KR101260823B1 - Diffraction noise reduction device for noise barrier upper edge using helmholtz resonance absorber - Google Patents

Abstract

The present invention relates to a noise barrier upper diffraction sound reduction device using a Helmholtz sound absorber having a variable function of resonance frequency; It is installed horizontally on the upper end of the soundproof wall is installed on one side of the track that the train moves, characterized in that the through-hole is formed in communication with the space portion in the upper portion of the chamber in which a plurality of space portion is partitioned.
According to the present invention, the diffraction sound reduction device using the Helmholtz resonance principle at the top of the soundproof wall is provided to reduce the diffraction sound at the top of the soundproof wall, thereby compensating the limitation of the performance of the conventional upright soundproof wall. In particular, the present invention has the advantage of overcoming the technical limitations of the existing railway soundproof wall performance, and to expand the soundproofing wall effect and sound absorbing position according to the noise source location and characteristics according to the speed of the train operation.

Description

Diffraction noise reduction device for noise barrier upper edge using helmholtz resonance absorber

The present invention relates to an apparatus for reducing diffraction sound at the top of a soundproof wall using a Helmholtz sound absorber having a variable resonant frequency, and more specifically, to reduce the acoustic energy passing over the soundproof wall by using the Helmholtz resonance principle. The present invention relates to a device for reducing diffraction sound at the top of a sound barrier using a Helmholtz sound absorber having a variable resonant frequency to compensate for sound barrier performance due to sound.

In general, railway noise barriers have a variety of noise sources that are incident toward noise barriers due to the noise source distribution characteristics of railroad cars, and their characteristics vary according to the operating characteristics of railways.

Conventional railway noise barriers have been constructed and constructed using the shape and structure of general noise barriers considering incidence at a low position incident toward the sound barrier at the contact surface where the road and wheel contact, such as road noise.

However, as the railway speeds up, there is a high noise source such as a pantograph (current collector), and not only the pantograph but also the railroad cars that operate at high speed emit noise at the height of the upper body.

The existing soundproof wall technology to block the noise caused by the operation of the railway vehicle is based on the soundproof wall and the upper corner of the soundproof wall. It is divided into the form of additional noise reduction device attached to the top of the soundproof wall for the purpose of blocking the low frequency sound which is relatively long wavelength. At this time, the noise reduction device on the top of the sound barrier is divided into interference type and sound absorption type according to the physical implementation principle.

As an example, there is a technology described in Korean Patent No. 10-0634348 as shown in FIGS. 17 and 18. Looking at the technical features, a foundation portion in which concrete 12 is poured to have a constant width and height on the ground The base plate 22 of the support portion 20 and the support 20 and the base plate 22 is fixed to the base 10 by a plurality of base plates 22 at regular intervals. The soundproof plate portion 40 and the support pillar, each of which is formed by stacking a plurality of sound insulation plates 42 having sound absorbing holes formed on the surface between the support portions formed by assembling and coupling the H beams respectively to the H beams. One side is welded to the upper end of the H beam at the same time while being assembled to the bracket 50 made of the T-shaped steel plate 52 and the steel plate 52 of the bracket 50 while covering the upper end of the soundproof plate portion 40. Made of open polygonal steel plate 62 It is characterized by consisting of a true noise damping unit (60).

However, railway noise is distributed by height unlike road noise, and although the noise and noise distribution of railroad cars whose frequency characteristics are changed according to the operating speed band should be considered, the conventional soundproof walls are used to distribute the noise sources of such railroad cars. And the characteristics are not reflected at all, and most of them are designed and constructed in consideration of the noise source radiating from the lower (ground) position, there is a problem that the noise reduction can not be made efficiently.

In addition, the existing resonance, sound absorption and interference noise reduction device technology improves the sound insulation performance of a simple upright sound barrier in a specific narrow band frequency range, but due to the physical characteristics of the resonator, the frequency range and the receiver position are adversely affected. exist.

