DE2534556B2 - Silencers for gas flows - Google Patents

Description

The invention relates to a multi-stage silencer for sound attenuation in gas flows, consisting from a double-walled housing, open on the output side, of circular cross-section with a Entrance stage with an inlet pipe closed at the inner end and perforated in the side wall, the extends coaxially over part of the length of the entrance step, and with the inside perforated Double wall of the housing enclosed, sound-absorbing material, with one in the entrance stage porous coarse material and otherwise strong sound-absorbing material is present.

A well-known multi-stage silencer of this type (US-PS 37 76 365) is made of a framework construction constructed which houses a series of coaxially arranged, annular sound attenuation packs. The double-walled sound-absorbing packings have perforated walls, between which sound-absorbing Material is arranged. In the entry level is only a muffler pack present; this forms the outer wall of the silencer. The one from the Inlet pipe exiting gas flow is perpendicular to the

hl) directed sound absorption packing, which is filled with a porous coarse material, which is temperature-resistant and not irreversibly compressible, among other things, and which prevents sound radiation caused by vibrations of the housing. The other soundproofing packings are filled with spin-like, strongly sound-absorbing material such as glass fibers and are arranged parallel to the gas flow passing through the soundproofing device

The invention assumes that a particularly favorable sound absorption is achieved when the Gas flow in all stages is directed perpendicular to the sound insulation packings, but this requires that the sound-absorbing material is pressure shock resistant or the gas flow acting is free from pressure surges Strongly sound-absorbing material in the steps following the entrance steps is namely under The effect of pressure surges is irreversibly compressed and then loses a significant part of it sound absorbing effect. For the desired more favorable arrangement of the sound absorption packings is e «: therefore expedient, not only in the entry level the vibration excitation of the housing, but also the pressure surges contained in the gas flow suppress. This is only possible to a limited extent with the known silencer because the one used there Packing is made of a relatively brittle material that breaks under the action of pressure surges and thereby loses at least part of its effectiveness.

There are also known essentially single-stage silencers in which the gas flows perpendicular to Packings made of strongly sound-absorbing material are directed and the-thus directly disadvantageous Effect of pressure surges are exposed (US-PS 19 27 213; 20 65 343; 25 23 260; 37 10 891). At a Another known, multi-stage silencer (CUPS 4 52 997) is the sound attenuation alone aimed at the multiple diversion of the gas flow and on the additional sound absorption and the The vibration excitation of the housing is not suppressed by sound-absorbing packings

The object of the invention is to provide a multi-stage silencer of the aforementioned type create a high level of sound attenuation even with strongly pulsating gas flows over long operating times is achieved.

According to the invention, this object is achieved in that the housing is transverse to the general direction of flow of the gas divided into several chambers according to the number of stages of the silencer by partition walls with a central opening and edge flange is and the partition walls and the housing with the interposition of vibration-damping, elastic Elements are connected to each other; that each partition wall with a closed at the inner end and is provided in the side wall perforated inlet pipe which extends coaxially over part of the length of the associated chamber extends; and that the double wall of the entrance stage has a filling made of pressure shock resistant Has metal chips and is provided on the outside with a jacket made of sound-absorbing material.

The silencer according to the invention enables a particular for the entire sound absorption favorable design of the individual stages, with the gas flows in each stage perpendicular to the soundproofing packings are directed. High noise attenuation is achieved even over long operating times, because the pressure surges are already in the unity level

be suppressed to a sufficient extent and a multiple deflection of the gas flow with the sound absorption is combined in the sound-absorbing packs. A sound propagation through the housing becomes by the vibration-damping connection between the housing parts that form the steps effectively prevented To prevent sound from being radiated through the housing, it is sufficient in the To provide a sound-absorbing outer jacket at the entrance level.

Advantageously amounts to in the various Levels of the silencer according to the invention, the radial distance between the circular holes provided side wall of the inlet pipe and the inside perforated double wall the four to Twenty times the diameter of the holes in the side wall of the inlet tube. With one of these Distance is ensured that the exiting from the inlet pipe, individual gas streams deep enough into the penetrate sound-absorbing or sound-absorbing packing, but on the other hand not with excessive pressure on the respective pack.

The silencer according to the invention can also be shaped like a truncated cone, with the entrance step at the end with the smaller diameter is arranged

Embodiments of the invention are shown in the figures and are described below! explained and described in detail with reference to the reference numerals. It shows

Fig. 1 is a side view of the silencer according to the invention;

Fi k 2 is a longitudinal section through a silencer according to Fig. 1;

3 shows an enlarged detailed view of a stage in the mode of action is indicated;

3A and 3B detailed views of the openings in the inner jacket or manifold of the silencer according to the invention;

Fig. 4 and 5 detailed sections through two trainings a vibration-isolating connection between adjacent stages of the silencer according to the invention, where F i g. 4 refer to the silencer according to FIG. 1 and 2 refers;

F i g. 6 in a partially broken away side view an extension piece for the invention Silencer;

F i g. 7 is a side view of another embodiment of the silencer according to the invention.

