NL8700513A - DEVICE FOR ADJUSTING THE SOUND CARTRIDGE INCLUDING THE RENAL TIME IN A ROOM. - Google Patents

Description

- I

£.: _.

873006 / Ke / HH

Device for setting the sound pattern including the reverberation time in a room.

The invention relates to a device for installing the sound pattern, including the reverberation time, in a room, and comprising a number of sound-absorbing / reflecting members which can be arranged, for example, in the corners of the room.

Swedish patent application no. 8103345 describes the use of flat diagonal absorbents that adjust the sound pattern, including the reverberation time in a room. However, the frequency response is not completely satisfactory because it is not sufficiently uniform, see Fig. 5b.

According to the invention, each sound-absorbing member is shaped such that it is preferably located in places near an angle where the speed of the air particles is particularly high, exploiting the phenomenon that the speed of the air particles is particularly high in special places .

In this way, an even requisite sponge is obtained and thus the possibilities for adjusting the reverberation time are improved. Furthermore, the members according to the invention are flexible in such a way that architectural solutions become possible.

The invention will now be described with reference to the accompanying drawings.

Fig. 1 illustrates a known diagonal absorbent fabric to be angled; FIG. 2 illustrates Ej / E t of a diffused sound field at an angle.

Fig. 3 illustrates isoabsorption curves (E / ^ / B constant) containing diagonal absorbents, and at different ratios from size to wavelength; FIG. 4 illustrates the absorption against the frequency;

Fig. 5 illustrates the absorption against the frequency in various embodiments of the absorbent, and

Fig. 6 illustrates flow resistance to density.

$ 700513 1Λ * ï '-2-

At frequencies greater than about 100 to 300 Hz, the sound absorption in the diagonal absorbent material of Fig. J occurs during the movement of the air particles in a porous immobile material. The absorbent material is at an angle 5 where the velocities of the air particles (cf. fig. 25) are high.

The frequency f ^ where the absorption is maximum can be determined on the basis of theoretical analyzes of the sound field at an angle as: _ 140 _ 280 * 1 ““ ”Τ7 * !!! 28 10 where d is the depth of the absorbing dust in meters while X and · Θ are indicated in fig. 1.

At lower frequencies (50-200 Hz) with diagonal absorbents, £. less than 2 m, the sound absorption 15 is mainly due to the sheet material oscillating at the resonant frequency, and because the energy is absorbed due to loss in the material and loss along the edges where the material is attached. When these resonant vibrations are activated, the areas of the sound field 20 with high pressure variations are important.

Associated with a flat diagonal absorbent fabric with low flexural strength compared to the. resistance of the trapped air is the resonance frequency: j__120

to ~ Vm.l.sin (Sfï Z

Where m is the mass of the sheet material per unit area 2 λ in. kg / m and X is the length in meters. The former process at high frequencies entails specific requirements in terms of size, shape and flow resistance. The second process at low frequencies has specific requirements in terms of dimensions and mass at unit area.

The aim is to achieve the highest possible sound absorption in the frequency range 100-4000 Hz, and the absorption should preferably be in this frequency range. take place as evenly as possible.

Experiments with flat absorbents have given promising results when X-0.90 m and &-30 °, and there are still possibilities. better results are expected in connection with special, non-planar embodiments (cf. fig. 5d). Conversely, uneven frequency processes should be expected with particularly unfavorable 27 0 0 5 1 3

Sr -> -3- versions. Problems arise at low frequencies if the dimensions are too small- Furthermore, the available absorption range depends on the surface of the absorbent material.

Since the resonant frequency should be approximately 4.00 Hz and is assumed to be in the range of 0.90-1 / 80 m, the following requirements for the mass per unit area arise: 2 m = 1 - 2 kg / m because the mass per unit area must be highest for small 10 values of each. Experiments have shown that the flow resistance should be slightly higher than in connection with traditional suspended 3 ceiling plates, probably approximately: r = 2000 - 2500 Ns / m. These values depend on the sheet thickness h and also on actual material parameters of the formula; 15 m = p.h, where β is the density, and r = ST-h, where S? is the specific flow resistance.