Therefore, the present invention is to solve these problems, the object of the sound barrier to reduce the acoustic energy that rides to the top of the sound wall by using the Helmholtz resonance principle to compensate for the limitation of the sound wall performance due to the diffraction sound on the top of the sound wall It is to provide a diffraction sound reduction device at the top.

In order to solve such a technical problem,

It is installed horizontally on the upper end of the soundproof wall is installed on one side of the track that the train moves, the through-hole is in communication with the space portion is formed in the upper portion of the chamber is divided into a plurality of space portion of the resonant frequency variable function Provided is a diffraction sound reduction device on the top of a soundproof wall using a Helmholtz sound absorber.

In this case, the plurality of spaces formed in the chamber is formed independently by the partition wall, characterized in that the upper end of the chamber is formed by the through hole is in communication with the space portion and narrower diameter than the space portion is formed.

The chamber may include: a lower plate installed in a horizontal direction on an upper end of the soundproof wall; a partition wall forming a plurality of space portions on an upper portion of the lower plate; and an integral portion fixed to an upper portion of the partition wall to close the space portion; A plurality of through holes are formed to maintain a constant interval so as to communicate with the part is characterized by consisting of a top plate formed.

At this time, the partition is characterized in that it is installed in a grid form.

In addition, the chamber is installed in the longitudinal direction of the soundproof wall is characterized in that it has a predetermined width.

And, the chamber is characterized in that consisting of a rectangular parallelepiped shape.

On the other hand, a slide member is formed on an upper portion of the upper plate, the slide member is characterized in that the first secondary through hole of the same size as the through hole, and the second secondary through hole formed smaller in diameter than the through hole is formed.

In addition, the upper portion of the upper plate is formed with a slide member, the slide member is formed in two rows of the first auxiliary through hole of the same size as the through hole, the first column is formed to correspond to the through hole formed in the upper plate, the second column in the upper plate Characterized in that less than the number of through holes formed in the.

On the other hand, a slide member is formed in the upper portion of the upper plate, characterized in that the first auxiliary through hole of the same size as the through hole is formed in the slide member.

Here, the side portion of the chamber is characterized in that the control unit for controlling the opening degree of the through hole by controlling the movement of the slide member.

At this time, the control unit, the rack gear is installed on the side of the slide member, the pinion gear is installed on the side of the chamber, the motor is installed the pinion gear, a frequency analyzer for detecting and measuring the frequency of the noise and And a controller for controlling the rotation of the motor according to the frequency detected by the frequency analyzer.

On the other hand, the chamber is characterized in that the through-hole is formed in the upper portion, consisting of a plurality of unit cells having a different height.

In addition, the unit cell is characterized in that the cylindrical or rectangular cylinder shape.

According to the present invention, the diffraction sound reduction device using the Helmholtz resonance principle at the top of the soundproof wall is provided to reduce the diffraction sound at the top of the soundproof wall, thereby compensating the limitation of the performance of the conventional upright soundproof wall.

In particular, the present invention has the advantage of overcoming the technical limitations of the existing railway soundproof wall performance, and to expand the soundproofing wall effect and sound absorbing position according to the noise source location and characteristics according to the speed of the train operation.

1 is a view showing the installation state of the top sound-proof diffraction sound reduction device using the Helmholtz sound absorber of the variable function of the resonant frequency according to the present invention.
2 is a plan view showing a chamber of the present invention.
3 is a front view of the chamber of the present invention.
4 is a side view of the chamber of the present invention.
5 is a view showing a part of the upper plate constituting the chamber of the present invention.
6 is a soundproof wall in a state in which the diffraction sound reduction device is not installed and installed on the top of the soundproof wall in the anechoic chamber for the design of the soundproof wall upper diffraction sound reduction device using the Helmholtz sound absorber having a variable resonant frequency according to the present invention. It is a graph showing the performance improvement over the frequency band obtained by comparing the noise level measured from the back.
7 is an anechoic chamber test installation diagram of a sound absorbing wall upper diffraction sound reduction device using a Helmholtz sound absorber having a variable function of resonant frequency according to the present invention.
8 is a conceptual diagram of an anechoic chamber test of an upper diffraction sound reduction device of a soundproof wall using a Helmholtz sound absorber having a variable function of resonant frequency according to the present invention.
9 is a diagram showing a noise reduction degree different from the test of FIG. 7.
FIG. 10A is a partially enlarged view of a top plate according to another exemplary embodiment of the present invention, and FIG. 10B is a cross-sectional view of FIG. 10A.
FIG. 11A is a partially enlarged view of a top plate according to still another embodiment of the present invention, and FIG. 11B is a cross-sectional view taken along the line AA of FIG. 11A.
12 is a schematic view of an adjustment unit installed on the side of the chamber according to another embodiment of the present invention.
FIG. 13 is a block diagram of FIG. 12.
14 is a state diagram showing the operation of FIG.
15 is a schematic diagram of different heights of unit cells constituting a chamber according to another embodiment of the present invention.
16 is a conceptual diagram illustrating an installation position of a chamber according to another embodiment of the present invention.