The in F i g. 1 to 4 shown silencer consists of two stages, each of which has a cylindrical housing part 1 or 2, the entrance being closed off by an inlet part 3. In the inlet part 3 is an inlet pipe 4 is welded in, which carries a common connecting flange 5. The sides of the inlet pipe 4 are pierced and the hole pattern is shown in full size in FIG. 3B. An orifice plate 6 with an inlet opening 7 rests against the outer surface of the flange 5.

The adjacent ends of the housing parts 1 and 2 carry flanges 8 and 9, between which one Partition wall 10 with a central opening 11 and an edge flange 12 is attached. Between the edge flange 12 and the flanges 8 and 9 are inserted elastic, vibration-damping elements 13; the Connection is made by bolts 14. The elastic elements 13 prevent the transmission of vibrations between the housing parts via the connection point.

On the housing parts 1 and 2 are cylindrical

Inner jackets 15, 16 attached by rings 17 in the Are kept at a distance from each other. The inner jackets 15, 16 are perforated; F i g. 3A shows the hole pattern of FIG Full size inner coats.

In the central opening 11 of the partition wall 10, another inlet pipe 18 of the same type is attached
The housing part 1 of the inlet part is of a

ίο Outer jacket 21 made of sound-absorbing material such as Encapsulated lead or asbestos and can also have a sheet metal jacket. The inlet part 3 can continue be provided on the inside with a perforated inner jacket 19 on the input side; the one thus formed

The space in between is covered with sound-absorbing material 20, filled, e.g. B. a packing made of copper or steel fibers.

The silencer shown in the figures is arranged at the end of a gas flow line and

> (i the inner jacket 16 and the housing part 2 are on Exit 22 open to the atmosphere. The muffler can also with its ends in a Gas flow line to be installed.

The one entering the inlet pipe 4 of the first stage

y. Gas flow varies widely between a relatively balanced flow and a very strongly pulsating flow. Since the downstream end of the inlet pipe 4 is closed, the gas flow through the holes in the inlet pipe 4 is divided into radial partial flows

split in by a multitude of individual nozzle openings are directed to the inner jacket 15. The space 23 surrounding the inlet pipe 4 is with mechanically resistant material filled, e.g. B. with metal turnings or copper grains, which

ΐϊ have other connected pores. As a result, the Gap 23 for absorption of sound originating from upstream sound sources from the Gas flow at. Its main effect, however, is to reduce the pressure surges from the inlet pipe 4

to be absorbed and attenuated in exiting jet streams. The sound absorption, which is desired per se, is achieved by the material contained in the space 23 therefore partly given up for the fact that the material against decay under the action of the gases

ιό is resistant, because these gases occur with high Speed through the holes in the inner jacket 15 into the pores within the space 23. The other one Space 24 in the entrance stage of the muffler downstream of the inlet pipe 4 is also preferred

, ο with a mechanically resistant, sound-absorbing Material filled. The sound energy is therefore in the first stage both from that in the interstices 23 and 24 contained material, as well as taken up by the sound-absorbing material 20.

· -, ■ -, In the entrance stage of the silencer, the gas flow is thus compensated to a considerable extent by the action on the shock and sound-absorbing material.
In the second stage of the muffler will be

ho remaining pressure waves attenuated further; the after The sound energy still contained in the gas stream passes through the first stage in the second stage absorbed. The mode of action in the second stage is similar to the first stage, but it predominates

ι ,. Sound absorption with further equalization of the gas flow, so that the gas stream exits into the atmosphere with a minimal sonic shock. the Sound attenuation takes place here in the space 25

thanks to highly absorbent material such as pressed hair felt or glass fibers. Preferably the holes in the inlet tube 18 are somewhat smaller and the inlet tube 18 is somewhat longer than the inlet tube 4 of the first stage. In this way a larger number of smaller ^r > beam currents is obtained. The inlet pipe 18 also effects a further equalization of the flow in the second stage; however, the main effect in the second stage is the absorption of the sound waves propagating in the gas flow. The area of sound-absorbing material exposed to the gas flow extends considerably beyond the closed downstream end of the inlet pipe 18 and thus causes a continued absorption of sound energy to the extent that the gas flow to the outlet into the atmosphere at a fairly low and constant speed compressed by the open, downstream end of the muffler. As a result, both sound generated upstream of the muffler and sound generated within the muffler from the gas flow are absorbed to such an extent that the sound level at the muffler outlet is reduced to a sufficient extent.

