KR100262905B1 - Apparatus for testing noise performance - Google Patents

Abstract

The present invention relates to a sound insulation test apparatus capable of quantitatively testing the sound insulation performance of surface structures or soundproof structures, such as transportation machinery, electronic products, and industrial machinery. The sound insulation performance can also be tested accurately, and it is possible to test at low cost and convenience.

According to the present invention, the noise generating mechanism 12 is installed inside and has a polygonal sound cylinder 10 having an opening 11 formed on one surface thereof, and is connected to the sound cylinder 10 opposite to the opening 11. The sound transmission opening portion 22 communicating with the polygonal sound receiving cylinder 20 formed on one surface, between the sound source cylinder 10 and the opening 11 and the sound transmission opening portion 22 of the sound receiving cylinder 20. Specimen support member 30 is installed in the sound source cylinder 10 and the sound receiving cylinder 20 and the sound measuring means 14, 24 provided in the sound source cylinder 10 and the receiving cylinder 20 While satisfying the expanded sound field conditions, the volume of the sound cylinder 10 is formed to 0.5 to 3 ㎥, and the volume of the sound receiving tube 20 is formed to 1 to 10 ㎥.

Description

Soundproof Tester

The present invention relates to a soundproofing test apparatus, and more particularly, to a soundproofing tester capable of quantitatively testing soundproofing performance of surface structures or soundproofing structures, such as transportation machinery, electronic products, and industrial machinery.

As is well known, noise produced by transportation machines, electronic products, industrial machines, etc., is an important concern for passengers or consumers when the products are sold, and each manufacturer is taking sound insulation measures.

The most economical and effective approach to the development of the noise-generating products is the sound insulation design technique, which is the magnitude of noise that is reduced when the noise generated from the noise-generating products is delivered to the listener. In general, the greater the noise reduction, the better the sound insulation performance.

When designing sound insulation of noise-generating products at industrial sites, effective sound insulation can be expected if objective and scientific evaluation data are provided for the sound insulation performance of each structure, for example, transportation equipment.

The sound insulation performance test system has been proposed by the International Organization for Standardization (ISO) and is defined in IS O-140. The sound insulation performance test system described above is composed of two large reverberation chambers, namely 30㎥ of concrete, which is sealed to the outside and has good sound insulation characteristics. The sound source room and the sound receiving room are formed to face each other, and the sound source wall is sealed between the sound source room and the sound absorbing room and at the same time, a noise transmission path is formed on the soundproof wall, and a rail is installed above and below the passage, and the rail has a noise transmission path. Install a specimen with a large area and move the specimen along the rail to the noise transmission path, install the specimen, or install a specimen that completely seals the noise transmission path directly to the noise transmission path, and then install the specimen in the sound source room. The sound source and the sound pressure of the sound source room are operated by transferring the noise generated from the sound source room to the sound receiving room through the specimen The sound pressure of the sound room is measured and the difference is evaluated as the sound insulation value. The sound insulation performance test system is generally used for the sound insulation performance test of building materials because the noise transmission path is formed in the size of 10-12 m 2.

However, the sound insulation performance test system specified in IS O-140 should be constructed in the form of a reverberation chamber and a sound chamber in a fixed form, and the specimens must be transported to the test site. It will take.

In addition, if the area of the noise transmission path is formed from 10 to 12㎡, if the specimen is smaller than the area of the passage, interconnect the plurality of specimens or block the noise transmission passage with sound insulation such as a thick steel plate, and then connect the noise transmission passage to the sound insulation. Since it is necessary to install and test the specimen, the reliability of the test value will occur.

In particular, the sound insulation performance test system described above cannot accurately conduct sound insulation performance tests of structures made of materials with a high sound insulation performance of about 50 dB.

That is, the conventional sound insulation performance test system is to test the sound insulation performance of building materials. Generally, the sound insulation performance of building materials is about 20 to 40 dB, for example, 50 dB for doors of automobiles and railway vehicles, which are transporting machines. Since the material with the above sound insulation performance is used, the noise level of the sound source room should be increased to 120dB or more for the sound insulation performance test of the door. Speaker) does not exist.

