KR101260038B1 - Directional characteristics of noise meter measuring device - Google Patents

Abstract

PURPOSE: A device for measuring directional characteristics of a sound-level meter is provided to automate the measurement of directional characteristics of the sound-level meter by using a servo motor, thereby improving measurement accuracy and reducing the time required for the measurement. CONSTITUTION: A device for measuring directional characteristics of a sound-level meter comprises a height adjusting unit, a base plate(19), a driving unit(45), and a sound level meter support(27). The height adjusting unit is installed on a floor of an anechoic room. The base plate is fixed in the upper part of the height adjusting unit and provides a supporting force. The driving unit is mounted on the base plate and generates rotational torque by being remotely controlled by signals transmitted from a control unit located outside the anechoic room. The sound-level meter support connected to the driving unit is rotated within a predetermined angle range and supports the sound-level meter. [Reference numerals] (11) Sound source

Description

Directional characteristics of noise meter measuring device

The present invention relates to a sound level meter directivity measurement device.

A sound level meter is a measure of the loudness of noise. The noise level is a value that is set so that the difference in sensitivity to the frequency of sound is equal to the hearing of a person. In other words, it is a measuring instrument that can measure sound at a value close to the level of sensory size felt by humans by correcting the human hearing.

There are various kinds of such a sound level meter, but basically has a microphone, an amplifier, an attenuator, an auditory correction circuit, an indicator, and a calibration signal generator. The sound level meter is very much used throughout the industry. The most important thing in such a sound level meter is how accurate the sound level meter actually measures noise.

Directivity test, one of the test items to check the accuracy and performance of the sound level meter, is performed in the low anechoic chamber. The directivity test is a test to find out in which angle range the sound level meter to be tested can perform its normal function.

What is important in the directivity test is the precision of setting the relative position and direction of the sound level meter relative to the sound source. In particular, the direction of the sound level meter relative to the sound source must be precisely and consistently adjusted (e.g. 1 degree angle) to obtain an accurate value.

In addition, during the test, if there is movement inside the anechoic chamber, the test is inaccurate. Even small movements of the reflector inside the anechoic chamber (investigators or testers who have entered the room for noise measurement) are detected as very large sound field changes, making it difficult to make accurate measurements once a person enters the anechoic chamber.

By the way, the conventional sound level meter directivity measurement device is not automated and remote control is also impossible, there is a problem that the operator manually adjusts the direction setting of the sound level meter for the sound source.

That is, the worker enters the anechoic chamber, rotates the sound level meter by 1 degree, leaves the anechoic room, measures the noise of the sound source with the sound level meter, and the worker enters the anechoic room again by turning the sound level meter by 1 degree, and leaves the noise. After measuring again, the operator should go back to the anechoic room and turn the sound level meter an additional degree and repeat the work. This process is very tedious and physically demanding, usually taking about six hours to test a sound level meter.

In addition, as described above, since the operator needs to manually set the sound level meter, the relative position and angle change of the sound level meter relative to the sound source are not constant, making it difficult to secure the accuracy of the measurement result, and the reliability of the measurement itself is very low.

The present invention has been made to solve the above problems, and by automating the measurement of the directional characteristics of the sound level meter using a servo motor, the time required for measurement can be shortened, and in particular, the measurement accuracy can be greatly improved, and the remote control can be improved. It is possible to provide a simple sound level meter directional characteristic measuring device because it does not need to enter and exit the anechoic chamber.

The sound level meter directivity measurement apparatus of the present invention for achieving the above object, is installed in the interior of the anechoic chamber, erected at a predetermined distance from the sound source in the anechoic chamber, fixed to maintain a sound level meter for checking the directivity characteristic thereon And to, standing on the bottom of the anechoic chamber and the height adjustment unit capable of height adjustment; A horizontal base plate fixed to an upper part of the height adjusting part and providing a support force; A driving unit mounted to the base plate and remotely controlled by a signal transmitted from a control unit outside the anechoic chamber to generate rotational torque; It is connected to the drive unit is characterized in that it comprises a sound level meter support for rotating the motion within a certain angle range during operation of the drive unit, the sound level meter fixing the upper part.

