KR20120016702A - Hybrid Exhaust Silencer - Google Patents

Abstract

The present invention relates to a composite exhaust gas silencer. The silencer of the present invention includes: an inner cell 110 providing a main passage through which exhaust gas passes; An outer cell 120 surrounding the inner cell 110 while securing a predetermined space radially outwardly; A first sound absorbing silencer 101 formed by filling the first sound absorbing material S1 by a predetermined length of a space between the inner cell and the outer cell; Second sound absorbing noise in which a second sound absorbing material layer S2 is formed in a space between the inner and outer cells of the remaining length of the silencer except for the first sound absorbing silencer at a predetermined thickness radially outward from the outer circumference of the inner cell. Part 102; A plurality of through holes formed in the inner cell so as to communicate with the first sound absorbing material layer or the second sound absorbing material layer; And a resonance cylinder 130 secured in a space between the outer circumference of the second sound absorbing material layer and the outer cell by forming the second sound absorbing material layer, and radially penetrating from the inner cell to the resonance cylinder through the second sound absorbing material layer. It is made of an opening neck 140. The present invention utilizes the radially inner portion of the resonance silencer as the second sound-absorbing silencer, and the second sound-absorbing silencer also serves as the opening neck of the resonance silencer, so that the resonance silencer and the second sound-absorbing silencer are within the same length. Coexistence forms a sound-absorbing silencer over the entire length of the muffler, which reduces the overall length of the muffler, improves design freedom for securing space and placement of peripherals, and reduces material cost burden.

Description

Hybrid Exhaust Silencer {HYBRID EXHAUST GAS SILENCER}

The present invention relates to a composite exhaust gas silencer, and more particularly, to combine a resonator-type silencer and a sound-absorbing silencer in order to obtain a good noise effect in the entire frequency range, while combining a compact exhaust in a short length Relates to a gas silencer.

Examples of a silencer combining a resonance type silencer and a sound absorber type are disclosed in Korean Patent Laid-Open Publication No. 10-2008-0058020, filed by the present inventor, and the like, in which a similar form is attached to the accompanying drawings. 1 is shown.

The silencer illustrated in FIG. 1 is a resonance type silencer that shows a better noise performance in a low frequency band to compensate for the low noise effect of the low frequency band, which is lacking in a conventional silencer by a porous sound absorbing material. Combination, to obtain a good noise effect in a wide frequency band.

The silencer 10 illustrated in FIG. 1 is a form in which the sound absorber core portion in the middle of the silencer illustrated in FIG. 2 is disclosed.

As shown in FIG. 1, the silencer 10 includes an inner cell 20 providing a main passage through which exhaust gas passes, and an outer cell 30 forming a constant space outside the inner cell 20. Equipped. Between the inner cell 20 and the outer cell 30, a sound absorbing noise portion 40 of a predetermined length L1 and a resonance silencer 50 of a predetermined length L2 are provided.

Sound absorbing silencer 40 is filled with a porous sound-absorbing material (S) between the inner cell 20 and the outer cell 30, the inner cell 20 has a large number of through holes 21, such as a so-called 'porous plate'. Formed form. This exhausts the noise energy while the exhaust gas passing through the inner cell 20 contacts the sound absorbing material S through the through hole 21.

The resonance silencer 50 uses the physical structure of the Helmholtz resonator, and is formed by the partition 60 or the virtual partition 61 in the longitudinal direction between the inner cell 20 and the outer cell 30. The opening neck 22 is partitioned into the space 62 having a predetermined volume, and the inner cell 20 communicates with each of the space 62 partitioned. As a result, the noise energy is exhausted in the course of the exhaust gas passing through the inner cell 20 to the space 62 through the opening neck 22.

