensor in the third sound measuring tube is greater than or less than the noise intensity A4 detected by the noise sensor in the fourth sound measuring tube, the controller controls the first universal rotating mechanism to rotate to the right or to rotate to the left until the noise intensity detected by the noise sensor in the third sound measuring tube is equal to the noise intensity detected by the noise sensor in the fourth sound measuring tube;

stopping rotation of the first universal rotation mechanism when a1=a2=a3=a4; then, a noise sensor in the fifth sounding pipe is started to detect the noise intensity A5, and the laser lamp is turned on at the same time, so that a section of path irradiated by the light 18 emitted by the laser lamp is the path 24 which needs to be passed when the noise source of the multiple noise sources 20 transmits, and a noise source transmission path of the multiple noise sources is found. The noise-dividing paths 19 of the multiple noise sources 20 are combined to form a path 24 which the combined noise source needs to pass when transmitting.

After the noise source-closing transmission path 24 of the multi-noise source is found, the noise at the region S can be largely shielded by providing the soundproof plate 21 or the sound-deadening plate on the noise source-closing transmission path 24 of the multi-noise source. The area S in this embodiment is where the low frequency noise test analysis system is placed.

According to the embodiment, the area S is not required to be divided into the soundproof houses by the soundproof plates, the use of the soundproof plates is reduced, the occupied area of the soundproof plates is reduced, the cost of soundproof treatment is reduced, the structure is simple, the use is convenient, and the combined noise source transmission path emitted by multiple noise sources can be detected.

The embodiments of the present invention have been described above with reference to the accompanying drawings, but the embodiments are not limited to the above examples, and various changes or modifications may be made by one of ordinary skill in the art within the scope of the appended claims.

Claims (2)

1. The low-frequency noise test analysis system is characterized by comprising a shell and a laser lamp, wherein a data processing module and a controller are respectively arranged in the shell, a bracket is arranged on the upper surface of the shell, and a first universal rotating mechanism is arranged on the bracket;

five sounding pipes are arranged on the first universal rotating mechanism, the lengths of the five sounding pipes are equal, the diameters of pipe holes are equal, and the pipe center lines are parallel; the front end surfaces of the five sounding pipes are also located in the same vertical plane; the first sounding pipe of the five sounding pipes is arranged right above the fifth sounding pipe, and the second sounding pipe is arranged right below the fifth sounding pipe; the third sounding pipe is arranged right and left of the fifth sounding pipe, and the fourth sounding pipe is arranged right and left of the fifth sounding pipe; the first sounding pipe and the second sounding pipe are arranged symmetrically up and down relative to the fifth sounding pipe, and the third sounding pipe and the fourth sounding pipe are arranged symmetrically left and right relative to the fifth sounding pipe;

a noise sensor is respectively arranged in the fifth sounding pipe, the first sounding pipe, the second sounding pipe, the third sounding pipe and the fourth sounding pipe, the laser lamp is arranged in the fifth sounding pipe, and the central line of light emitted by the laser lamp and the pipe center line of the fifth sounding pipe are on the same straight line;

the control end of the first universal rotating mechanism, the control end of the laser lamp, the data processing module and each noise sensor are respectively connected with the controller;

a sound insulation plate is arranged at the right end opening of each sound measurement tube, and a sound elimination layer is also arranged on the inner tube wall of each sound measurement tube;

a wireless module connected with the controller is also arranged in the shell.

2. An analysis method of a low frequency noise test analysis system according to claim 1, wherein,

the analysis method comprises a multi-noise-source transmission path searching method, and the multi-noise-source transmission path searching method is realized as follows:

firstly, placing the low-frequency noise test analysis system at a region S with small required noise;

then, simultaneously starting the noise sensors in the first sound measuring tube, the second sound measuring tube, the third sound measuring tube and the fourth sound measuring tube, and uploading the noise information detected by each noise sensor at the same moment to a controller;

then, the data processing module compares the noise intensity of each piece of uploaded noise information and calculates the vibration frequency, and if the noise intensity A1 detected by the noise sensor in the first sound measuring tube is larger or smaller than the noise intensity A2 detected by the noise sensor in the second sound measuring tube, the controller controls the first universal rotating mechanism to rotate towards the right or towards the left until the noise intensity detected by the noise sensor in the first sound measuring tube is equal to the noise intensity detected by the noise sensor in the second sound measuring tube; similarly, if the noise intensity A3 detected by the noise sensor in the third sound measuring tube is greater than or less than the noise intensity A4 detected by the noise sensor in the fourth sound measuring tube, the controller controls the first universal rotating mechanism to rotate to the right or to rotate to the left until the noise intensity detected by the noise sensor in the third sound measuring tube is equal to the noise intensity detected by the noise sensor in the fourth sound measuring tube;

stopping rotation of the first universal rotation mechanism when a1=a2=a3=a4; then, a noise sensor in a fifth sounding pipe is started to detect the noise intensity A5, and the laser lamp is turned on at the same time, so that a path irradiated by light emitted by the laser lamp is a path which needs to be passed when the multi-noise source is transmitted by the multi-noise source, and a multi-noise source transmission path is found.