The above-described silencer for gas flows is designed in such a way that it absorbs sound energy from upstream sound sources as far as possible, and the gas flow is compensated so that only sufficiently little sound occurs at or outside the silencer outlet . But it must also be designed so that no sound is generated within the silencer itself. The low-frequency flow noise that usually occurs when a gas flow at relatively high velocity enters an extensive space in J5, such as when a gas flow exits an inlet duct into a relatively large silencer chamber, is avoided in the silencer described here. The inlet stream is split into a plurality of jet streams 26 * '> (FIG. 3) and the shock absorbing material is positioned beyond the cores of the jet streams shown at 27 in the enlarged detail view of FIG. Optimal is a distance between the inlet pipe 4 and the - ^1Γ > perforated inner jacket 15, which is four to twenty times the diameter of the holes in the distributor pipe. In such a design, damage to the shock absorbing material is avoided "high by the pressure prevailing in the cores of the jet flows ^r> speeds, and the gases are admitted without generating a low frequency noise and continued. This distance can also be somewhat smaller or be greater, however, the life of the shock absorbing material or the acoustic effectiveness of the muffler will then be impaired

Silencers must be designed for a certain maximum flow. For this purpose, a valve limiting the flow rate can be arranged in the line leading to the muffler, but secondary noises can then still arise downstream of the valve. This can be prevented by a mounted at the entrance of the inlet pipe 4 Mündungspiatte 6, wherein the surface formed by the total number of *> s holes in the side wall of the intake pipe 4 is in a certain proportion to the size of the opening 7 and is generally about three times as large is like its mouth surface. The holes in the inlet tube 18 of the second stage may form an area of approximately the same size for best results, since the gas flow entering the inlet tube 18 is much more uniform.

With a silencer made up of only two stages, the Radiation of sound to the atmosphere through the vibration-damping outer jacket described above 21 on the housing part 1 prevented. The transmission of vibrations of the housing part 1 of the first Stage on the housing part 2 of the second stage is in large part due to those described above elastic elements 13 prevented in the connecting parts, and to a further part in that the More uniform flow of the gas stream into and through the second stage does not normally result in a more disruptive one Vibration of the housing leads.

Another embodiment of the vibration-damping connection is shown in FIG. 5 shown therein overlap the end members la and 2a of the two housing parts and are interposed with one elastic body 13a attached to each other

From a cost point of view and from the point of view of efficiency, the silencers are generally constructed from cylindrical housing parts However, in a further embodiment shown in FIG. 1, the housing can also be conical be, the arrangements according to F i g. 1 to 4 can be adopted ir corresponding adjustment.

The requirements for sound absorption are increasing over time to reduce noise pollution greater. It is therefore to be expected that currently acceptable and permissible sound levels in the future will be too high be considered. In view of this development, the two-stage silencer described above is i designed so that one or more additional steps can be added to it. According to Fig. 6 eir Connecting flange 28 is provided to which an «extension step 29 with a housing 30 with a Layer of sound-absorbing material 31 and an inlet pipe 32 by means of a connecting element " can be set. If necessary, further intermediate stages can be provided at a later point in time can be used.

In the case of the FIG. 6 silencer shown is zui further lowering of the sound level in the gas tron sound-absorbing material 33 between a closed inner tube 34 and a perforated outer tube 35 of an extension of the inlet tube 3; ai ordered. The gas flow passes through the ring-shaped flow path with the sound-absorbing layer through which an intensive sound absorptiot is caused.

The above-described silencer has a particularly wide range of applications. True it mainly and especially for sound dampening and (to compensate for a strong impact If the current is suitable, it can also be effective in certain cases are used in which pressure reductions play a role in the generation of sound, as in de Noiseless release of pressurized steam to the surrounding atmosphere.

For this purpose 3 sheets of drawings

Claims (3)

Patent claims: 1. Multi-stage silencer for sound attenuation in gas streams, consisting of a double-walled housing with a circular cross-section, open on the outlet side, with an inlet stage with an inlet pipe closed at the inner end and perforated in the side wall, which extends coaxially over part of the length of the inlet stage, and with in the inside perforated double wall of the housing enclosed, sound-absorbing material, a porous coarse material and otherwise strongly sound-absorbing material is present in the entrance stage, characterized in that the housing (1, is 2) transversely to the general direction of flow of the gas through partition walls (10) Central opening (11) and edge flange (12) is divided into several chambers according to the number of stages of the silencer and the partition walls (10) and the housing (I, 2) are connected to one another with the interposition of vibration-damping, elastic elements (13, \ 3a); that each partition wall (10) is provided with an inlet tube (4, 18, 32 ) which is closed at the inner end and perforated in the side wall and which extends coaxially over part of the length of the associated chamber; and that the double wall of the entrance stage has a filling of pressure shock-resistant metal chips and is provided on the outside with a jacket (21) made of sound-absorbing material. 2. Silencer according to claim 1, characterized in that the radial distance between the side wall provided with circular holes of the inlet pipe (4, 18,32) and the inside »perforated double wall is four to twenty times the diameter of the holes in the side wall of the inlet pipe . 3. Silencer according to claim 1 or 2, characterized in that the housing (1,2) truncated cone · «> is shaped like and the input stage is arranged at the end with the smaller diameter.