DE739460C - Sound absorption in lines with a smooth passage to which resonators of different natural frequencies are connected - Google Patents

Description

Sound attenuation in lines with a smooth passage to which resonators Different natural frequency are connected There are known facilities at which attempts are made to attenuate the sound in lines with a smooth passage to achieve that side of the lines resonators in any order are connected. Such branch filters act like the electrical ones Analogy, as a suction circuit. Through such an arbitrary disorderly sequence However, a _ broad 'attenuation range cannot be achieved, since the coupling of the individual resonators with each other only for the attenuation of individual frequencies or individual small frequency ranges can lead.

According to the invention, there is now an attenuation of the sound in lines with smooth passage to which resonators of different natural frequencies are connected are achieved by @ that: the space sizes of the resonators are roughly reversed how their corresponding fictitious frequencies behave. This dampens the sound Achieved over a larger frequency range with almost constant intensity. The recording of the damping curves therefore results in a practical one for the damping rectangular band filter curve with a steep slope.

In a further advantageous embodiment of the subject matter of the invention two or more resonators are arranged to the side of the sound line or around it, wherein the first resonator for damping the low frequencies is greatest and z. B. is connected by tubes to the sound line, while the second resonator to attenuate the middle frequencies smaller than the first and z. B. through openings in the sound line is connected to this and finally a third resonator to attenuate the highest frequencies the smallest and z. B. through a number of finest openings in the sound line is connected to this.

In the accompanying drawing, Fig. I shows an example of the training a device according to the invention shown while Fig. Figure 2 shows a curve representing the damping process.

In a conduit i, through which a medium flowed from left to right v-ird, sound vibrations occur which are caused by the medium. At di ° line i different resonators z, 4. and 6 are connected one after the other, which are connected to line i by corresponding means 3, 5 and 7.

The first resonator 2 stands with the help of a few tubes; with the Sicballeitung i in connection and is relatively large. This first resonator serves to dampen the low frequencies. The second resonator 4 is smaller than the resonator 2 and is connected to it through holes in the sound line. This resonator dampens the middle frequencies. Finally, a small resonator 6 is connected as a third resonator for damping the high frequencies, which is connected to the wall of the safety line by means of fine openings 7. The resonators connected one behind the other in this way must be matched to one another or dimensioned in such a way that the spatial sizes of the resonators behave in reverse order to their associated natural frequencies.

In the example shown, the resonators 2 and 1 are on the side, the resonator 6 is arranged around the sound line. However, all resonators can be used to the side or around the sound conductor or alternately one or the other version are provided.

The arrangement can also be made so that the first, second etc. Resonators two or more spaces are provided, each together one Resouator correspond. These groups must then also be dimensioned in such a way that the The spatial sizes of the resonators behave roughly the other way around than their associated Eib nfreque: nzen.

You can do the training z. B. advantageous also so that the series-connected resonators or groups of resonators in their resonances do not differ from each other by more than 1: 2. If you follow the rule given here before, then the damping curves for each resonator are obtained about the same width. As shown in Fig. 2, a practically rectangular band filter curve is then obtained with a large flank part work. Mz; n sees from this that a facility according to the Invention has the great advantage that the attenuation of a certain frequency starts suddenly and remains constant over the entire bandwidth.

The value for the attenuation width is given by the expression: b = F,. In this formula, c denotes the total conductance of the openings, V denotes the connected ones Resonator and F the cross section of the line through which the flow passes.

A device according to the invention is applicable wherever Sound occurs through flowing media in pipes or pipe-like rooms, these media being liquid, gaseous or solid. Body (in fine distribution) could be. The sound can be before the entry of the fatigue in the line already be virgins or only arise in this.

Claims (2)

PATENT CLAIMS: i. Sound attenuation in pipes with a finitely smooth passage, to which resonators of different natural frequencies are connected, characterized that the spatial sizes of the resonate,) reil behave roughly the other way around than their associated ones Natural frequencies. 2. Device according to claim i, characterized in that the first resonator for damping the low frequencies at the largest and z. B. by Rölirchen is connected to the sound line, while the second resonator for damping the middle frequencies smaller than the first and z. B. through openings: in the sound line connected to this, and finally a third resonator for damping the highest frequencies the smallest and z. B. through a series of very fine openings in the sound line is connected to it.