DE19830351A1 - Wide band sound absorber with two layers of sound absorbent material - Google Patents

Abstract

The first layer (20) of sound-absorbent material has a preset thickness (d2) spaced apart by a preset amount (s2) from which is a damped resonance absorber (10) formed of interconnected Helmholtz resonators. The resonance absorber is formed of a second layer of sound-absorbent material (11) with a preset thickness (d1). A perforated plate (12) opposite the first layer is positioned at a preset distance (s1) from the second layer.

Description

The invention relates to a broadband sound absorption device, in particular for Wall and / or ceiling lining with a first layer of sound absorbing Material provided in a predetermined thickness.

Such known sound absorbing wall and / or ceiling linings used in workshops, machine rooms and the like. This prevents them largely reduce and reduce the sound reflections from the room boundary surfaces with it the reverberation and the noise level.

In addition, such sound absorbing liners are used for improvement the room acoustics in measuring and test rooms, studios and the like. Here the sound reflections on the room boundary surfaces are also largely prevented, whereby a measuring environment can be created in measuring and test rooms, in which acoustic measurements can be carried out, and in studios an optimized one Room acoustics is maintained.

Both when reducing the noise level and when creating an acoustic suitable measurement environment, the highest possible degree of absorption for all frequencies zen of the sound to be absorbed.

While for an absorption of sound with frequencies that are greater than 500 Hz, a Absorbance of about 1 achieved with the known absorption panels absorption in the low-frequency range, i. H. in the area where the frequencies are below 500 Hz, is a problem. In particular, the absorpti onsgrad in this area limited by the depth of the lining.

For example, conventional absorption panels reach out even when off clothing depth of 250 mm only at 250 Hz absorption levels of approximately 0.9. Under half of 250 Hz, the degree of absorption of the known linings is especially for use in measuring and test rooms is generally too low, since the measuring to be achieved accuracy cannot be realized.

In view of these disadvantages of the device known from the prior art, lies the invention has for its object to improve the known device.

This object is achieved by a device of the type mentioned at the outset characterized in that at a predetermined distance from the first layer of sound sorbent material a damped resonance absorber device is provided.

The problem set out above is also achieved by a method for spreading band sound absorption with the steps of arranging a damped resonance absorber device at a predetermined distance from a wall to be clad and / or a blanket to be clad, and arranging a first layer sound absorbing material at a predetermined distance from the resonance absorber tung.

By using such a damped resonance absorber device, comparable with the prior art lining depth of the sound absorption direction, also for frequencies below 250 Hz, degrees of absorption above 0.9 be achieved.

According to a preferred development, the damped resonance absorber device can be formed by a plurality of coupled Helmholz resonators. Here can be a second layer of sound absorbing material with a predetermined Thickness and one provided at a predetermined distance from the second layer, the first Layer of sound absorbing material opposite perforated plate ver be applied.

Such resonance absorber devices are simple and can therefore be constructed manufacture inexpensively.

According to a preferred development of the invention, the perforated plate has a Perforated area proportion that is in a range from 0.001 to 0.03. Here, in  the perforated plate has circular holes with a diameter that is in an area from 3 mm to 9 mm.

A perforated plate designed in this way leads to a particularly advantageous fre rate-dependent degree of absorption.

According to another development of the invention, the perforated plate can have knobs have sound absorbing as a spacer between the second layer the material and the perforated plate.

By using such knobs is a particularly simple structure and thus a simple and inexpensive manufacture of the resonance absorber device optimal effect of the same possible.

The previously described training courses can advantageously be further developed in this regard be that the thickness of the first layer of sound absorbing material and / or the thickness of the second layer of sound absorbing material and / or the distance between resonance absorber device and the first layer of sound absorbing absorb the material and / or the distance between the first layer the material and the perforated plate and / or the perforated area portion of the perforated Plate formed according to a desired frequency-dependent degree of absorption are.

By optionally changing certain of the above-mentioned parameters the broadband sound absorption device thus to certain circumstances for example, the depth available for the sound absorption device and the like, as well as to the desired frequency-dependent degree of absorption sen.

According to a preferred development, on the side of the first sound absorption end layer facing away from the resonance absorber device, a perforated plate The device can be provided mechanically by such a perforated plate  can be designed to withstand high loads, and they also become optical shapes possibilities opened up.

The perforated area proportion of this perforated plate should be at least 0.3 so that the Ab sorption degree of the broadband sound absorption device is not reduced.

