EP0316640A1 - Low-frequency silencer - Google Patents

Abstract

In order to silence low-frequency sound waves, which can arise in components of turbo-engines, the silencer proposed here consists of an inlet tube (1) through (3) and around (4) which a medium flows. At the end of the inlet tube (1) in the outlet flow direction this tube has a row of silencing holes (2), distributed around the circumference, through which the medium (4) flowing around the inlet tube (1) flows into the interior of the inlet tube (1). The effective length L of the inlet tube (1), the cross-sectional area A of the inlet tube (1), and the overall cross-sectional area B of the silencing holes (2) form the geometrical parameters for calculating optimum silencing of the low-frequency sound waves. …<IMAGE>…

Description

The present invention relates to a silencer for damping low-frequency sound waves.

STATE OF THE ART

For numerous turbomachines, or components of turbomachines (combustion chambers, regulating valves, etc.), the impedance properties of flow feeders play an important role with regard to their acoustic stability properties, particularly with regard to low-frequency acoustic natural vibrations of such components. Sound waves that are emitted into feed divisions should, if possible, not be reflected, or at most only to a small extent. Otherwise, the reflected waves can help to ignite strong resonant vibrations. Effective damping of high-frequency sound waves can usually be achieved with simple technical precautions (e.g. use of a classic silencer: perforated plate over a small closed cavity). The attenuation of low-frequency sound waves, however, is much more difficult. A common technique is to couple large Helmholz resonators to the supply lines. The disadvantage of such The measure, however, is that such damping resonators take up a lot of space and are correspondingly complex and expensive. In addition, the frequency bandwidth of the damping is quite small, and the damping effect is weak even in the optimal frequency range.

OBJECT OF THE INVENTION

The invention seeks to remedy this. The invention, as characterized in the claims, is based on the object of achieving the attenuation of a wide frequency band in the smallest space in a silencer of the type mentioned.

The main advantage of the invention can be seen in the fact that waves of this type can also be strongly damped, the wavelength of which is substantially greater than four times the length of the feed pipe between the pipe inlet and the row of holes.

Furthermore, while in normal mufflers, such as those found in the exhaust pipe of internal combustion engines as Helmholz resonators, the absorption is quadratic in the sound wave amplitude, the holes provided there not being flowed through in the vibration-free case, the absorption in the object according to the invention is proportional to the amplitude , in the vibration-free case, the damping holes are flowed through.

This means that the subject matter according to the invention acts as an absorber for the frequency designed in each case, within an attenuation bandwidth of approximately 1 octave.

Another advantage of the invention is that the silencer can be integrated into all possible turbomachines at any time with only minor modifications due to its simple and space-saving shape, also as a retrofit measure.

Advantageous and expedient developments of the task solution according to the invention are characterized in the dependent claims.

Exemplary embodiments of the invention are explained below with reference to the drawing. All elements not necessary for the immediate understanding of the invention have been omitted.

BRIEF DESCRIPTION OF THE INVENTION

• Fig. 1 einen Schalldämpfer,
• Fig. 2 eine weitere Ausführung eines Schalldämpfers und
• Fig. 3 die graphische Erfassung der optimalen Dämpfungseigen­schaften.

It shows:

• 1 shows a silencer,
• Fig. 2 shows another embodiment of a silencer and
• Fig. 3 shows the graphic recording of the optimal damping properties.

DESCRIPTION OF THE EMBODIMENTS

wobei n die Anzahl der Oeffnungen und d_L deren Durchmesser bedeuten.As can be seen from FIG. 1, the muffler consists of a supply pipe 1 through which a medium flows 3 and around which it flows 4. After a length L from the pipe inlet, this has a row of damper bores 2 distributed over the circumference, through which part 4 of the supplied pipe Medium flows into the interior of the feed pipe 1 and collides there with the medium 3 flowing through the feed pipe. The medium 5 then leaves the feed pipe 1 and enters a turbomachine, not shown. The medium in question is intended to be a gas, in many cases it will be air. The wall 6 is intended to symbolize that the feed pipe 1 forming the muffler can communicate directly with the combustion chamber 7 of the turbomachine, not shown. Of course, the feed pipe 1 can be placed on a premixing element. The type of combustion chamber determines whether a change in cross-section, for example due to a jump in the borehole, is required at the transition between feed pipe 1 and the premixing element (not shown) together. For reasons of space, it also happens that the feed pipe 1 can be followed directly by a burner, which in turn is connected upstream of the combustion chamber. It is physically noticeable that the feed pipe 1 is only characterized by three geometrical sizes, namely by the cross-sectional area A of the feed pipe 1, by the effective length L of the feed pipe, which extends in the direction of flow from the pipe inlet to the center of the damper bores 2, and by the overall cross section B of all damping holes 2 on the bolt circle. Further parameters for the optimal design of a muffler are also the speed of the flow V through the damping bores 2 and the speed of sound c of the medium itself. In principle, the speed V also depends on the size of the individual damping bores 2. On the other hand, the dimensioning and number of damping bores 2 depend on the cross-sectional area A of the feed pipe 1. Mathematically, the total cross section B of the damping bores 2 with

where n is the number of openings and d _{L is} the diameter.