The driving unit may further include: A motor fixed to the lower part of the base plate and generating rotational torque by an external control signal, a drive gear fixed to the drive shaft of the motor and positioned on an upper part of the base plate, and a driven gear engaged with the drive gear; It is characterized in that it comprises a power transmission shaft fixed to the upper portion of the center of rotation of the driven gear and extending vertically.

In addition, the sound level meter support unit; It is fixed to the power transmission shaft and when rotating the power transmission shaft, the horizontal rotation plate to rotate the rotation movement using the power transmission shaft as a rotating shaft, a support frame fixed to the upper portion of the rotating plate, and is provided on the upper support frame It is characterized in that it comprises a sound level meter fixing plate for supporting the sound level meter in a laid state, the microphone of the sound level meter to be positioned in the vertical upper portion of the rotating shaft of the rotating plate.

In addition, the rotation plate is located horizontally on the upper portion of the base plate, the bottom surface of the rotation plate, characterized in that the interval maintaining portion for maintaining the interval of the rotation plate with respect to the base plate during the rotation of the rotation plate is further provided.

In addition, the side portion of the sound level meter is provided with a display window for displaying the content measured by the sound level meter, the sound level meter support portion, characterized in that the camera is further provided to read the contents displayed on the display window to the control unit outside the anechoic chamber.

The driving unit may be connected to the control unit through an RS-232C module.

The sound level meter directional characteristic measuring device of the present invention as described above, by using the servo motor to measure the sound level characteristic of the sound level meter, it is possible to shorten the time required for measurement, and in particular, greatly improve the measurement accuracy, high reliability, In addition, remote control is possible so that the operator does not have to enter the anechoic chamber, so it is as simple as that.

1 is a view illustrating a measuring method of the sound level meter directivity characteristic.
2 is a side view showing the structure of a sound level meter directivity measurement apparatus according to an embodiment of the present invention.
FIG. 3 is an exploded perspective view showing an exploded view of a main part of the apparatus for measuring directivity characteristics shown in FIG. 2.
4 and 5 are diagrams for explaining the operation of the directivity measuring device shown in FIG.
6 and 7 are diagrams illustrating an anechoic chamber and a control room in which a sound level meter directivity measurement apparatus according to an embodiment of the present invention is located.

Hereinafter, one embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a view for briefly explaining a measuring method of the sound level meter directivity characteristic prior to the full description of the present invention.

Basically, the measurement of the directivity characteristic of the sound level meter 13 causes the sound level meter 13 to measure the noise output from the sound source 11 while changing the position and direction of the sound level meter 13 with respect to the sound source 11. The noise detection performance of the sound level meter 13 in the position and direction will be examined.

For example, as shown in FIG. 1, the intensity of the noise is measured while changing the orientation of the microphone 13a in the -90 degree to +90 degree angle range with respect to the sound source 11. For example, the sound level meter 13 is measured at an angle of 90 degrees (relative to the sound source), and the noise is measured at a position of 60 degrees, a position of 30 degrees, and a position of 0 degrees.

Through the above process, it is possible to find out in which angle range the sound level meter 13 performs more than the allowable performance.

In any case, the sound level meter directional characteristic measuring device according to the present embodiment has a structure in which the sound level meter 13 installed in front of the sound source is rotated by 1 degree within a 180 degree angle range by using a servomotor capable of remote control.

2 is a side view showing the structure of the sound level meter directivity characteristic measuring apparatus 15 according to an embodiment of the present invention.

As shown, the sound level meter directivity characteristic measuring device 15 according to the present embodiment is a tripod 17 as a height adjusting part which is standing on the bottom surface 202 of the anechoic chamber and whose height is adjustable, and the tripod 17. A base plate 19 fixed horizontally to an upper end of the base plate 19, a drive unit 45 supported by the base plate 19, and operated by a remote signal transmitted from a control room (100 of FIG. 6), and the drive unit ( It is fixed to the upper portion of 45) includes a sound level meter support portion 47 is rotated by a predetermined angle by the drive unit 45 while supporting the sound level meter 13 to be measured.