Further advantages of the invention result from the following exemplary description Practice of preferred embodiments of the invention with reference to the drawing mentions. Show it:

Fig. 1 a first embodiment of the broadband acoustic absorption device according to the present invention;

Fig. 2 shows a second embodiment of a broadband sound absorption device according to the present invention; and

Fig. 3 is a diagram showing the accuracy class depending on the environmental correction according to ISO 3744 as a function of the degree of absorption for acoustic measuring rooms with reflective floors and absorbent lining on the walls and the ceiling.

In Fig. 1 a first embodiment of a broadband sound absorption apparatus is shown according to the present invention. This device comprises a damped resonance absorber device 10 , which is arranged at a predetermined distance s ₃ with respect to a wall W. The damped resonance absorber device 10 has a layer 11 of sound-absorbing material with a predetermined thickness d ₁ .

Furthermore, the resonance absorber device 10 comprises a perforated plate 12 which is arranged at a predetermined distance s ₁ on the side of the layer 11 made of sound-absorbing material away from the wall by suitable means (not shown), for example spacers.

In the embodiment shown, the perforated plate 12 is in the form of a perforated plate, the hole diameter being approximately 6 mm and the proportion of the perforated area over the entire area being 0.008.

The absorption layer 11 consists of commercially available mineral wool or foam in a fiber-free design. In the illustrated embodiment, absorption material with a length-specific flow resistance of 10 Ns / m ^{4 is} used.

In addition, the broadband sound absorption device comprises a further layer 20 of sound-absorbing material with a predetermined thickness d ₂ . The layer 20 of sound-absorbing material is provided at a distance s _{2 from} the perforated plate 12 . Commercially available mineral wool or foam material in a fiber-free design is also used as the sound-absorbing material, which also preferably has a length-specific flow resistance of approximately 10 Ns / m ⁴ .

The following measurements are suitable for obtaining a broadband sound absorption device, as is required for room acoustic design (ie ideally a degree of absorption of 1 in the entire frequency range):
d ₁ = 100 mm, d ₂ = 150 mm, s ₁ = 3 mm, s ₂ = 50 mm and s ₃ = 50 mm

The following table shows the degrees of absorption of the Breit according to the invention band sound absorption device and a conventional broadband sound absorption Device shown for different frequencies.

table

As can be seen from this table, according to the invention can already be in the frequency range 100 Hz, an absorption factor of <0.9 can be obtained.  

In FIG. 2, a second embodiment of the broadband acoustic absorption apparatus is shown according to the present invention.

This device differs from the device according to FIG. 1 in that on the one hand the perforated plate 12 is provided with knobs 13 and in that a perforated plate 21 is provided in front of the second sound-absorbing layer 20 .

The provided in the perforated plate 12 knobs 13 serve as a spacer, so that the required between the perforated plate 12 and the layer 11 of absorbent material distance s _{1 is} ensured. The knobs 13 can be formed by a suitable method, for example deep drawing. Instead of the knobs, other depressions, which are formed, for example, by folds and / or bends, can be formed in the plate 12 .

The perforated plate 21 of the second embodiment comprises circular holes with a hole diameter of approximately 5 mm and a hole area fraction of 0.45.

The broadband sound absorption device can be subjected to high mechanical stresses due to the perforated plate cover 21 . In addition, the hole pattern and the surface of the perforated plate can be adapted to optical requirements if necessary.

In addition to the described embodiments, numerous modifications are possible.

In particular, the thicknesses of the sound-absorbing layers d ₁ and d ₂ as well as the diameter of the perforated perforation of the perforated plate 12 and the distance of this plate from the sound-absorbing layer 11 s ₁ , the perforated area portion of the perforated plate 12 and the distances s ₂ and s ₃ of the elements described to one another and the length-specific flow resistance of the layers of sound-absorbing material to be adapted to the desired degree of absorption.

If necessary, d. H. desired absorption characteristics and product requirements To ensure, other absorption materials, such as in  for example sheep wool, cotton, gypsum foam, cellulose, expanded clay, foam glass etc. be used.

The perforated plate as well as the perforated plate cover can also be made if necessary another material, e.g. B. plastic.

In Fig. 3, a diagram is shown in which the environmental correction in acoustic measuring rooms with a reflective floor and absorbent lining on the walls and ceiling is shown. A length and a width of a and a height of a / 2 were assumed for the measuring room. A length and width of b and a height of b / 2 were assumed for the measuring surface.

The different curves represent, as indicated, different absorption grade α.

Furthermore, the accuracy class according to ISO 3744 which is dependent on the environmental correction is indicated in FIG. 3.

From Fig. 3 can thus be achieved with the broadband sound absorption device according to the invention accuracy class of acoustic measurements in measuring and test space men. In practice, the broadband sound absorption device according to the invention enables measurements in the highest accuracy class, in which the environmental correction must not exceed 0.5, in the frequency range from 100 Hz.

