DE1264021B - Sound absorbing wall - Google Patents

Description

Soundproofing wall The soundproofing of a wall is known mainly influenced by the inertia. Nevertheless, the insulation values correspond in the rarest cases the inertial resistance of the wall, because other factors such as B. the bending stiffness of the wall, reduce the insulation. The following applies to single walls therefore that for an increase in the average sound insulation by 6 db the wall weight must at least be doubled.

Increasing the weight to improve sound insulation is often undesirable. In such cases, multi-layer walls are used with the same sound insulation are lighter, but take up more space. This is also the case with the multi-layer wall but of course, the greater the weight, the greater the sound insulation thus the sound insulation of the single shell.

The law of mass as the upper limit of what can be achieved with a simple shell Although sound insulation applies to homogeneous walls, it is by no means generally applicable: It applies z. B. not if an in-phase excitation of the wall is not an in-phase one Wall oscillation.

An out-of-phase oscillation of individual parts of the wall surface against each other can despite in-phase excitation z. B. can then be achieved if the wall mass unevenly distributed over the surface, so that individual parts of the wall surface are different Have input impedances. If individual wall parts oscillate in opposite phase, the Sound radiation of a wall is lower than that despite the same oscillation amplitude a homogeneous wall vibrating in phase, because the radiated sound components partially annihilate each other.

Antiphase oscillation can also be achieved by connecting it to the wall Achieve resonators. You can z. B. the wall with appropriately sized cavities provided so that it swings in part as a single-shell wall, each as a mechanical one Series circuit arranged resonator in resonance exactly in phase opposition to the exciting force swings. The invention is based on this knowledge.

Resonators that are used for the purpose of sound absorption, are known. Such resonators must largely adapt to the wave resistance of the air are adapted and therefore have an input resistance with an optimal design from about 60 to 80 Rayl. However, this can improve sound insulation cannot be achieved.

According to the invention, high insulation with low weight is intended by means of a sound-absorbing wall with chambers opened to the room through perforation can be achieved in that the chambers as Helmholtz resonators with an im An input resistance range below about 40 acoustic ohms is formed are and have rigid walls that are rigidly connected to one another. Consequently should, contrary to known requirements, the input resistance of the resonators in Resonance case must be less than 40 Rayl.

The resonators are therefore possibly responsible for sound absorption ineffective.

Through the subject matter of the invention, the sound insulation in the area of Resonance frequency of the resonators around 20 db and on average over the entire building acoustics Frequency range can be improved by about 6 to 8 db.

To achieve the broadest possible effectiveness of the sound-absorbing wall, it is necessary to adjust the input resistance Z of the resonators accordingly to keep it as small as possible.

M means the effective mass of the air plugs in the resonator neck, F the suspension of the resonator volume.

Accordingly, the spring volume, ie the resonator cavity allotted to a hole in the cover plate and the individual resonator openings should be as large as possible. However, there are limits to this, since the natural frequency f depends on the size of the resonator space and the resonator opening is dependent. Accordingly, the input resistance Z is calculated taking into account all the requirements mentioned - as follows: Since the greatest sound insulation occurs at the natural frequency, it is important to achieve the greatest possible effect on the frequency selection. Either a maximum improvement in insulation at a certain frequency can be sought or the greatest insulation effect over the entire frequency range, e.g. B. by differently tuned resonators. This can be achieved by different volumes of the resonator chambers or by a different number or size of the openings per chamber, whereby the mentioned features can also be used in combination.

The wall according to the invention can also be formed in that a construction element consisting of a grate-like latticework and a perforated one Cover plate with a wall, ceiling or the like. Is rigidly connected. With a fastening The impact sound insulation can be improved on the underside of the ceiling.

Further details of the invention are from the drawing and their Explanation can be found. It shows F i g. 1 a plate-shaped component for attachment on an existing wall in an oblique partial view, FIG. 2 a wall-forming, plate-shaped one Component with Helmholtz resonators arranged on one side in the same view, F i g. 3 shows a component according to FIG. 2, but with arranged on both sides Helmholtz resonators, FIG. 4 measurement results associated with the subject matter of the invention were achieved.

The component according to FIG. 1 consists of a perforated Plate 1 a and a grate-like latticework 1 b arranged on one side. The holes 1 c can according to the desired or required sound insulation improvement have the same or different size; they can be more or less systematic be arranged; several holes can also be provided on a grid field. The grid cells can be the same or different sizes. The shape of the cells can be anything, e.g. B. polygonal, corresponding to 'a honeycomb.

The component should have as little mass as possible and can accordingly the intended use made of thin sheet metal, plastic, hard paper, plaster of paris, made by binding agents stiffened fiber or fiber reinforced plastic. It can also consist entirely or partially of foam plastic.

The component according to FIG. 1 can be on or off existing walls be attached on both sides. The component according to FIG. 2 is with another Shell 2 provided and thus independently wall-forming. Because the shell 2 is not perforated are all Helmholtz resonators created by the connection with the shell 2 directed only on one side towards the perforated cover plate 1a.

In Fig. 3, however, the shell 2 a is perforated. The perforation the plate la and the shell 2a are related to each other in such a way that the Resonator chambers only on one side, either via the holes 1c of the plate la or those of the shell 2a, are in communication with the outside space.

In Fig. 4 are the insulation values associated with the subject of the invention - according to the strongly drawn out curve - and for comparison with a known, not drilled wall - according to the dashed curve - were achieved graphically reproduced in a coordinate system. The test wall was with holes from 5 mm in diameter. On the ordinate is the sound reduction index in decibels, on the abscissa shows the sound frequency f in Hertz. By this comparison is the sound insulation improvement achieved according to the invention, which in particular according to the experiment is very important in the range of 200 to 2500 Hz, clearly illustrated. As already mentioned, by an appropriate construction, for. B. Change the resonator volume and the holes shown in FIG. 4 specified values, if applicable be changed in accordance with the respective requirements, d. i.e., the one shown Curve can, if necessary, e.g. B. flattened by differently tuned resonators or in a higher or lower frequency range with maximum insulation improvement be shifted at a certain frequency.

Claims (5)

Claims: 1. Sound-absorbing wall with perforation for Chambers open towards space, d a -characterized in that the chambers are designed as Hehnholtz resonators with an input resistance in the range below about 40 acoustic ohms are formed and have rigid walls that are rigidly connected to one another are. 2. Wall according to claim 1, characterized in that the chambers alternately are open to one side and the other. 3. Wall according to claim 1 or 2, characterized in that the resonators are tuned differently, for example through different openings and / or chamber volumes. 4. Wall after a of claims 1 to 3 from a wall, ceiling or the like. With which a component, consisting made of a rust-like latticework and a perforated cover plate, rigidly connected is. 5. Wall according to one of the preceding claims, characterized in that it is at least partially made of foam plastic. References considered: U.S. Patent No. 2,350,513; Slawin, Industrial Noise and Its Combat, Berlin, 1960, pp. 274/275.