DE8032078U1 - Coincidence silencer - Google Patents

Description

U em 89/80 f

Sat, 29. 3. 80

COINCIDENCE SILENCER

The invention relates to a wall element for sound absorption with a closed surface and high mechanical, corrosive and thermal strength using the coincidence effect. It is intended to bring about _sound dampening and sound insulation in ducts, capsules, rooms and in intake and outlet flows.

Absorption materials of various designs are known for this task. In these, the sound is converted into heat by the frictional movement of the sound wave and the absorption material. In order to achieve high absorption values, it is important to have an absorber surface that is as soft and open-pored as possible and a sufficient absorber depth. In addition, when using absorbent room walls or ceilings, a minimum distance of approximately one quarter of the sound wavelength from the absorber to the wall is necessary in order to be in the area of effective velocity movements.

A disadvantage of the absorption materials described is their low resistance to mechanical stress, moisture and rotting.

The German patent application P 25 31 866 has disclosed a wall element that also uses the coincidence effect to absorb sound. The disadvantage of this design, however, is that these elements are not flexural vibrators and do not have a volumetric stroke. This means that they are ineffective when sound is applied to both sides.

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The object of the invention is a wall element for sound absorption using the coincidence effect. In particular, coincidence oscillators are provided which have a volumetric thrust. This results in sound damping and sound insulation compared to the state of the art, even when sound is applied from both sides. Thanks to the volumetric thrust, even when the front and back are exposed to the same force, the resulting pressure forces are not canceled out, but both sides are individually stimulated to coincidence oscillations. This not only results in double utilization of the area, but also saves the need for a special covering of one side of the wall to avoid pressure neutralization.

According to the invention, this object is achieved by using bending waveguides as coincidence waveguides with profile shapes with a high area moment of inertia J, e.g. trapezoidal, wave-shaped and made of a material with a high elastic modulus E and low density <? , e.g. aluminum, beryllium, steel, GRP and CFRP materials. With these conditions, sufficiently high bending wave speeds can be achieved with a low area weight and therefore a high acoustic effect.

/ According to a further feature of the invention, 2 coincidence waveguides are connected together essentially in parallel, whereby the resulting gap is sealed gas-tight and filled with a gas with a high speed of sound, e.g. helium or hydrogen. Such a measure results in pressure equalization in the gap thanks to the high speed of sound, so that even when the coincidence waveguides are close together, the spring properties of the gas cushion are less disruptive.

According to a further feature of the invention, as coincidence waveguides, flat or strip-shaped membranes are used, which are subjected to a two- or one-axis tensile load, so

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that the membrane wave speed is equal to the speed of sound of the surrounding medium. The tensile load on flat membrane surfaces can be achieved by clamping the edges. Another possibility is to keep curved membrane surfaces under tensile load by applying a vacuum or negative pressure to one side.

According to a further feature of the invention, the edges of the flexible waveguides used as coincidence waveguides are not firmly fixed to one another, but can oscillate freely thanks to a spring-soft connection. This means that the entire length of the coincidence waveguide is effective. Furthermore, the rear end of the coincidence waveguide, seen in the direction of sound, is damped. This can be achieved in a manner known per se by a reflection-free termination of the coincidence waveguide. In this case, the termination impedance is matched to that of the flexible waveguide. This mechanism is also used, for example, for edge damping of window panes using putty.

According to a further feature of the invention, the coincidence waveguides are additionally covered with conventional, porous absorption mats. This allows the high frequencies in particular to be attenuated.

The invention is explained in more detail with reference to the following drawing descriptions. They show

Fig. 1 to Fig. 7 Absorption elements with coincidence waveguides using bending waves,

Fig. 8 to Fig. 11 Absorption elements with coincidence waveguides using membrane waves.

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Fig. 1 shows the basic design of an absorption element 1. It consists of 2 coincidence conductors 2, which have a trapezoidal shape. There is a gap 3 between the two coincidence conductors 2. The gap 3 is sealed gas-tight to the outside and is filled with a gas with a high speed of sound, e.g. hydrogen or helium at ambient pressure.