Claims (18)

1. Broadband sound absorption device, in particular for wall and / or ceiling lining, comprising a first layer ( 20 ) of sound-absorbing material with a predetermined thickness (d ₂ ), characterized in that at a predetermined distance (s ₂ ) to the first layer ( 20 ) a damped resonance absorber device ( 10 ) is provided from sound-absorbing material. 2. Device according to claim 1, in which the damped Resonanzabsorberein direction ( 10 ) is ausgebil det by a plurality of coupled Helmholtz resonators. 3. Device according to claim 1 or 2, in which the Resonanzabsorbereinrich device ( 10 ) by a second layer ( 11 ) of sound-absorbing material with a predetermined thickness (d ₁ ) and at a predetermined distance (s ₁ ) to the second layer ( 11 ) provided, the first layer ( 20 ) of sound-absorbing material opposite, perforated plate ( 12 ) is formed. 4. The device according to claim 3, in which the perforated plate ( 12 ) has a perforation area in a range from 0.001 to 0.03. 5. The device according to claim 3 or 4, in which the perforated plate ( 12 ) has circular holes with a diameter in a range of 3 mm to 9 mm. 6. Device according to one of claims 3 to 5, in which the perforated plate ( 12 ) has knobs ( 13 ) which act as spacers (s ₁ ) between the second layer ( 11 ) of sound-absorbing material and the perforated plate ( 12 ) . 7. Device according to one of the preceding claims, in which the thickness (d ₂ ) of the first layer ( 20 ) made of sound-absorbing material and / or the thickness (d ₁ ) of the second layer ( 11 ) made of sound-absorbing material and / or the distance (s ₂ ) between the resonance absorber device ( 10 ) and the first layer ( 11 ) of sound-absorbing material and / or the distance between the first layer of sound-absorbing material ( 11 ) and the perforated plate ( 12 ) and / or the perforated area portion of the perforated plate ( 12 ) are designed according to a desired frequency-dependent degree of absorption. 8. Device according to one of the preceding claims, in which a perforated plate ( 21 ) is provided on the side of the first sound-absorbing layer ( 20 ) facing away from the resonance absorber device ( 10 ). 9. The device according to claim 5, in which the perforated plate ( 21 ) has a perforated surface portion of at least 0.3. 10. A broadband sound absorption method comprising the steps of:
Arranging a damped resonance absorber device ( 10 ) at a predetermined distance (s ₃ ) to a wall to be covered (W) and / or a ceiling to be covered, and
Arranging a first layer ( 20 ) of sound-absorbing material at a predetermined distance (s ₂ ) from the resonance absorber device ( 10 ). 11. The method according to claim 10, in which the damped Resonanzabsorberein direction ( 10 ) in the form of a plurality of coupled Helmholtz resonators is seen easily. 12. The method according to claim 11, in which the resonance absorber device ( 10 ) is provided in the form of a second layer ( 11 ) made of sound-absorbing material with a predetermined thickness (d ₁ ) and at a predetermined distance (s ₁ ) from the second layer ( 11 ), the perforated plate ( 12 ) opposite the first layer ( 20 ) of sound-absorbing material is provided. 13. The method according to claim 12, in which a perforated plate ( 12 ) is used with a perforation area in a range from 0.001 to 0.03. 14. The method according to claim 12 or 13, in which a perforated plate ( 12 ) with circular holes with a diameter in a range of 3 mm to 9 mm is used. 15. The method according to any one of claims 12 to 14, in which a perforated plate ( 12 ) with knobs ( 13 ) which act as a spacer (s ₁ ) between the second layer ( 11 ) of sound-absorbing material and the perforated plate ( 12 ) , is used. 16. The method according to any one of claims 10 to 15, in which the thickness (d ₂ ) of the first layer ( 20 ) made of sound-absorbing material and / or the thickness (d ₁ ) of the second layer ( 11 ) made of sound-absorbing material and / or From stood (s ₂ ) between the resonance absorber device ( 10 ) and the first layer ( 11 ) of sound-absorbing material and / or the distance between the first layer of sound-absorbing material ( 11 ) and the perforated plate ( 12 ) and / or the predetermined distance (s ₃ ) of the resonance absorber device ( 10 ) from the wall to be clad (W) and / or the ceiling to be clad and / or the perforated area portion of the perforated plate is adjusted in accordance with a desired frequency-dependent degree of absorption. 17. The method according to any one of claims 10 to 16, in which on the side of the resonance absorber device ( 10 ) facing away from the first sound absorbing layer ( 20 ) a perforated plate ( 21 ) is provided. 18. The method according to claim 17, in which a perforated plate ( 21 ) with a hole area fraction of at least 0.3 is used.