First, the tripod 17 includes a plurality of legs 17a, a hub 17b for collecting and fixing the upper ends of the legs 17a, and a pillar 17e supported in the upper part of the hub 17b. It has a fixing portion 17c that passes through and fixes the column 17e at a desired height. The fixing part 17c is provided with a fixing screw 17d for pressing and fixing the outer circumferential surface of the column 17e. The pillar 17e is completely fixed to the fixing portion 17c by the fixing screw 17d, and there is no fear of axial rotation or falling out.

In addition, since the tripod 17 is used as the height adjusting unit as described above, the height of the sound level meter 13 with respect to the bottom surface 202 can be easily adjusted.

The base plate 19 is a metal plate having a predetermined thickness and is horizontally fixed to the upper end of the pillar 17e, and firmly supports the driving unit 45 and the sound level meter support unit 47. Detailed shapes and features of the base plate 19 will be further described with reference to FIG. 3.

The driving unit 45 is mounted on the base plate 19. The drive unit 45 is a motor 21 for generating a torque by operating by a signal transmitted from the control room (100 in Figure 6), a drive gear 23 is fixed to the drive shaft of the motor 21, The driven gear 25 meshes with the drive gear 23.

The motor 21 is fixed to one lower side of the base plate 19. The motor 21 is an AC servo motor that receives a signal output from the computer 43 of the control room 100 and rotates by a predetermined angle, and includes elements for enabling remote control such as a driver controller, an encoder, a serial port, and the like. It is. The computer 43 and the motor 21 are connected through a known RS-232C module.

In addition, the reducer is built in to reduce the rotation speed of the drive shaft and increase the output. The reduction ratio of the reducer is 1:40. This means that when the rotor inside the motor rotates 40, the drive shaft rotates once.

In addition, the motor 21 sets 360 degrees to 800,000 pulses. However, the angle-to-pulse ratio for driving the motor can be changed in various cases.

The drive gear 23 is a spur gear fixed to the drive shaft of the motor passing upward through the base plate 19, and is spaced apart from the surface of the base plate 19. The driven gear 25 meshing with the drive gear 23 is bearing-supported on the upper portion of the base plate 19 and rotates following the rotation of the drive gear 23. The tooth ratio of the drive gear and the driven gear is 1: 2.

Therefore, considering the reduction ratio of the motor and the number of teeth of the driving gear and the driven gear, the final mechanical reduction ratio is 1:80. Considering that the above-mentioned 360 degrees are set to 800,000 pulses, the rotational accuracy of the driven gear 25 is 1/177778 °. That is, the rotational precision of the sound level meter 13 is 1/177778 degrees. That is, the maximum error when the sound level meter 13 rotates 1 degree is 1/177778 degree. Compared to the previous manual setting of sound level meter.

Reference numeral 18 is a power supply. The power supply is generally involved in driving the motor 21.

The connecting block 27 is fixed to the upper portion of the driven gear 25. The connecting block 27 is fixed to a power transmission shaft (33 in FIG. 3) fixed to the rotation center of the driven gear 25, and rotates together with the driven gear 25.

In addition, the upper portion of the connection block 27 is a sound level meter support portion 47 for supporting the sound level meter 13 in a horizontal position. The sound level meter support portion 47 is fixed to the upper portion of the connecting block 27, the rotating plate 29 and the rotating shaft using the power transmission shaft 33 as a rotating shaft, and the upper portion of the rotating plate 29 It is fixed to and includes a support frame 39 for horizontally fixing the sound level meter plate 37.

The rotating plate 29 rotates while being kept horizontally on the top of the base plate 19. In addition, the lower portion of the rotating plate 29, the rotating plate 29 is prevented from being bent downward, the interval maintaining portion for maintaining the interval of the rotating plate 29 with respect to the base plate 19 is provided.