Since, in practice, the cross-sectional area A and the effective length L of the feed pipe 1 are predefined from technical dispositions, the total cross-sectional area B of all the damping bores 2 remains for the optimal design of the muffler. The number of damping bores 2 distributed over the circumference and their diameter depend on the size of the feed pipe 1. The optimization must take into account that the flow velocity V in the damping bores 2 and the sound velocity c of the medium still play a role as further parameters.

The sound power of the sound wave of frequency f scattered back by the damper is expressed as a percentage of the radiated power:

]^1/2      (3)
The total cross-sectional area B of the damping holes should be selected so that the parameter α reaches its optimal value α _OPTIMAL :

α _OPTIMAL = [1 +

] ^1/2 (3)

By inserting the value α _OPTIMAL thus obtained into equation (2), the percentage power of the wave reflected by the silencer is then calculated for the respective underlying case.

FIG. 2 shows a further embodiment variant of the muffler, in which the guidance of the air portion 4 to the damping bores 2 is guided through an annular opening 9, which extends over the entire length of the feed pipe 1. For this purpose, a second pipe 8 is provided concentrically with the feed pipe 1. The distance between the second tube 8 and the feed tube 1 depends on the determined amount of the air portion 4 and also on the desired speed of the flow V through the damping bores 2.

stellt die Phase dar, d.h. jene Länge des Schall­dämpfers, welche beim Wert 1 auf der Abszisse 10 die Ideallänge darstellt. die eine Ordinate 11 trägt die Leistung der vom Schalldämpfer reflektierten Welle in % auf, bezogen auf die einfallende Welle, d.h. auf die Welle, welche im Brennraum angefacht und in den Schalldämpfer eingestrahlt wird. Die andere Ordinate 12 stellt α_OPTIMAL dar. In diesem Wert ist, wie oben bereits dargelegt wurde, gewichtig die Gesamtquer­schnittsfläche B der Dämpfungsbohrungen 2 enthalten. Die Kurve 13 beschreibt die abfallende Leistung in % der vom Schalldämpfer reflektierten Welle in Abhängigkeit zu einer zunehmenden Phase (

). die andere Kurve 14 beschreibt den zunehmenden Wert von α_OPTIMAL bei abnehmender Phase (

). Gut ersichtlich ist in der Graphik, wie beim Idealwert 1 (Ideallänge) des Schalldämpfers die Leistung in % der vom Schalldämpfer reflek­tierten Welle Null beträgt, d.h. man hätte in einem solchen Fall eine vollständige Absorption erreicht.Fig. 3 shows a graphical representation, from the α _OPTIMAL and the associated percentage performance of the silencer reflected wave are readable. The abscissa 10 with the term

represents the phase, ie the length of the muffler, which represents the ideal length for the value 1 on the abscissa 10. one ordinate 11 plots the power of the wave reflected by the muffler in%, based on the incident wave, ie on the wave which is fanned in the combustion chamber and radiated into the muffler. The other ordinate 12 represents α _OPTIMAL . As already explained above, this value contains the total cross-sectional area B of the damping bores 2 as a weight. Curve 13 describes the falling power in% of the wave reflected by the muffler as a function of an increasing phase (

). the other curve 14 describes the increasing value of α _OPTIMAL with decreasing phase (

). The graph clearly shows how the ideal value 1 (ideal length) of the muffler means that the power in% of the wave reflected by the muffler is zero, ie complete absorption would have been achieved in such a case.

In practice, however, it is often the case, particularly when the silencer is retrofitted, that a reduced phase must be selected. If the installation conditions are such that, for example, only 50% of the theoretical ideal length of the silencer can be selected, this corresponds to an α _OPTIMAL of approx. 1.40 (vertical interface with curve 14). If these values are used in formula (2a), the total cross-sectional area B of the damping bores 2 can be calculated for a given cross-sectional area A of the feed pipe 1. The other interface with curve 14 gives the percentage power of the wave reflected by the silencer; in our case this corresponds to approx. 19%, which is still an almost complete absorption. As an introduction to the use of the graphic according to FIG. 3, the assumed example is included in the graphic in the form of dashed lines.

Claims (3)

1. Muffler for damping low-frequency sound waves, characterized in that the muffler consists of a feed pipe (1) through which a medium flows (3) and around which (4), which from the inlet pipe inlet is distributed over the circumference after a length (L) in the outflow direction Row of damping bores (2), via which the medium (4) flowing around the feed pipe (1) flows into the inside of the feed pipe (1). 2. Silencer according to claim 1, characterized in that the power of the reflected wave from the silencer, based on the incident wave, expressed in%:

meaning that

A = cross-sectional area of the feed pipe (1)
B = total cross-sectional area of the damping holes (2)
c = speed of sound of the medium (3)
f = frequency of the sound wave
L = effective length of the feed pipe (1) from the pipe entry to the bolt circle
V = velocity of the flow through the damping holes (2).
3. Silencer according to claim 1, characterized in that α _OPTIMAL is determined as follows:

α _OPTIMAL = [(1 +

)] ^1/2 ,
in which

is.

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