DE10026584A1 - Acoustic element has impedance grid with solid reflective areas, hollow vibrational areas with membrane covering layer, hollow central layer defining separation of two membrane layers - Google Patents

Abstract

The acoustic element has at least one impedance grid (2,3,4,5) with reflective areas (7) made of a solid material and hollow vibrational areas (8) with a membrane covering layer (9) and a rear membrane layer (10) and a hollow central layer (11) defining the separation of the two membrane layers. The hollow areas can be round and/or hexagonal.

Description

Acoustic elements have the function of creating the acoustics of a room in a desired way to influence th way, e.g. B. a sound coming from different directions len can reflect diffusely to generate diffuse sound fields.

For special applications, e.g. B. to increase clarity or language understandability, are also reflections with diffuse characteristics of a certain Room area in another certain room area desired.

The main characteristics of diffuse sound fields are a uniform sound incidence from all directions and balanced amplitude ratios at the same frequency as well as balanced relationships at all frequencies.

In order to achieve a completely diffuse reflection, the sound reflection (a) must be one λ / 4 phase shifted and (b) omnidirectionally scattered for all Fre sequences and all sound incidence angles evenly. Known to increase diffusivity Acoustic elements, however, only transform a vertically arriving beam very well gets into a diffuse reflection, since the above conditions (a) and (b) depend on the be were not met at the same time.

Sound scattering can e.g. B. by relief structures, the mathematical consequences fol gen, can be achieved. So λ / 4 shifted sound reflections are possible, however  a club-shaped scatter characteristic is achieved. Determining the relationship between amplitude, frequency, phase and direction that your perpendicular sound is possible, is difficult for other (oblique) directions of sound incidence, because right Flow-like structures have a comparatively deep depth for a broadband effect Construction depth. This leads e.g. B. to frequency and directional diffraction fect, d. H. the behavior varies depending on the version.

In this regard, reference is made to U.S. Patents 4821839, 4964486 and 507920, which each structured surfaces for sound absorption diffusers for a partial Ab Show sorption and reflection of sound.

Sound scattering can also be achieved through curved surfaces. At a comparatively large installation depth to ensure a broadband effect however, no / 4 shift is achieved.

Partial reflection and partial absorption is infinite due to impedance gratings Latter and towards 0 impedance possible, but with these grids there is none or to achieve only a narrow-band sound scatter. An exact phase difference of λ / 4 is not guaranteed.

There are therefore no known acoustic elements in the prior art which all require meet the relevant criteria. In addition, these known elements are based on subjective ones Building and listening experiences, each of which is an approximation or a compromise.

On the other hand is the description of diffuse sound fields and the influence involved sizes or their interaction when the diffuse sound fields arise advanced computer technology. The accuracy of the simula tion is only limited by the performance of the computer.

Based on these well-established theoretical foundations, Hörver seek a balance between theory and practice. To do this either  Acoustic elements that work according to the type of simulation are built or, conversely, the acoustic elements should be able to be recorded by data technology. A such data acquisition and thus a Simu compared with listening tests lation is based on known, based on subjective building and listening experiences Acoustic elements are very difficult or not possible at all.

The invention is therefore based on the object of specifying an acoustic element which with vertical sound incidence a λ / 4 shifted sound reflection, an omnidirection nale sound scattering and a broadband frequency effect guaranteed, the phase-shifting and omnidirectional effect even in the case of oblique sound broadband is preserved. The acoustic element should also be precisely writable and thus easy to record in terms of data, so that simulations are optimally supported the.

The tasks are performed by an acoustic element with the characteristics of the claim 1 solved.

The acoustic element according to the invention has at least one surface Impedance grid on which reflective partial surfaces made of a solid material and has oscillatable hollow sections, the hollow sections having a membrane deck layer, a membrane backing layer and the distance between the two membrane layers have defining hollow middle layer. Under the reflective partial surfaces A solid material also includes those that are made up of chambers that are made with one or more insulation materials are filled.

Such an impedance grid facing the room thus consists of three layers. Further impedance gratings can be arranged under this impedance grid, whereby the three layers of an upper impedance grid represent the membrane top layer for one represent the underlying impedance grid, which also consists of three layers. The Diameter of the membrane layers can be, for example, λ / 4, during the Distance of the membrane layer centers λ / 2 can be.  