Spacers 4 in roll form are used for mutual fixation. The coincidence conductors 2 represent bending waveguides. Given the wall thickness and trapezoid height, these have an area moment of inertia J in the axial direction. With the elastic modulus E, mass coverage m and at the excitation frequency w, the coincidence conductor has a bending wave velocity C-

This is now chosen so that it corresponds to the track speed C

of a sound wave incident at an angle oC*

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To attenuate broadband noise signals, several absorption elements 1 tuned to different frequencies must be used. In the case of parallel sound incidence, C = C = C_ (C = speed of sound). Materials with a high modulus of elasticity E and low density, e.g. aluminum, fiber materials such as GRP and CFRP, beryllium and also steel, are particularly suitable as materials for the coincidence conductors.

Fig. 2 shows an analogous design to Fig. 1. The absorption element 11 consists of 2 coincidence conductors 12 with a wave-shaped profile. In the space 13 there is again a gas with a high speed of sound (hydrogen, helium) at ambient pressure and the roller-shaped fixings 14.

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The coincidence conductors 12 again represent bending wave conductors whose bending wave speed is matched to that of the surrounding medium, e.g. air. The absorption elements are installed, for example, in a ventilation duct 1S " .

In addition to the trapezoidal or wave shape of the coincidence conductor in the previous description examples, any cross-sectional shape can be selected. The profile shape is used in particular to increase the area moment of inertia and thus the bending wave speed. In Fig. 3, for example, a double-wave profile shape of the coincidence waveguide is shown. In this case, a pulling mechanism 23 is also provided, by means of which the coincidence waveguide 22 can be stretched (shortened) in the transverse direction. This also changes the profile height and thus the bending wave speed. In this way, these can be adapted to changed operating conditions. Automatic, temperature-dependent control is achieved when bimetallic strips are used. Pressure-dependent control can be achieved in a similar way using barometer springs.

Since the bending wave speed is frequency-dependent, absorption elements 31 are shown in Fig. 4 for a broadband sound influence, the coincidence conductors 32 of which have different profile heights and thus coincidence speeds adapted to the different frequencies of the speed of sound.

In Fig. 5, an absorption element 41 is shown in longitudinal section. It is characterized in that the profile height of the coincidence conductors 42 increases in the longitudinal direction. Such a measure ensures, as in Fig. 4, that in the case of broadband noise, the individual noise frequencies each find suitable sections with coincidence conditions.

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Fig. 6 is a cross-section through an absorption element 51 with a double-tubular coincidence waveguide 52. In the gas- tight space 53 there is again gas with high sound velocity.

Fig. 7 shows the cross section of an absorption element 61 with coincidence waveguides 62 consisting of honeycomb plates, which are joined together in a gas-tight manner to form the intermediate space 63. The cover plates oriented towards the intermediate space 63 expediently have openings 64 so that a relatively large volume is formed in the intermediate space 63. In this case C i , air can also be provided in the intermediate space 63 instead of a gas with a high speed of sound.

While in the embodiments according to Figs. 1 to 7 bending waveguides were used, in Figs. 8 to 11 membrane waveguides are used.

Fig. 8 shows an absorption element 71 whose coincidence waveguide 72 carries out membrane waves. It is spanned by a back shell 74. The space 73 between coincidence waveguide 72 and back shell 74 is evacuated or partially evacuated. In the latter case, the residual gas (hydrogen, helium) has a high speed of sound. The negative pressure load results in a tensile load in the coincidence waveguide 72. Tensile load and mass loading result in a frequency-independent membrane speed in a manner known per se. This is designed for coincidence with the ambient medium.

Since the pressure load on the coincidence waveguide 72 results in a curvature, it is advantageous to use such a construction simultaneously as a deflection element in a bend.