With reference to the accompanying drawings, a sound absorbing wall top diffraction sound reduction device using a Helmholtz sound absorber having a variable function of resonant frequency according to the present invention will be understood by the embodiments described in detail below.

1 to 5 according to the present invention by using the Helmholtz sound absorber of the resonant frequency variable function according to the present invention, the upper diffraction sound reduction device 100 by using the Helmholtz resonance principle to reduce the acoustic energy passing over the soundproof wall Overcoming the technical limitations of the existing railway soundproof wall performance, it is possible to expand the soundproof wall effect and sound absorbing position according to the noise source location and characteristics according to the high speed of train operation.

At this time, the Helmholtz sound absorber is a respirator using a resonator having a relatively small opening with a volume, and has a structure with a short neck and a large volume compared to the wavelength of interest. The air in the neck portion is a mass, and the volume of the cylinder is It acts as a spring and the natural frequency is determined by this mass and the spring, and it is designed to produce the largest sound absorption at the resonant frequency.

The upper diffraction sound reduction device 100 of the soundproof wall using the Helmholtz sound absorber of the variable function of the resonant frequency according to the present invention is installed horizontally on the top of the soundproof wall 200 is installed in a vertical direction on one side of the track on which the train moves In this case, a narrow through hole 114a communicating with the space 112a is formed at an upper portion of the chamber 110 in which the plurality of spaces 112a are partitioned by the partition wall 112.

At this time, each space portion 112a formed in the chamber 110 is formed independently by the partition wall 112, and communicates with the space portion 112a at an upper end of the chamber 110 and the space portion ( A through hole 114a having a smaller diameter than that of 112a is formed.

In addition, the fact that the upper end of the chamber 110 is the main reinforcement target for the performance of sound waves that are directly incident close to the angle of the right angle at a high position and the sound diffraction wall having a relatively small diffraction angle rather than the lower region behind the soundproof wall 200. (200) In order to improve the sound absorbing position near the upper region or the upper portion of the soundproof wall upper diffraction sound reduction device 100 using a Helmholtz sound absorber having a variable function of resonant frequency according to the present invention, the soundproof wall 200 together with T- To form.

The chamber 110 will be described in more detail. The chamber 110 is installed on the top of the soundproof wall 200 in a horizontal direction, and is installed in a lattice form on the top of the bottom plate 116. A plurality of spaces 112a formed therein, and a plurality of spaces 112a are integrally fixed to an upper portion of the partitions 112 so as to close the spaces 112a and communicate with the spaces 112a on a surface thereof. The through hole 114a of the upper plate 114 is formed while maintaining a constant interval.

At this time, the chamber 110 as a whole is installed in the longitudinal direction of the soundproof wall 200 to have a predetermined width. In this case, the width, length and height of the chamber 110 can be adjusted to suit various design criteria, but preferably made of a rectangular parallelepiped shape.

On the other hand, the upper plate 114 is formed through holes 114a in the form of perforations in order to match the mass per unit area due to the mass of the air particles, each of the space portion 112a which can be understood as the air layer is divided into a lattice form. .