If several impedance grids are used for an acoustic element according to the invention the membrane diameters of the Im arranged above each other pedance grid may be different. The membrane distances and the membrane diameters can with an underlying impedance grid z. B. double each.

The shape of the individual, oscillatable hollow partial surfaces of the at least one Im pedanzgitters is preferably round and / or hexagonal. Other forms, e.g. B. quadra tables, but are also possible. The shaped partial surfaces of the at least one Impedance grids are in a surface-tight arrangement, preferably in the Ab depending on the shape possible, most densely arranged arrangement. At a derar arrangement, different shapes of the sub-areas can be combined, e.g. B. round partial areas can be combined with hexagonal partial areas in such a way that a densest packing is achieved. With the acoustic element after the Invention λ / 4 shifted sound reflections are thus through an impedance grating from impedance to infinity (reflection) and impedance to 1 (power adapt solution, resonance) reached. The partial surfaces made of solid material reflect an impact fenden sound (impedance infinite), while the hollow partial surfaces of the impedance grid resonate (impedance = 1). Impedance grid from 1 and towards 0 can be changed by An order of empty and filled with insulation material can be achieved.

The sound scattering is achieved by the resonating membranes, the semi-ku Blast in a gel-like or hablball-like manner, d. H. the energy that strikes the Sound taken out due to the power adjustment will re in all directions inflected and thus scattered. To ensure this, Pac is the most densely packed kung, in particular the most densely packaged depending on the shape of the Areas, preferred.

The incident energy is thus reflected in a purely diffuse manner. The acoustic element after the invention supports all currently known features contributing to diffusivity without undefinable side effects, the range can also be selected. For Every frequency and for every angle of incidence can reflect direction, strength of reflection  (Amplitude) and phase position are described, so that the acoustic element after the invention can be recorded exactly in terms of data.

A broadband frequency effect is particularly ge by superimposed over each other layered impedance grid. The frequency range is determined by the parameters of the Layers, such as membrane diameter, distance between the membrane centers, exactly fixed layable.

The optimal values for membrane diameter and membrane distance can be be determined experimentally. A suitable value for the mem fire diameter is λ / 4, while for the distance between the membrane centers λ / 2 be is preferred

As listed above, the membrane spacing and membrane diameters can vary double for each underlying impedance grid. This doubling causes u. a. that the mutual influence of the resonating sub-areas is so low is possible as the partial overlap of hollow and solid sub-areas is avoided in adjacent impedance gratings. The resonating partial areas can be dimensioned so that the resonance frequency is hollow and solid Membrane backing remains the same. The doubling corresponds to the vote of single impedance grid at octave distance.

A favorable ratio of the basis weights for impedance gratings staggered in octaves is z. B. 3: 1: (3 × √5) (deck: middle: backing).

Top and back layers are preferably made of polystyrene plates, while the Mit tel layer preferably consists of styrofoam.

According to the desired requirements for the acoustic element according to the invention can the resonance behavior as well as the radiation characteristics by appropriate Interpretation of membrane thickness, membrane spacing and membrane weight as well as by  the appropriate definition of membrane size in relation to the resonance frequency Be designed wisely. The ratio of the scattered sound reflection to the proportion The λ / 4 shifted sound reflections can be changed by changing the membrane knife in relation to the distance between the membrane centers.

The acoustic element according to the invention has a low weight and can be like a any plate material can be assembled in a simple manner. Furthermore, one diverse surface design, but also a flat surface possible. Because of The low construction depth of the acoustic element according to the invention is not only Side effects minimized because the effective dimension is small compared to the waves length, but universal use is also possible, e.g. B. in small rooms. The acoustic element according to the invention can also be used in any surface, e.g. B. in Floors or in voluminous objects.

On the other hand, however, the acoustic element according to the invention is also free in the room can be set up, the at least one impedance z. B. on all sides on the surface of the acoustic element is arranged.

An exemplary embodiment is explained in more detail below with reference to drawings.

Fig. 1 shows a partial plan view of an embodiment of an acoustic element according to the invention.

