DE3204014A1 - SOUND-absorbing building board - Google Patents

Description

32040H

Description;

The invention relates to a sound-absorbing building panel for lining interior walls, in particular on a ceiling plate, with a carrier layer made of a perforated carrier plate with over the entire surface of the Support plate distributed holes and sound-absorbing material lying on the support plate.

Sound-absorbing building boards are used where the acoustic conditions of a room are influenced should. The most widespread use is as a ceiling panel, although sound-absorbing wall panels are also used to be built in. Ceilings made of sound-absorbing building boards are also referred to as acoustic ceilings. If in the following When talking about acoustic ceilings, these statements also apply to acoustic wall cladding.

Sound-absorbing acoustic ceilings can be divided into two main types. The first main type becomes porous plate bodies used, e.g. chipboard or mineral fibreboard. These plates are sound-absorbing themselves and can without additional sound-absorbing devices to the Heron

an acoustic ceiling can be used. The panels are self-supporting and, due to their load-bearing capacity be made with relatively large dimensions. It is also known to use such sound-absorbing structures

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panels with a microporous film on their visible side as described in DE-PS 1,053,173.

In this package, the microporous film generally has not the task of improving the sound-absorbing properties of the carrier plate, but serves to achieve a other surface structure without impairment at the same time the sound-absorbing properties, as sound-absorbing panels do not always meet architectural requirements fully comply if there is no visible side coating is. By applying a microporous film which is provided with a .porous coating, the Plate can be made washable.

The second main type uses perforated carrier plates, made of both metal and non-metal Materials such as plaster of paris, wood, especially plywood or asbestos cement. These plates are not sound absorbing themselves. The sound absorption is achieved by a relatively thick layer of sound-absorbing Material, e.g. mats made of glass fibers or asbestos fibers, causes that to be placed on the back of the plate will. The sound-absorbing material can be cut to the size of the plate, or larger ones Mats are used that cover several panels. The sound waves penetrate the holes and are in the sound-absorbing material attenuated. The disadvantage of this type of acoustic ceiling is that the sound-absorbing material dirty over time and there is no possibility of cleaning. When removing individual ceiling panels the sound-absorbing material must also be removed, which often results in partial destruction of the material and the corresponding accumulation of dirt, especially when large mats cover several panels. Even without repair work, particles of the sound-absorbing material can fall out through the holes. A de-

contamination of sound-absorbing material behind the Is not possible. In the manufacture of acoustic ceilings, there is the disadvantage that the laying of the sound-absorbing material is associated with the development of dust, which soaps "can also be harmful to health," in particular when processing asbestos fiber material.

The disadvantages of the types of panels described are avoided with a building panel according to DE-OS 29 30 123. The there The construction panel described has a carrier layer made of a perforated sheet metal. The sound-absorbing layer is on the visible side of the sheet metal arranged and firmly connected to the sheet metal, the sound-absorbing Layer has a thickness of at most 5 mm. The sound-absorbing layer is only effective in the area of the holes. Since the total area of all holes is essential in each case is smaller than the total area of the plate, the sound-absorbing layer is only partially used.

The invention is based on the object of designing a sound-absorbing building panel of the type mentioned at the outset in such a way that that with a minimum of sound-absorbing material a maximum of sound-absorbing effect is achieved.

This object is achieved according to the invention in that the holes are filled over at least part of their length with sound-absorbing material that is attached to the carrier plate connected is.

In the building board according to the invention there is sound-absorbing Material essentially only where it is acoustically effective, namely in the holes in the carrier plate. The sound-absorbing material contained in the holes is fully used for sound absorption, see above that the desired soundproofing effect is achieved with a minimum of sound-absorbing material. Filling out the holes also has the advantage that the ceiling panels are dust-tight, so that they can clear the space below the building

protect plates from dust. The sound-absorbing one Material has a good hold inside the holes.