Such a silencer 10 is a form in which the sound absorbing material core part of the center is excluded from the silencer shown in FIG. 2 of the aforementioned publication, in order to obtain a sound effect of the same or better low frequency band while removing the sound absorbing material core part. The length L1 of the sound absorbing silencer 40 must be secured between the inner cell 20 and the outer cell 30 to have a surface area equal to or larger than that of the central sound absorbing material core part. Therefore, in order to obtain the noise effect of the high frequency band while obtaining the noise effect of the low frequency band which is the same as or better than before, the resonance noise unit 50 of the resonance noise unit 50 is secured while the length L1 of the sound absorbing noise unit 40 is secured. Since there is no choice but to add more length L1, the noise effect is improved but the silencer becomes too large. For example, in a large diesel engine for ships or industrial facilities, if the conventional sound absorbing silencer is about 3 to 4 meters in length, an additional length of about 2 to 3 meters is required to give the function of the resonance silencer. need. In this case, the total length (L1 + L2) of the muffler reaches up to 6 meters or more, thereby reducing the freedom of design for securing the space and arranging the peripherals and increasing the material cost burden.

The present invention was developed to solve the above problems, and an object of the present invention is to effectively arrange a sound absorbing noise unit and a resonance noise unit so as to obtain a good noise reduction effect in the entire frequency range and to implement it compactly in a short length. To provide a combined exhaust gas silencer.

In order to achieve the above object, the composite exhaust gas silencer according to the present invention, the internal cell providing a main passage through which the exhaust gas passes; An outer cell surrounding while securing a constant space radially outward of the inner cell; A first sound absorbing silencer formed by filling the first sound absorbing material by a predetermined length of the space between the inner cell and the outer cell; A second sound absorbing silencer forming a second sound absorbing material layer at a predetermined thickness radially outward from an outer circumference of the inner cell in a space between an inner cell and an outer cell of the remaining length portion of the silencer except for the first sound absorbing silencer; A plurality of through holes formed in the inner cell so as to communicate with the first sound absorbing material layer or the second sound absorbing material layer; And a resonance hole secured in the space between the outer circumference of the second sound absorbing material layer and the outer cell by the formation of the second sound absorbing material layer, and an opening neck portion radially penetrating from the inner cell to the resonance hole through the second sound absorbing material layer. It includes a resonance noise portion consisting of.

The resonance cylinder is partitioned into a plurality of unit chambers in the longitudinal direction by a plurality of partition walls or virtual partition walls, and each of the divided unit chambers has a plurality of opening necks formed therethrough from the inner cell to the unit chamber via the second sound absorbing material layer. Can be done.

In addition, the second sound absorbing silencer and the resonance silencer, the intermediate cell between the inner cell and the outer cell of the remaining length portion of the silencer except the first sound-absorbing silencer, and the intermediate cell between the intermediate cell and the inner cell The second sound absorbing silencer is formed by filling the second sound absorbing material, and the space between the intermediate cell and the outer cell can be made into a resonance cylinder.

In accordance with another aspect of the present invention, a hybrid exhaust gas silencer includes: an inner cell providing a main passage through which exhaust gas passes; An outer cell surrounding while securing a constant space radially outward of the inner cell; Sound absorption comprising a sound absorbing material layer formed in a space between the inner cell and the outer cell with a predetermined thickness radially outward from the outer periphery of the inner cell, and a plurality of through-holes formed in the inner cell to communicate with the sound absorbing material layer Silencer; And a resonance cylinder formed by a resonance cylinder secured by a space between the outer circumference of the sound absorbing material layer and the outer cell, and an opening neck portion radially penetrating from the inner cell to the resonance cylinder through the sound absorbing material layer.

In this case, the resonance cylinder is partitioned into a plurality of unit chambers in the longitudinal direction by a plurality of partition walls or virtual partition walls, so that a plurality of opening necks penetrate from the inner cell to the unit chamber through the sound absorbing material layer for each partitioned unit chamber. Can be configured.