It is an object of the present invention to provide a sound insulation test apparatus capable of accurately testing the sound insulation performance of a structure having an area of 5 m 2 or less.

Another object of the present invention is to provide a sound insulation test apparatus that can accurately test the sound insulation performance of a structure having a sound insulation performance of 50 dB or more.

Still another object of the present invention is to provide a sound insulation test apparatus that can conveniently test sound insulation performance at low cost.

In order to achieve the above object, the present invention is a noise generating mechanism is provided inside the polygonal sound cylinder and the opening is formed on one surface, the sound transmission opening is connected to the sound cylinder and communicated with the opening is formed on one surface A polygonal sound receiving passage, a specimen support member provided between the opening of the sound source and the sound receiving tube and the noise transmission opening portion, and a noise measuring means provided in the sound source and the receiving cylinder, wherein the sound passage and the sound receiving tube have an extended sound field condition. At the same time the volume of the sound cylinder is formed to 0.5 to 3 ㎥ and the volume of the drinking vessel is to form 1 to 10 ㎥.

1 is a cross-sectional view of an embodiment of the present invention.

2 is a perspective view of a sound cylinder of an embodiment of the present invention;

3 is a perspective view of a water collecting container according to an embodiment of the present invention;

Figure 4 is an enlarged view of the noise measuring means of an embodiment of the present invention

Figure 5 is an enlarged view of the noise measuring means of another embodiment of the present invention

6 is a perspective view of a specimen support member of an embodiment of the present invention;

7 is a schematic diagram of an embodiment of the present invention.

<Description of the code | symbol about the principal part of drawing>

10: sound source, 12: noise generating mechanism, 13: amplifier, 14, 24: noise measuring means,

20: sound receiver, 30: specimen support member, 148: microphone, 149: sound level recorder

1 to 3, the present invention is roughly divided into a sound cylinder 10 and a receiver 20.

The sound cylinder (10) is made of a steel plate of 3 to 6 mm thick with a polygonal sealed structure of 4 to 12 polygons, and at the same time, the inner surface is smoothly formed so that noise can be heard and only a noise transmission path is provided at the top. The opening 11 is formed, and the outside thereof is covered with a dustproof material such as a coaltal to damp vibrations, and a seal 15 is provided around the opening 11.

In addition, noise generating mechanisms 12, such as two to five speakers and pistols, are provided on the inner bottom or sidewall of the sound cylinder 11, and the noise generating mechanism 12 is provided outside the sound cylinder 11. It is connected to the amplifier 13 is installed, the sound measuring means 10 is provided inside the noise measuring means (14).

In addition, the sound cylinder 10 is cross-sectional in order to meet the expansion sound field conditions, that is to prevent the generation of standing waves in the noise generated by the noise generating mechanism 12 installed inside the sound cylinder 10 to minimize the deviation of the noise The ratio of horizontal or vertical to vertical or horizontal is 1: 1.2 to 1.3, and the ratio of horizontal or vertical height is 1: 1.2 to 1.3, and the surfaces facing each other are not parallel to each other. The ratio of any length should be larger than 1: 0.5 and smaller than 1: 2, the volume of which is 0.5-3m 3 and the surface area of 1-5m 2.

The sound receiving cylinder 20 is formed in the same material and shape as the sound cylinder 10, and installed on the bottom to face the sound cylinder 10 as a support (21), the lower specimen (TS) In addition to forming the noise transmission opening portion 22 that can be introduced into the sound absorbing tube 20, the sound is blocked at the same time there is provided the same noise measuring means 24 installed in the sound cylinder (10).

And the sound receiving cylinder 20 is formed so as to meet the expansion sound field conditions, as the sound source 10, the volume is formed to be 1 ㎥ ~ 10 ㎥ and the surface area is 3 ㎡ ~ 30 ㎡.