The gap holding part is fixed to the bottom surface of the rotation plate 29 and the support rod 31 of the hollow pipe form extending vertically downward, and is located on the lower end of the support rod 31 and elastically supported downward, the rotation plate It consists of a ball 31a which is clouded at the time of rotation of (29). The ball 31a is elastically supported downward by a spring (not shown) provided in the support rod 31, and moves on the upper surface of the base plate 19.

The sound level meter 13 includes a main body 13c and a microphone 13a extending in the longitudinal direction from the main body 13c as an inspection object to inspect the directivity characteristic. In particular, the sound level meter 13 is set so that the longitudinal extension of the microphone 13a reaches the sound source 11. Of course, a separate fixing means may be added to more stably maintain the fixing of the sound level meter 13 with respect to the sound level meter fixing plate 37.

Reference numeral 13b denotes a display window on which the content measured by the sound level meter is displayed. The display window 13b displays an amount of noise in decibels (dB) as an LCD window.

In addition, the camera support 41 is provided at the rear of the sound level meter 13. The camera support 41 supports the camera 35 as a support member fixed to the rear end of the sound level meter fixing plate 37.

The camera 35 photographs the noise level information displayed on the display window 13b and transmits the information to the computer 43 of the control room 100. The camera 35 and the computer 43 are wirelessly or wiredly connected.

FIG. 3 is an exploded perspective view showing an exploded view of a main part of the directional characteristic measuring device 15 shown in FIG.

Referring to the drawings, it can be seen that the arcuate support surface 19a is formed at both sides in the width direction of the base plate 19. The arc-shaped support surface 19a is a portion where the ball 31a rolls over it. It goes without saying that the curvature of the arc-shaped support ground 19a is equal to the curvature of the imaginary circle centered on the power transmission shaft 33.

A plurality of teeth 33a are formed on an outer circumferential surface of the power transmission shaft 33 which is fixed to the center of rotation of the driven gear 25 and extends vertically upward. The vertical line passing through the center of rotation of the power transmission shaft 33 meets the microphone 13a of the sound level meter 13. Therefore, the sound level meter 13 rotates within the range of 180 degrees with the power transmission shaft 33 as the rotation shaft. This will be described with reference to FIGS. 4 and 5.

A fixing hole 29a is formed in the connection block 27 and the rotation plate 29. The fixing hole 29a is a hole through which the power transmission shaft 33 passes upward, and teeth 29b are formed on the inner circumferential surface thereof. The tooth 29b is engaged with the tooth 33a of the power transmission shaft and rotates during the rotation of the power transmission shaft 33 to rotate the rotation plate 29.

4 and 5 are diagrams for explaining the operation of the directivity measuring device 15 shown in FIG.

In order to check the directivity characteristic of the sound level meter 13 using the measuring apparatus 15 which concerns on a present Example, the sound level meter 13 is set on the upper part of the sound level meter fixing plate 37 first. At this time, the extension line of the microphone 13a of the sound level meter 13 should reach the sound source 11, and the end of the microphone 13a should be located vertically above the power transmission shaft 33.

In this state, the sound source 11 and the motor 21 are operated using the computer 43 in the control room 100. That is, in the setting state of FIG. 4, the noise is generated so that the sound level meter 13 measures the noise level at that time, and when the measurement of the noise is completed, the magnitude of the noise is read by the camera 35 and sent to the computer 43. .

Through the above process, if the noise measurement in the direction is completed, the motor 21 is operated to rotate the sound level meter 13 by 1 ° in the direction of the arrow a, and then the above process is repeated to remove the noise in the direction. Measure the size.

Subsequently, by using the motor 21, the sound level meter 13 is further rotated by 1 ° until the sound level meter 13 reaches a position of + 90 ° as shown in FIG. The magnitude of the noise is measured and stored in the computer 43.

If the above 91 measurements are completed, this time, the motor 21 is rotated in reverse, and the sound level meter 13 is rotated by 1 ° in the direction of −90 °, and noise at each angle is measured.