Here, the sound absorbing silencer and the resonance silencer, the middle cell between the inner cell and the outer cell, the sound absorbing silencer is made by filling the sound absorbing material between the intermediate cell and the inner cell, the intermediate cell The space between the outer cell and the outer cell may be configured to form the resonance cylinder.

The composite exhaust gas silencer of the present invention utilizes the radially inner portion of the resonant silencer as the second sound absorbing silencer, and makes the second sound absorbing silencer also function as the opening neck of the resonant silencer, thereby resonating the resonant silencer and the second sound absorption. The silencer coexists within the same length to form a sound absorbing silencer over the entire length of the silencer.

Therefore, according to the present invention, even if the total length of the muffler is secured only by the length of the sound-absorbing noise portion of the conventional muffler, it is possible to achieve the noise effect comparable to the conventional, according to the design for securing the space and arrangement of peripheral devices The degree of freedom is increased and the material cost burden is reduced.

1 is a cross-sectional view schematically showing an example of a conventional exhaust gas silencer.
2 is a cross-sectional view showing a hybrid exhaust gas silencer according to a first embodiment of the present invention.
3 is a sectional view taken along the line AA in Fig.
FIG. 4 is an enlarged view of the opening neck portion of FIG. 2. FIG.
5 is a cross-sectional view showing a hybrid exhaust gas silencer according to a second embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

(Example 1)

2 to 4 show a composite exhaust gas silencer according to the first embodiment of the present invention. Specifically, FIG. 2 is a cross-sectional view, FIG. 3 is a cross-sectional view taken along the line A-A of FIG. 2, and FIG. 4 is an enlarged view showing a detail of the opening neck part 140 of FIG.

First, as shown in FIGS. 2 and 3, the hybrid exhaust gas silencer 100 according to the present invention includes an inner cell 110 and a radius of the inner cell 110 that provide a main passage through which the exhaust gas passes. The first and second sound-absorbing noise units having a unique and effective shape by effectively partitioning the space between the outer cell 120 and the inner cell 110 and the outer cell 120 while securing a constant space in the outer direction. 101 and 102 and the resonance silencer 103 are provided.

Specifically, the first sound absorption silencer 101 is set by a predetermined length (for example, about 1/2, about 3/5, about 5/2, etc.) of the total length L3 of the silencer 100, The first sound absorbing material S1 is filled in the space between the inner cell 110 and the outer cell 120 of the portion.

The second sound absorbing silencer 102 is formed in the space between the inner cell 110 and the outer cell 120 of the remaining length of the silencer except for the first sound absorbing silencer 101 described above. In particular, the second sound absorbing silencer 102 is formed (filled) with the second sound absorbing material layer S2 formed at a predetermined thickness 'outward' from the outer circumference of the inner cell 110. Therefore, a space is formed between the second sound absorbing material layer S2 and the outer cell 120. This space becomes the resonance cylinder 130 of the resonance silencer 103.

In addition, a plurality of through-holes 111 communicating with the first sound absorbing material layer S2 and the second sound absorbing material layer S2 are formed in the inner cell 110 for the first sound absorbing silencer 101 and the second sound absorbing silencer 102. ) Is formed. Exhaust gas passing through the inner cell 110 contacts or permeates the sound absorbing materials S1 and S2 through the plurality of through holes 111.

As described above, the resonance cylinder 130 of the resonance silencer 103 is secured by the space between the outer circumference of the outer circumference of the second sound absorbing material layer S2 and the outer cell 120 by forming the second sound absorbing material layer S2. do. The opening neck 140 is formed to penetrate radially from the inner cell 110 to the resonance cylinder 130 via the second sound absorbing material layer S2. Therefore, the exhaust gas passing through the inner cell 110 is in communication with the resonance cylinder 130 through the opening throat 140.

In the present embodiment, the resonance cylinder 130 may be partitioned into the plurality of unit chambers 130a in the longitudinal direction by the plurality of partitions 131 or the virtual partitions 132. At this time, the opening neck 140 is formed for each divided unit chamber 130a.