1 to 4, the noise measuring means 14 and 24 are provided with support members 140 on sidewalls of the sound cylinder 10 and the sound receiving cylinder 20, as shown in FIGS. The support shaft 141, which has the prime bevel gear 143 installed on the other end thereof, is supported so that the handle 142 is exposed to the outside, and the support piece 144 is installed on the support member 140 to provide the prime bevel gear ( At the same time as supporting the support shaft 146 in which the driven bevel gear 145 engaged with the 143 is installed, a lever 147 is installed on the support shaft 146 to install a microphone 148 at the tip thereof. A noise level recorder 149 such as a digital, analog or plotter is connected to the conductor 150 at 148, and an indication point 151 is displayed at the handle 142 position of the side wall. ) By rotating the point by point 151, the microphone 148 is rotated 360 degrees to improve the noise level of many points in the sound source chamber 10 and the sound receiving chamber 20. After the measurement, the handle 142 is rotated forward and backward to prevent the cutting of the conductive wire 150, and the noise level is measured for each indication point 151 to obtain an average value.

FIG. 5 is an automated embodiment of the manual noise measuring means of FIG. 4 as another embodiment of the noise measuring means, as the switch 242 to the support member 240 fixed to the side wall of the sound cylinder 10 and the sound receiving cylinder 20. A DC motor 241 for reverse rotation operation is installed, a lever 244 is installed on the shaft 243, a microphone 148 is installed at the tip of the lever 244, and a noise level recorder is mounted on the microphone 148. 149 is connected with a conductive wire, and the average value is obtained by measuring the noise level while rotating the DC motor 241 at a constant angle or reverse rotation or by slowly rotating the DC motor 241 by the operation of the switch 242.

Meanwhile, between the opening 11 and the noise transmission opening 22 of the sound cylinder 10 and the sound receiving cylinder 20, a specimen support member 30 as shown in FIGS. 1 and 6 is installed. The member 30 is provided with seals 31 and 31 'around the top and bottom thereof, and at the same time, forms the noise transmission hole 32 to fix the specimen TS to seal it in the noise transmission hole 32. .

In addition, the ratio of the horizontal or vertical to vertical or horizontal of the specimen support member 30 and the noise transmission hole 32 is formed in the ratio of 1: 1.2 to 1.3 in the same manner as the sound source 10 and the receiver 20. , The ratio of the width or length should be larger than 1: 0.5 and smaller than 1: 2, and the area of the noise transmission hole 32 is determined in the range of 0.4-5 m 2, and the area of the specimen TS is 0.5 m 2 or more. It is.

In addition, when the specimen support member 30 is installed or separated between the sound receiving cylinder 20 and the sound cylinder 10, the actuator 40 is installed between the sound cylinder 10 and the bottom, and the actuator 40 is hydraulic or pneumatic, and the piston 41 is provided with a piston 42 having a support piece 43 supporting the bottom of the sound cylinder 10 in the cylinder 41 to operate the switching valve 44. 42) to elevate.

That is, in the state in which the piston 42 is lowered, the sound cylinder 10 and the specimen support member 30 maintain their lowered state by their own weight, and the sound receiving cylinder 20 maintains the state supported by the support 21. Since the space portion is formed between the cylinder 10 and the sound receiving cylinder 20, the installation and separation of the specimen support member 30 is convenient. In addition, in order to make the installation and separation of the specimen (TS) even more convenient, the sound cylinder (10) is lowered and then moved horizontally to install or remove the specimen support member (30) and the specimen support member (30) to receive the water container ( It can also be raised after moving to the lower part of 20).

In addition, in order to test the sound insulation performance of the specimen (TS), after fixing the specimen (TS) to the drawn specimen support member 30, the specimen support member 30 to the sound source so that the specimen (TS) to the sound source cylinder 10 side When the piston is mounted on the upper part of the cylinder 10 and the piston 42 is raised, the specimen support member 30 and the specimen TS are disposed between the sound receiving cylinder 20 and the openings 22 and 11 of the sound source cylinder 10. The seals 31, 31 'and 15 are installed in close contact with each other so that there is no leakage of noise therebetween.