Subsequently, the operator determines the directivity characteristic of the sound level meter 13 based on the data stored in the computer 43.

6 and 7 are views illustrating an anechoic chamber 200 and a control room 200 in which a sound level meter directivity measurement apparatus according to an embodiment of the present invention is located.

As shown in the drawing, the measurement device 15 and the sound source 11 of this embodiment are installed inside the anechoic chamber 200 so as to face each other, and the computer 43 is located in the control room 100 which is separated from the anechoic chamber 200. Is located.

The computer 43 is connected to the motor 21 and the camera 35 through a known wired / wireless communication method to remotely control the motor 21 and receive the photographed contents of the camera 35.

In particular, in the case of the measuring device 15 shown in Figure 7 the camera 35 is missing, this is when testing the sound level meter 13 is provided with a communication port itself. That is, when the sound level meter 13 and the computer 43 are connected by a separate wired or wireless communication method, when the content measured by the sound level meter can be sent to the computer 43 through the communication, the camera 35 is not necessary.

As a result, the sound level meter directivity characteristic measuring device 15 according to the present embodiment, which is made as described above, is remotely controlled by the computer 43 in a state in which it is disposed in the anechoic chamber 200, thereby enabling accurate and rapid measurement work.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

11: Sound source 13: Silencer 13a: Microphone
13b: display window 13c: main body 15: measuring device
17: tripod 17a: leg 17b: hub
17c: fixed part 17d: set screw 17e: pillar
18: power supply 19: base plate 19a: arc-shaped ground
21: motor 23: drive gear 25: driven gear
27: connecting block 29: rotating plate 29a: fixing hole
29b: Teeth 31: Support Rod 31a: Ball
33: power transmission axis 33a: teeth 35: camera
37: Sound meter fixed plate 39: Support frame 41: Camera support
43: computer 45: drive part 47: sound level
100: control room 200: anechoic chamber 202: floor

Claims (6)

It is installed inside the anechoic chamber, and is established at a point spaced apart from the sound source in the anechoic chamber by holding a sound level meter to check the directivity characteristics.
A height adjusting part which is erected on the bottom of the anechoic chamber and whose height is adjustable; A horizontal base plate fixed to an upper part of the height adjusting part and providing a support force; A driving unit mounted to the base plate and remotely controlled by a signal transmitted from a control unit outside the anechoic chamber to generate rotational torque; It is connected to the drive unit and rotates within a certain angle range during operation of the drive unit, and includes a sound level meter support for fixing the sound level meter on the top,
The drive unit is fixed to the lower portion of the base plate, and generates a rotational torque by an external control signal, a drive gear fixed to the drive shaft of the motor and positioned on the upper base plate, and meshes with the drive gear A driven gear and a power transmission shaft fixed to an upper portion of the center of rotation of the driven gear and extending vertically;
The sound level meter support portion is fixed to the power transmission shaft and when rotating the power transmission shaft, the horizontal rotation plate to rotate by using the power transmission shaft as the rotation axis, the support frame fixed to the upper portion of the rotation plate, and the support frame It is provided on the upper side, the sound level meter directional characteristic measuring device, characterized in that it supports the sound level meter in a lying state, the sound level meter fixing plate for supporting the microphone of the sound level meter is located in the vertical upper portion of the rotating shaft of the rotating plate. delete delete The method of claim 1,
The rotating plate is located horizontally on the top of the base plate,
The bottom surface of the rotating plate, the sound level meter directional characteristic measurement device further comprises a gap maintaining portion for maintaining the interval of the rotation plate with respect to the base plate during the rotation of the rotation plate. The method according to claim 1 or 4,
The side of the sound level meter is provided with a display window for displaying the content measured by the sound level meter,
The sound level meter support unit further includes a camera for reading the contents displayed on the display window and transmitting the readings to a control unit outside the anechoic chamber. The method of claim 1,
And a driving unit connected to the control unit through an RS-232C module.

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