In the present embodiment, the boundary between the second sound absorbing silencer 102 and the resonance silencer 103 can be partitioned by the intermediate cell 150. The intermediate cell 150 is disposed between the inner cell 110 and the outer cell 120. By filling the second sound absorbing material S2 between the intermediate cell 150 and the inner cell 110, the above-described second sound absorbing silencer 102 is formed, and between the intermediate cell 150 and the outer cell 120. The resonance cylinder 130 is partitioned by space.

In this case, the opening neck 140 may be made as shown in FIG. That is, by inserting the hollow tube 160 penetrating the inner cell 110, the second sound absorbing material (S2) and the intermediate cell 150, the hollow tube 160 serves as the opening neck of the resonance cylinder 130 will be.

The composite exhaust gas silencer 100 of the present invention utilizes the radially inner portion of the resonance silencer 103 as the second sound absorbing silencer 102. Therefore, the resonance silencer 103 and the second sound absorbing silencer 102 coexist in the same length, and the sound absorbing silencers 101 and 102 are formed over the entire length of the silencer 100.

Even if the total length L3 of the silencer 100 of the present invention is the same as the length L1 (see FIG. 1) of the sound-absorbing silencer 40 (see FIG. 1) of the conventional silencer (see FIG. 1), The inner surface area of the first sound absorbing silencer 101 and the second sound absorbing silencer 102 is equal to the inner surface area of the sound absorbing silencer 40 of the conventional silencer. Therefore, while ensuring the sound absorbing performance corresponding to the prior art, it is not necessary to increase the length of the silencer specifically for the resonance silencer 103.

For example, when comparing FIG. 1 and FIG. 2, the total length L1 + L2 of the silencer shown in FIG. 1 is about 6 meters, and the length L1 of the sound absorbing silencer 40 is about 3-4 meters. If the total length L3 of the silencer 100 according to the present invention is secured only by the length L1 of the conventional sound-absorbing silencer 40, the equivalent noise performance can be exhibited.

As described above, according to the present invention, the overall length of the silencer can be greatly reduced by the effective arrangement and division of the sound absorbing silencer and the resonant silencer. do.

(2nd Example)

In the accompanying drawings, a hybrid exhaust gas silencer according to a second embodiment of the present invention is shown. For ease of understanding, reference numerals of the respective components are given by adding 100 to the reference numerals of the components of the muffler 100 according to the first embodiment (FIGS. 1 to 4).

As shown in FIG. 5, the exhaust gas silencer 200 according to the present embodiment has a sound absorbing silencer 204 radially inward between the inner cell 210 and the outer cell 220 over the entire length of the silencer. ) And the resonance silencer 205 is disposed radially outward. That is, over the entire length of the silencer 200, the sound absorbing silencer 204 is a means for forming the opening neck portion of the resonance silencer 205 and serves as a sound absorbing silencer itself.

Specifically, as shown in FIG. 5, the sound absorption silencer 204 surrounds the inner cell 210 providing a main passage through which the exhaust gas passes, while securing a constant space radially outward of the inner cell 210. The sound absorbing material layer S3 and the inner cell 210 are formed to have a predetermined thickness radially outward from the outer circumference of the inner cell 210 in the space between the outer cell 220, the inner cell 210 and the outer cell 220. ), A plurality of through holes 211 formed to communicate with the sound absorbing material layer S3.

In addition, the resonance silencer 205 is a resonance cylinder 230 secured between the outer circumference of the sound absorbing material layer S3 and the outer cell 220, and the resonance tube 230 from the inner cell 210 via the sound absorbing material layer S3. It consists of an opening neck portion 240 that is radially penetrated to).

Similar to the first embodiment described above, the present embodiment can also be divided into the plurality of unit chambers 230a in the longitudinal direction by the plurality of partitions 231 or the virtual partitions 232. In addition, the opening neck part 240 is penetrated from the inner cell 210 to the unit chamber 230a via the sound absorbing material layer S3 for each divided unit chamber 230a.