At this time, the chamber 110 should be designed in a direction where the spatial position of the acoustic impedance of the minimum value is distributed in the region where sound waves are diffracted as much as possible at the top and obstructs the shape. It is easier than producing a long oval and has the advantage of low production cost.

In addition, the chamber 110 has a larger sound effect as the width of the top is wider to improve the performance of the simple upright type under the conditions of incident noise and sound absorption, but the width is considered in consideration of the influence of strong winds or structural stability in the installation area. It is preferable to adjust appropriately.

In addition, the inner diameter of the space portion 112a corresponding to the air layer of the chamber 110 should be smaller than the half wavelength of the sound wave of interest. When the inner diameter of the space portion 112a of the chamber 110 is the half wavelength of the incident sound wave, the first transverse transverse mode is generated in the space portion 112a of the chamber 110, so that the effect may be significantly lower than when the inner diameter is small. Because.

On the other hand, the present invention is to control the acoustic impedance and the resulting acoustic energy on the top of the soundproof wall 200 by using the principle of the Helmholtz resonator, and to improve the performance of the soundproof wall 200 in the target frequency range and the target sound receiving position It is important to find the optimal acoustic impedance to match.

Therefore, using the resonance frequency deriving principle of the simple resonator composed of mass and spring, the area of the through hole 114a with respect to the thickness of the top plate 114 of the chamber 110 and the area of the top plate 114 of the chamber 110 is occupied. By determining numerical values such as the ratio, the size of the through hole 114a, and the like, the acoustic impedance of the upper diffraction sound reduction device 100 of the soundproof wall using the Helmholtz sound absorber having a variable function of the resonance frequency according to the present invention is obtained.

Under such conditions, the effect is different for each frequency region of noise depending on the resonance frequency region set in order to design the top diffraction sound reduction device 100 using the Helmholtz sound absorber having a variable function of the resonance frequency according to the present invention. (See Figure 6)

In this case, the graph is designed and verified in consideration of the noise of the high-speed railway traveling at 300 km / h, but the size, height, and top plate of the unit cell forming the resonance-type upper end according to the frequency range for which the performance is to be improved. By designing different perforation structure of), it can be used for noise in various frequency ranges and various noise sources.

To this end, as shown in FIGS. 7 and 8, the upper diffraction sound reduction device 100 of the soundproof wall using the Helmholtz sound absorber having a variable function of resonant frequency according to the present invention is installed on the top of the soundproof wall 200, and the soundproof wall ( On one side of the 200 is provided a speaker 120 for generating noise and a reference microphone (Ref) for measuring the reference value of the noise output from the speaker 120, the speaker on the other side of the soundproof wall 200 In order to measure the noise level in the state in which the noise output through the 120 passes over the diffraction sound reduction device 100 on the top of the soundproof wall 200, a plurality of microphones CH1 to CH7 are installed with a height difference. In this case, experiment in an anechoic chamber to minimize the reflection of sound and external noise.

In this case, the performance improvement test results, which are designed by selecting a resonance frequency in consideration of the frequency range for reinforcing the soundproof wall as 700 Hz to 2500 Hz, can be obtained as shown in FIG. 9.

That is, FIG. 9 shows an additional total sum of the rear surface by adding the top diffraction sound reduction device 100 of the soundproof wall using the Helmholtz sound absorber having a variable function of the resonance frequency according to the present invention, compared to the case where only the soundproof wall 200 is present through the anechoic chamber test. Indicates noise reduction.

In other words, when the total noise reduction is represented by the 1/3 octave center frequency, a value corresponding to the frequency range of 31.5 Hz to 10000 Hz was calculated. Unlike conventional sound barriers, the total noise improvement in this frequency range corresponds to the lower part of the shaded sound field by providing a diffraction sound reduction device 100 at the top of the sound barrier using a Helmholtz sound absorber having a variable function of resonant frequency according to the present invention. It can be seen that a greater effect occurs at the higher measuring position than the measuring region.

In other words, it can be seen that the improvement effect is shown up to 5th channel and 6th channel, which are out of the line of sight, which cannot be effected by a normal upright soundproof wall. It can be seen that.