Thus one obtains> = Ef o '1,250 s "1 20 which can be recorded in a -p- graph as a line (cf. fig. 6).

The latter may indicate that the maximum fiber diameter is slightly smaller than the fiber diameter of conventional glass wool. Alternatively, a cover layer that suitably increases flow resistance can be used.

In order to prevent high-frequency signals from being reflected by an excessively compressed surface, the specific flow resistance should not be too high. The material parameters should be selected within the following ranges: h p 7 = T ~ 30 20 mm 100 kg / m3 125.103 Ns / m4 3 3 4 40 mm 50 kg / m 63.10 Ns / m

Pig. 5a-e show the characteristics of different embodiments of the absorber. Fig. 5a shows an oval absorber that gives a very uneven frequency response because that frequency response exhibits a groove at (i / j ^ = 0.7, corresponding to a location of the absorption material in places with the weakest oscillations. Fig. 5b also provides a very poor response because in this case only part of the absorbent is located at the site showing the largest oscilla- 870O513 -4- 'X tions A slight improvement is obtained by the diagonal absorbent asymmetrical, to be placed with an angle that

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peels from 45. Fig. 3 illustrates the effect of such an absorbent on the sound field at different frequencies. 5 turns out that. the response must necessarily exhibit a screw (illustrated at about 500 Hz). Fig. 5d illustrates an ideal embodiment of the absorber, which member is located in areas containing a particularly strong sound field. Fig. 5th illustrates. the absorber of an alternative asymmetrical embodiment, ie an asymmetrical L-shaped embodiment.

Fig. 6 illustrates the flow resistance to the density of different material types.

The sound absorbing members can be changed if desired in response to. one or more parameter values in the chamber, if desired in such a way that they counteract a possible change of the parameter values in question.

For example, the sound absorbing elements can be used in a concert hall and adjusted according to the special requirements of. an orchestra related to the reverberation time, etc., 20 if desired during a concert.

The absorbent materials are located in one or more corners of the room and along the edge of the ceiling. The absorbent fabric of Fig. 5e is preferably located along the edge of the ceiling, optionally along with a perforated, sound-permeable sub-ceiling which is flush with the absorbent fabric and provides a good architectural effect.

30 35 8700513

Claims (10)

Device for adjusting the sound pattern, including the reverberation time, in a room, and comprising a number of sound-absorbing / reflecting elements which can be arranged, for example, in the corners of the room, characterized in that each of the sound-absorbing members near a corner or along an edge of the ceiling are shaped in such a way that it is preferably located where the sound field is particularly strong. Device according to claim 1, characterized in that the sound-absorbing member is asymmetrically L-shaped or corrugated. Device according to claim 2, characterized in that the distance between a crest and a trough of a wave substantially corresponds to a quarter of the wavelength. The device according to any one of claims 1 to 3, characterized in that the sound-absorbing member is located asymmetrically. Device according to any one of the preceding claims, characterized in that each member is provided with a covering layer, whereby the flow resistance is increased. 6. Device according to any one of the preceding claims, characterized in that the sound-absorbing members can be changed in response to one or more parameter values in the room. Device according to claim 6, characterized in that the sound-absorbing / reflecting members are modifiable in such a way that they counteract a possible change of the parameter values in question. Device according to claim 7, characterized in that the changes are controlled by a microprocessor capable of comparing the sound pattern with a desired sound pattern. 9. Device according to claim 6, characterized in that the sound-absorbing members are adjusted and / or deformed in response to the special requirements of an orchestra with regard to the reverberation time, etc., if desired in connection with a concert. Device according to claim 9, characterized in that the means for adjusting the sound pattern is connected to one of the musical instruments. 35 8700513