In addition, the sound absorbing silencer 204 and the resonance silencer 205 may divide and partition the intermediate cell 250 between the inner cell 210 and the outer cell 220. In this case, the sound absorbing material S3 is filled between the intermediate cell 250 and the inner cell 210.

The hybrid exhaust gas silencer 200 according to the present embodiment has a structure in which the sound absorbing silencer 204 and the resonance silencer 205 coexist over the entire length of the silencer. It is possible to reduce noise and to have an equivalent noise effect.

100, 200: Silencer
101: first sound absorption silencer
102: second sound absorption unit
103, 205: resonance noise section
204: sound absorption
110, 210: inner cell
111 and 211
120, 220: outer cell
130, 230: Resonance tube
130a, 230a: unit chamber
131, 231: bulkhead
132, 232: virtual bulkhead
140, 240: opening neck
150, 250: intermediate cell

Claims (6)

An inner cell providing a main passage through which the exhaust gas passes;
An outer cell surrounding while securing a constant space radially outward of the inner cell;
A first sound absorbing silencer formed by filling the first sound absorbing material by a predetermined length of the space between the inner cell and the outer cell;
A second sound absorbing silencer forming a second sound absorbing material layer at a predetermined thickness radially outward from an outer circumference of the inner cell in a space between an inner cell and an outer cell of the remaining length portion of the silencer except for the first sound absorbing silencer;
A plurality of through holes formed in the inner cell so as to communicate with the first sound absorbing material layer or the second sound absorbing material layer; And
A resonance hole secured in the space between the outer periphery of the second sound absorbing material layer and the outer cell by the formation of the second sound absorbing material layer; and an opening neck portion radially penetrating from the inner cell to the resonance hole through the second sound absorbing material layer. Composite exhaust gas silencer comprising a resonance silencer made of. The method of claim 1,
The resonance cylinder is partitioned into a plurality of unit chambers in the longitudinal direction by a plurality of partition walls or virtual partition walls, and the plurality of opening necks penetrate through the second sound absorbing material layer from the inner cell to the unit chamber for each partitioned unit chamber. A composite exhaust silencer characterized by the above. The method of claim 1,
The second sound absorbing silencer and the resonance silencer dispose an intermediate cell between an inner cell and an outer cell of the remaining length portion of the silencer except for the first sound absorbing silencer, and the second cell between the intermediate cell and the inner cell. The second sound absorbing silencer is made by filling the sound absorbing material, and the space between the intermediate cell and the outer cell forms a resonance cylinder. An inner cell providing a main passage through which the exhaust gas passes;
An outer cell surrounding while securing a constant space radially outward of the inner cell;
Sound absorption comprising a sound absorbing material layer formed in a space between the inner cell and the outer cell with a predetermined thickness radially outward from the outer periphery of the inner cell, and a plurality of through-holes formed in the inner cell to communicate with the sound absorbing material layer Silencer; And
And a resonance cylinder formed of a resonance cylinder secured by a space between the outer circumference of the sound absorbing material layer and the outer cell, and an opening neck formed to radially penetrate from the inner cell to the resonance cylinder through the sound absorbing material layer. Combined exhaust silencer. The method of claim 4, wherein
The resonance cylinder is partitioned into a plurality of unit chambers in the longitudinal direction by a plurality of partition walls or virtual partition walls, and a plurality of opening throats are formed through the sound absorbing material layer from the inner cell to the unit chambers for each partitioned unit chamber. Combined exhaust silencer. The method of claim 4, wherein
The sound-absorbing silencer and the resonance silencer are arranged in the middle cell between the inner cell and the outer cell, and the sound-absorbing silencer is made by filling a sound absorbing material between the middle cell and the inner cell, and the intermediate cell and the outside The exhaust gas silencer, characterized in that the space between the cells make up the resonance cylinder.

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