According to the present invention as described above, after installing the specimen (TS) between the sound receiving cylinder 20 and the sound cylinder 10, the noise generating mechanism 12 is driven by the amplifier 13 to each octave in the sound source chamber 10. Or at least 90 dB per third octave band.

The noise generated in the sound source room 10 is distributed as the sound pressure is formed as the expansion sound field as described above, the sound pressure distributed as described above rotates the handle 142 by each indication point 151 to rotate the microphone 148 360 ° The sound level is measured by measuring the noise level of at least 8 points or more with the noise level measuring instrument 149, and then averaged by the noise level.

On the other hand, the noise generated in the sound source room 10 is transmitted to the test piece TS through the opening part 11, and then the sound is generated in the sound receiving room 20 through the noise transmission opening part 22 formed in the sound receiving room 20. The sound transmitted to the sound absorbing room 20 is distributed as the sound pressure is distributed while the expansion sound field is formed, and thus the sound pressure distributed as described above measures the noise level in the same manner as the sound source room 10 in the noise measuring means 24. The sound insulation performance of the test piece TS is measured by the difference between the measured value of the sound source chamber 10 and the measured value of the sound absorbing chamber 20.

The test apparatus of the present invention is simple to move because the sound source chamber 10 and the sound absorbing chamber 20 are made of steel sheet to meet the expansion sound field conditions and a specimen is installed therebetween to test the sound insulation performance of the structure. This is convenient, and the cost of manufacturing and testing the test apparatus is reduced.

In addition, the test apparatus of the present invention can generate a noise level of more than 120dB of sound source room, so the sound insulation performance of the transportation equipment, industrial machinery, etc., with a sound insulation performance of 50dB or more, can also accurately test the sound insulation performance of doors having an area of 5㎡ or less. It can be.

In the above embodiment has been described that the sound source cylinder 10 and the receiving cylinder 20 is installed up and down, of course, the sound source cylinder 10 and the receiving cylinder 20 may be installed horizontally.

As described above, the present invention is made of a steel plate to meet the expansion sound field conditions of the sound cylinder and the sound receiving tube, and the specimen between them can test the sound insulation performance, so the structure is simple, easy to move, the production and testing of the test apparatus The cost is reduced.

In addition, since the sound level of the sound source room can be generated more than 120dB, the sound insulation performance of the structure with the sound insulation performance of 50dB or more and the area of 5㎡ or less can be accurately tested.

Claims (5)

The sound source of the polygon is provided inside the noise generating mechanism and the opening is formed on one side of the polygon, the sound receiving opening of the polygon is formed on one side of the sound transmission opening is connected to the sound source and communicates with the opening, And a specimen support member installed between the opening portion and the noise transmission opening portion, and noise measuring means installed in the sound cylinder and the receiving cylinder, wherein the sound cylinder and the receiving cylinder satisfy the expansion sound field conditions and at the same time the volume of the sound cylinder is Sound insulation test device formed by 0.5 to 3㎥ and the volume of the water collecting container to 1 to 10㎥ The sound insulation test apparatus according to claim 1, wherein the area of the noise transmission hole provided in the specimen support member is 0.4 to 5 m 2 or less. According to claim 1, The noise measuring means is provided with a support member on the side walls of the sound cylinder and the sound receiving cylinder to support the support shaft with the handle at one end and the driving bevel gear at the other end so that the handle is exposed to the outside, the support member Sound insulation test by installing a support piece to support the support shaft on which the driven bevel gear is meshed with the driven bevel gear, and at the same time by installing a lever on the support shaft to install a microphone at its tip, and connecting a noise level recorder to the microphone. Device According to claim 1, The noise measuring means is provided with a direct current motor to the support member fixed to the side wall of the sound cylinder and the receiving cylinder, the lever is installed on the shaft, and the microphone is installed at the tip of the lever to connect the sound level recorder Sound insulation test equipment The sound insulation test apparatus according to claim 1, wherein an actuator is installed between the sound cylinder and the floor to raise and lower the sound cylinder.