Sound-absorbing material according to claim 2 is particularly advantageous. Such material can be used in the Make holes and solidify afterwards. There may be a thin layer on the back of the build plate, which consists of the same material as the hole filling and the. is related to the hole filling (claim 3) .-. A thin layer on the back makes it easier filling in the holes, as it is possible to coat the entire back with sound-absorbing material and from this layer the holes are filled. But it is also possible to prefabricate a film, the knobs has die.die.die same arrangement as the holes in the metal sheet, and a prefabricated film on the carrier plate to apply and to connect firmly to this.

A visible side layer is preferably arranged on the front side of the carrier plate (claim 4). Such a layer has the advantage that the hole pattern on the visible side is invisible and can therefore be used to meet any architectural requirement. The visible side layer can in turn consist of the same material as the hole filling and is then thin from the point of view that sound-absorbing material which is not arranged in the area of the holes has no acoustic effect anyway. The visible side layer can, however, also consist of a different material than the Lpchausfüll (claim 6). For example, an acoustically transparent film may be used (claim 7) or the visible side layer may be made of an applied mass, Q ^ _{9 9} eipem lacquer or a filler made.

A protective layer made of a different material than the hole filling can be arranged on the rear side (Claim 9). Such a protective layer can e.g.

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Serve corrosion protection.

The acoustic flow resistance advantageously increases from the front to the rear (claim 10). this can be achieved, for example, by using layers with different resistances (claims 11 and 12). An acoustic resistance increasing from front to back has the advantage that the absorption properties the plate can be improved.

The carrier plate can consist of any material that gives the building board a sufficiently high overall strength. Sheet metal is well suited (claim 13). Thicknesses as specified in claim 14 come into consideration for this purpose. The carrier plate can, however, also consist of non-metallic materials (claim 15), in which case larger Thicknesses than come into question when using sheet metal, namely thicknesses as specified in claim 16. Even a relatively thin sheet of metal provides a sufficiently thick layer of sound absorbing material within each Loches. In the case of thicker carrier plates, i.e. in particular

Chen, which consist of non-metallic materials, it is also possible that the holes only over a part their length are filled with sound-absorbing material.

Areas for the acoustic flow resistance of the sound absorbing Materials are specified in claims 17 and 18. On the concept of acoustic flow resistance reference is made to DIN sheet 52 213 from December 1958. The required flow resistance can be achieved in various ways. With a thick layer made of sound-absorbing material, such as can be used, for example, for carrier plates made of non-metallic material, a sound-absorbing material of relatively high specific permeability can be selected, in which case the desired acoustic flow resistance is created by a greater layer thickness. If a thinner Carrier plate is used, one will usually be one

Use sound-absorbing material which, in relation to its thickness, has a greater flow resistance.

The invention is further explained below with reference to the drawing. Show it:

Fig. 1 is a perspective bottom view of an acoustic ceiling, are used in the building boards according to the invention,

Fig. 2 is a perspective view of a single building panel which is pyramid-shaped is,

3 is a perspective view of a plane Building board,

Fig. 4 shows a partial section through the plate according to Fig. 3 corresponding to the line IV-IV in Fig. 3 in one "Enlarged scale,

Fig. 5 is a partial plan view of a plate according to the arrow V in Fig. 4,

6 shows a section through the edge region of the plate according to Fig. 3 according to the line VI-VI in Fig. 3 on an enlarged scale,

7 shows a vertical partial section through a building board according to a further embodiment the invention,

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8 shows a partial section through a building board in an embodiment in which the building board has a coating does not have,

9 shows a partial section through a building board, in which, in addition to filling the hole, the rear side of the

Plate is coated and

Fig.10 is a partial section through a building board at a Embodiment, at the front and back are coated.

The ceiling construction according to Fig. 1 has as a support device for ceiling panels 1, a system of strip grid profiles 2 and 3 arranged at right angles to one another. With these strip grid profiles square fields are formed which are filled by the ceiling panels 1. The plate shown has a square plan shape and is profiled so that it has a four-sided pyramid with the inclined surfaces 4 to 7 (see also Fig. 2). The surfaces 4 to 7 abut one another at edges 8 to 11. At the edges the plate has upward-facing folds 12.