FIG. 2 shows a section through the acoustic element according to FIG. 1 along the line AB.

An acoustic element 1 shown in FIGS . 1 and 2 has a plurality of impedance gratings 2 , 3 , 4 and 5 arranged one above the other.

The acoustic element also has on its surface an upstream pinhole 6 , which is shown in FIG. 1 in the form of simple small rings.

Each impedance grid 2-5 consists of partial surfaces 7 made of a solid material and of hollow partial surfaces 8 arranged adjacent to it. The hollow partial surfaces 8 have a membrane covering layer 9 and a membrane backing layer 10 , which are spaced apart from one another by a middle layer 11 representing the cavity. An upper impedance grid, e.g. B. 3, with its three layers 9 , 10 , 11 each form the membrane cover layer for an underlying impedance grid, z. B. 4.

The partial surfaces 8 of the impedance grids 2-5 are arranged according to FIG. 1 in the most densely packed. The partial surfaces 8 of the impedance grating 2 are circular. The subareas 8 of the underlying impedance grids 3 , 4 are circular 3a, 4a, or hexagonal 3b, 4b, while the subareas 8 of the lowermost impedance grid 5 are hexagonal in shape.

The impedance grids 2-5 are arranged one below the other according to FIG. 2. In this case, the respective membrane diameters D and membrane distances A double in the order of the grating 2-3-4-5 . The doubling has the effect that the mutual influencing of the resonating partial surfaces 8 remains as small as possible.

Claims (13)

1. Acoustic element, characterized in that it has at least one impedance grating ( 2 , 3 , 4 , 5 ) which has reflecting partial surfaces ( 7 ) made of a solid material and oscillatable hollow partial surfaces ( 8 ), the hollow partial surfaces having a membrane cover layer ( 9 ), a membrane backing layer ( 19 ) and a hollow middle layer ( 11 ) which determines the distance between the two membrane layers ( 9 , 10 ). 2. Acoustic element according to claim 1, characterized in that the partial surfaces ( 8 ) are present in a surface-tight arrangement, in particular surface-tightest arrangement according to the shape of the partial surfaces. 3. Acoustic element according to claim 1 or 2, characterized in that the shape of the oscillatable hollow partial surfaces ( 8 ) of the impedance grid ( 2-5 ) round ( 2 , 3 a, 4 a) and / or hexagonal ( 3 b, 4 b, 5 ). 4. Acoustic element according to claim 1 or 2, characterized in that the shape the oscillatable hollow partial surfaces is square. 5. Acoustic element according to one of claims 1 to 4, characterized in that the diameter of the membrane layers about / 4 the resonance frequency of the hollow Is partial areas.   6. Acoustic element according to one of claims 1 to 5, characterized in that the distance of the membrane layer centers around / 2 the resonance frequency of the hollow sub-areas. 7. Acoustic element according to one of claims 1 to 6, characterized in that a plurality of impedance gratings ( 2-5 ) are arranged one above the other. 8. Acoustic element according to claim 7, characterized in that a first, from membrane cover layer ( 9 ), middle layer ( 11 ) and membrane back layer ( 10 ) built up impedance grid represents the membrane cover layer of another, including angeord Neten impedance grid. 9. Acoustic element according to claim 7 or 8, characterized in that the Ab stood the membrane layer center and / or the diameter of the membrane layers of an impedance grid from the corresponding distance and / or through neighboring impedance grid is different. 10. Acoustic element according to claim 9, characterized in that the distance of the Membrane layer centers and the diameter of the menstrual layers of an Im in relation to an overlying impedance grid around the Factor increases by which the resonance frequency of the hollow partial surfaces decreases. 11. Acoustic element according to one of claims 1 to 10, characterized in that it has an upstream pinhole ( 6 ). 12. Acoustic element according to one of claims 1 to 11, characterized in that it can be set up freely in space and has at least one impedance grid ( 2-5 ) on all sides on its surface. 13. Acoustic element according to one of claims 1 to 11, characterized in that at least one impedance grating ( 2-5 ) is provided in a certain spatial configuration on the surface of the acoustic element ( 1 ) to a diffuse reflection in a desired To achieve direction.