On the other hand, through the present invention it is possible to apply the diffraction sound reduction device 100 using the Helmholtz resonance principle using a multi-resonant frequency design for expanding the frequency range having an improvement effect. For example, a combination of various resonant frequency resonators such as 500 Hz, 630 Hz, 820 Hz, 1340 Hz, 1340 Hz, 2380 Hz, 1340 Hz, and the like can achieve a higher improvement effect in the area of about 2500 Hz to the maximum effect and the surrounding frequency range.

In another embodiment of the present invention, as shown in FIG. 10, the chamber 110 is divided into a plurality of space portions 112a by the partition wall 112 formed in a lattice pattern, each of the space portions 112a. An upper portion of the upper plate 114 formed at the upper portion of the upper plate 114 to cover the entire sliding member 115 is formed.

Here, the sliding member 115 has a second auxiliary through hole formed smaller in diameter than the first auxiliary through hole 115a and the through hole 114a having the same size as the through hole 114a formed in the upper plate 114. 115b) is formed sequentially.

Thus, the first auxiliary through hole (115a) formed in the sliding member 115 and the through hole (114a) of the upper plate 114 is located in communication, or by sliding the sliding member 115 to the second auxiliary through hole ( By placing 115b) and the through hole 114a in communication with each other, the size of the hole can be adjusted, so that the resonance frequency can be changed even without separately manufacturing the chamber 110.

In this case, the sliding member 115 may be installed below the upper plate 114 to be used.

In addition, as shown in FIG. 11 according to another embodiment of the present invention, a slide member 115 is formed on an upper portion of the upper plate 114 formed on the upper portion of the chamber 110, and the upper plate is formed on the slide member 115. The first auxiliary through hole 115a having the same size as the through hole 114a formed in the 114 is formed in two rows.

Here, among the first auxiliary through holes 115a formed by the second row, the first row 115c is formed to communicate with all the through holes 114a formed in the upper plate 114, and the second row 115d is the upper plate 114. Less than the number of through-holes (114a) formed in the.

Thus, by sliding the slide member 115, the hole is formed in the same manner as the number of through holes 114a of the upper plate 114, but in communication with the second row (115d) to communicate with the first row (115c). In this case, some of the through holes 114a formed in the upper plate 114a are blocked by the slide member 115 to form a smaller number of holes than the number of the through holes 114a formed in the upper plate 114. Even if the chamber 110 is not manufactured separately, the resonance frequency can be changed.

In this case, the slide member 115 may be installed and used under the upper plate 114.

On the other hand, as another embodiment of the present invention as shown in Figures 12 to 14, the slide member 115 is formed on the upper portion of the upper plate 114 installed on the upper portion of the chamber 110, the slide member ( The first auxiliary through hole 115a having the same size as the through hole 114a formed in the upper plate 114 is formed in the 115.

Here, the side portion of the chamber 110 is provided with an adjusting unit 300 for controlling the opening degree of the through-hole (114a) by controlling the movement of the slide member 115.

At this time, the adjustment unit 300 is a rack gear 240 is installed on the side of the slide member 115, the pinion gear 350 and the pinion gear 350 is installed on the side of the chamber 110 The motor 330 is installed at one side of the motor 110 and the chamber 110 to detect the frequency of noise and measure the frequency, and the motor 330 according to the frequency detected by the frequency analyzer 310. Control unit 320 for controlling the rotation of the).

Thus, the frequency analyzer 310 detects noise generated when the railroad car approaches the soundproof wall, and when the detected noise level is higher than or equal to a predetermined level, the frequency analyzer 310 slides according to the frequency detected by the frequency analyzer 310. By controlling the movement of the member 115, the opening degree of the through hole 114a is adjusted to have a resonance frequency with respect to noise.

Therefore, the resonance frequency can be changed even if the chambers 110 having various resonance frequencies are not manufactured, thereby reducing the noise by appropriately adjusting the resonance frequency according to various frequencies of the noise.