The shape of the plate can be any. In Fig. 3, a flat plate 13 is shown, which also has a has a square plan shape and folded edges 14, two diagonals extend over the plate Beads 15 and 16, which serve to stiffen the plate, but are covered from the visible side. The invention is not concerned with the basic shape of the plates described, but with their structure, which is to be described below with reference to FIG.

The plate 13 (correspondingly also the plate 1 according to Fig. 2)

has, it is assumed in the exemplary embodiments discussed with reference to the drawing, a carrier layer 17 in the form of a perforated sheet metal. The perforated plate 17 is pierced by many holes 20, the arrangement of which can be seen in FIG. Fig. 5 shows that the holes 20 are evenly distributed. The pattern of distribution may differ from FIG. 5. The hole arrangement and the hole size can vary within wide limits. The hole proportions, ie the total area of all holes, can be in the range from 4% to 40% of the total area of the plate. The thickness S _{1 of} the sheet depends on the material of the sheet, the percentage of holes and the overall size of the plate. A common thickness when using sheet steel is 1 mm.

The holes 20 are made of a sound-absorbing material

21 completed. There is a layer on the front

22 made of the same material with which the holes were filled are. The thickness of this layer is small. One This is because only those parts of the layer 22 which lie within the edges of the holes 20 have a sound-absorbing effect. The thickness s_ can be, for example, 0.5 mm.

The sound-absorbing material 21 and the layer 22 can be designed in accordance with DE-PS 1 053 173, i.e. it can be a preferably non-flammable fiber carrier, e.g. in the form of fleece or fabric, which is mixed with a mixture of substances that forms open micropores when it hardens is.

In the manufacture of the plate, the procedure is preferably such that the beads 15, 16 are attached first. The beads extend upwards, so that on the visible side formed by the layer 22 there are no protrusions.

are in hand. Then the sound-absorbing material is applied to the plate in a still malleable state. Here so much material is given up that all holes 20 are filled and then a remainder for the formation the layer 22 remains. After the sound-absorbing material has hardened, the folded edges 14 are produced. Then the plate can be painted on its visible side (bottom in Fig. 4).

Through the thin layer 22 despite the beads 15 is a smooth outer surface formed. The cavity 15 "that the bead forms on the underside of the sheet metal plate 17 is filled by the sound-absorbing material and is accordingly not visible.

Figures 4, 6 and 7 are versus full size enlarged approximately on a scale of 5: 1. Fig. 6 shows the area the edge fold 14. At this edge fold there is a bend 21 of 90 °. A tearing open of the layer 22 in the area of the bend is avoided if you either make the bend before applying the layer or the Layer only then solidifies (after it has already been Turn has been applied) when the turn is made.

FIG. 7 shows a partial section through an overall number 23 designated plate, which consists of two or more sheets 24 and 25 is composed. The sheets 24 and 25 have folded edges 24a and 25a which are connected to each other, e.g. by spot welding. The joint at the bottom Here, too, 26 is filled with sound-absorbing material 22 and is accordingly not visible.

The plate according to FIG. 8 is designated by 27 as a whole. This plate also has a carrier 28 in the form of a perforated

ten sheet. However, there is no surface coating, i. E. only the holes 29 are filled with sound-absorbing material 30. This embodiment is suitable when the requirement is not made that the hole pattern should be invisible on the visible side of the plate. The sound-absorbing one The effect is very good, since only the sound-absorbing material is involved in the sound absorption which is located in the area of the holes.

The plate 31 according to FIG. 9 in turn has a support 32 in Form of a perforated sheet. In this plate, the holes 33 are filled with sound-absorbing material 34. On the back of the plate 31 there is a thin layer 35, which can consist of the same material 34, with which the holes 33 are filled. This embodiment is inexpensive to manufacture. The production can take place in that on the back of the metal sheet 32 a certain excess of material is poured, so that a complete filling of the holes 33 is guaranteed and the layer 35 is formed from the excess material.

The plate 36 according to FIG. 10 also has a carrier 37 in the form of a perforated metal sheet. The holes 38 are filled with sound-absorbing material 39. This material 39 forms a thin layer 40 on the rear side, as in the embodiment according to FIG. 9. On the visible side (Front) of the plate 36 is a further layer 41, which consists of a different material as the hole filling · For example, the layer 41 can be formed by a lacquer.