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With a mass loading^of the membrane, the pressure difference Δ.�R· between the front and back, the radius of curvature r, which gives the coincidence speed c, is

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Fig. 9 shows an absorption element 81 integrated into a tube. It consists of a cylindrical coincidence waveguide 82 which is held by a tube casing 84. The space 83 between the coincidence waveguide 82 and the tube casing is fully or partially evacuated. This creates a tension in the coincidence waveguide 82 which results in a frequency-independent membrane wave velocity. Thanks to the transverse contraction, the primary ring stresses are also converted into longitudinal stresses so that the membrane wave velocity in both directions can be made equal to the speed of sound of the medium flowing through the tube.

Fig. 10 shows the inverse case to Fig. 9. Here, the absorption element 61 consists of a tubular coincidence waveguide 62. This is under an internal pressure P., whereby the pressurized gas consists of low-molecular substances with a high speed of sound. The membrane wave speed can be adjusted to coincidence in an analogous manner by means of the internal pressure.

Fig. 11 shows a two-sided absorption element 101 which has tensioned membranes on its outer sides as coincidence waveguides 102. At a membrane density of **» ^kg/m_7, these receive a tension G~lß/mJ so that the membrane speed C _M = y C/ f is equal to the speed of sound of the surrounding medium, e.g. air. The tension C exists in both membrane directions so that sound can be absorbed from all angular directions. In narrow channels with a preferred direction, a uniaxial membrane tension is sufficient.

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The tension itself can be maintained by springs 105 (e.g. buckling springs). These springs 105 are particularly recommended because of their fader constancy, so that the same membrane tension is always maintained regardless of expansion. The springs 105 themselves are supported on a central plate 104. The interior 103 is filled with a gas with high sound speed.

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Claims (8)

ti Il ·■ Ot *· ·■ &bull; 4 Jfc ft » Ju'l * &Lgr; » · &bull; ■■ &igr; · · -3 &igr;&igr; * · &ogr;&igr; · PROTECTION CLAIMS &bull; 1. Absorption element with a closed surface based on the coincidence effect, characterized in that 2 coincidence waveguides with a trapezoidal, wave-shaped, double-wave-shaped or tubular profile made of a material with a high modulus of elasticity and low density, e.g. aluminum, beryllium, CFRP, GFRP fibers, steel are joined together and the space between them is sealed gas-tight and filled with a gas with a high speed of sound, e.g. hydrogen or helium, and spacers are used for fixing. 2. Absorption element according to claim 1, characterized in that the profile depth and thus the bending wave speed of the coincidence waveguides differs in the transverse direction (Fig. 4). 3. Absorption element according to claim 1, characterized in that the profile depth of the coincidence waveguides is different in the longitudinal direction (Fig. 5). 4. Absorption element according to claims 1 to 3 ^, characterized in that the profile height is changed by a transverse expansion of the coincidence waveguides by bimetallic, barometer spring or controlled mechanical adjustment and thus the coincidence speed is adapted to a changing operating condition (Fig. 3). 5. Absorption element according to claim 1, characterized in that a coincidence waveguide (72) acting as a membrane conductor is spanned by a cylindrical shell (74) in that the intermediate space (73) which is formed is evacuated or, in the case of a partial vacuum, is filled with a gas with a high speed of sound. - 10 - »III ··!*··&euro;· >1 JJJl 11 Jl » · «· 6. Absorption element according to claim 1, characterized in that a cylindrical coincidence waveguide (82) spanned by a tube (84) acts as a membrane conductor, the membrane tension being achieved by evacuating the intermediate space (8). 7. Absorption element according to claim 1, characterized in that two membrane surfaces (62) are held under tension by springs so that their membrane wave speed is set to coincide with the ambient medium to be damped and are joined together in a gas-tight manner, whereby the &Lgr; gap is filled with a gas at high speed of sound. 8. Absorption element according to claims 1 to 7, characterized in that the coincidence waveguides are closed off at the edges in a reflection-free manner by edge attenuation.