Meanwhile, as another embodiment of the present invention, as shown in FIG. 15, a chamber 110 ′ is installed at an upper end of the soundproof wall 200 to reduce noise generated by a railway vehicle traveling on a track. The unit cells constituting the chamber 110 'are formed in different heights to form one chamber 110'.

Thus, by forming different resonant frequencies for each unit cell having different heights, it is possible to reduce noise of various frequencies at one time by using one chamber 110 '.

Here, the unit cell may be formed in a rectangular cylinder shape or a cylindrical shape. When the rectangular unit cell is formed in a rectangular cylinder shape, the unit cells are installed to be in close contact with each other without a space, and each unit cell is formed in a cylindrical shape. In this case, a separate space is formed between each unit cell.

Therefore, when formed into a cylindrical shape, since the additional tubular space is configured, the effect of sound absorption may be increased depending on the frequency domain, and noise may be more easily reduced by adding another configuration to efficiently use the space. Will be.

And, as shown in FIG. 16 as another embodiment of the present invention, when installing the soundproof wall upper diffraction sound reduction device 100 using the Helmholtz sound absorber of the variable function of the resonance frequency on the top of the soundproof wall 200, According to the condition, the position can be adjusted to the whole, the rear part, or the center part, and the noise can be reduced more stably.

While the present invention has been described in connection with what is presently considered to be preferred embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

100: diffraction sound reduction device 110,110 ': chamber
112: partition 112a: space part
114: top plate 114a: through hole
116: bottom plate 200: soundproof wall

Claims (13)

Through-holes are formed in the upper portion of the chamber in which a plurality of spaces are partitioned to be formed horizontally on the top of the soundproof wall is installed on one side of the track that the train moves,
The chamber includes a lower plate installed in a horizontal direction on an upper end of the soundproof wall, a partition wall forming a plurality of space portions on the upper portion of the lower plate, and integrally fixed to an upper portion of the partition wall to close the space portion, and the space portion on the surface thereof. The plurality of through holes are made of a top plate formed to maintain a constant interval so as to communicate,
A slide member is formed on the upper portion of the upper plate,
And a first auxiliary through hole having the same size as that of the through hole is formed in the slide member.
The method of claim 1,
A plurality of spaces formed in the chamber is formed independently by a partition wall, the resonance frequency is characterized in that the upper end of the chamber is in communication with the space portion is formed by the through-hole narrower than the space portion is formed Diffraction sound reduction device on the top of soundproof wall with function Helmholtz sound absorber.
delete The method of claim 1,
The partition wall is a diffraction sound reduction device on the top of the soundproof wall using the Helmholtz sound absorber of the variable function of the resonant frequency, characterized in that installed in the form of a lattice.
The method of claim 1,
The chamber is installed in the longitudinal direction of the soundproof wall and the sound diffraction sound reduction device on the top of the soundproof wall using a Helmholtz sound absorber of the variable function of the resonant frequency, characterized in that it has a predetermined width.
The method of claim 1,
The chamber is a diffraction sound reduction device on the top of the soundproof wall using a Helmholtz sound absorber of the variable function of the resonant frequency characterized in that the rectangular shape.
The method of claim 1,
And a second auxiliary through hole having a diameter smaller than that of the through hole is further formed in the slide member.
The method of claim 1,
The first auxiliary through hole is formed in two rows,
The first row is formed to correspond to the through hole formed in the top plate,
The second diffraction noise reduction device of the soundproof wall using the Helmholtz sound absorber of the variable function of the resonant frequency, characterized in that less than the number of through holes formed in the upper plate.
delete The method of claim 1,
The side of the chamber is characterized in that the control unit for controlling the movement of the slide member to adjust the opening degree of the through hole is provided with a Helmholtz sound absorber of the resonant frequency variable function of the soundproof wall upper diffraction sound reduction device.
The method of claim 10,
The control unit includes:
A rack gear installed at the side of the slide member;
A pinion gear installed at the side of the chamber,
A motor in which the pinion gear is installed;
A frequency analyzer for detecting and measuring the frequency of noise;
And a control unit for controlling the rotation of the motor according to the frequency detected by the frequency analyzer.

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