Versions in which a visible side layer are also possible and a back layer of another

Material exist as the material with which the holes are filled. It is advantageous that the visible side layer has a relatively small acoustic flow resistance, the hole filling a larger one acoustic flow resistance and the back layer has an even greater acoustic flow resistance. This brings the advantage mentioned in the introduction to the description.

A visible side layer can be acoustically completely transparent, so only have the task of the visible side to give the look you want. The sound attenuation then takes place exclusively above this layer, mainly in the material that fills the holes in the sheet metal. An acoustically transparent material is e.g. a plastic film with a small thickness, for example with a thickness of 0.02 mm or less.

Claims (18)

Sound-absorbing building board requirements 1.Sound-absorbing building board for cladding room walls, in particular ceiling plate, with a carrier layer from a perforated carrier plate with over the entire Surface of the carrier plate distributed holes and on the carrier plate adjacent sound-absorbing material, characterized in that the holes (20; 29; 33; 38) over at least part of their length with sound-absorbing material (21; 30; 34; 39) are filled with the support plate connected is. 2. Building board according to claim 1, characterized in that the hole filling (21; 30; 34; 39) made of a material introduced into the holes (20; 29; 33; 38) in the formless state (21; 30; 34; 39) consists, e.g. of organic odep? a ^ P.r-pyriic fibers, produced by a commercially available organic or inorganic binder, e.g. carbamide resin or water glass, is bound. 3. Building board according to one of the preceding claims, characterized in that on the rear side of the building board (31; 36) a layer (35; 40) is arranged, 'which consists of the consists of the same material as the hole filling (34; 39) and which is related to the hole filling. 4. Building board according to one of the preceding claims, characterized in that on the front side of the carrier plate (17; 25, 26; 36) a visible side layer (22; 41) is arranged. 5. Building board according to claim 4, characterized in that the visible side layer (22) consists of the same material like the hole filling (21) and is related to the hole filling, the visible side layer (22) preferably is thinner than the carrier plate (17; 24, 25), e.g. has a thickness of 1 mm. 6. Building board according to claim 4, characterized in that the visible side layer (41) consists of a different material than the hole filling (39) (FIG. 10). 7. Building board according to claim 6, characterized in that the visible side layer consists of an acoustically transparent Foil, e.g. a plastic film with a thickness of at most 0.02 mm. 8. Building board according to claim 6, characterized in that the visible side layer (41) consists of an in the formless state applied mass, e.g. a lacquer or a filler. 9. Building board according to one of claims 1, 2 and 4 to 8, characterized in that on the back of the building board a protective layer is arranged, which preferably consists of a mass applied in the formless state, for example a Varnish or a filler. 10. Building board according to one of the preceding claims, characterized in that the acoustic flow resistance 320A0H stood increasing from the front to the back. 11. Building board according to claim 10, characterized in that that the visible side layer (41) has a smaller acoustic flow resistance than the hole filling. 12. .Building panel according to one of claims 10 and 11, characterized characterized in that the back layer has a larger one Has flow resistance than the hole filling. . 13. Building board according to one of the preceding claims, characterized in that the carrier plate is a metal sheet is. 14. Building board according to claim 13, characterized in that the metal sheet (17; 28; 32; 37) has a thickness (S ₁ ) between 0.4 mm and 2 mm, preferably of about 1 mm. 15. A panel according to any one of claims 1 to 12, characterized _r that the carrier plate consists of a non-metallic material, for example plaster, plasterboard, fiber material or plastic. 16. Building board according to claim 15, characterized in that the carrier plate has a thickness between 5 mm and 20 mm preferably of about 12 mm. 17. Building board according to one of the preceding claims, characterized in that the flow resistance of the sound-absorbing material is in the range of 300 Ns / m ³ to 3,000 Ns / m ³ , 18. Building board according to claim 17, characterized in that the flow resistance of the sound-absorbing material is in the range of 300 Ns / m ³ to 1,200 Ns / m ³ .