DE19506120A1 - Ceramic or plastic noise absorption building block or tile - Google Patents

Abstract

Noise absorbing building block comprises a base (1) and a face plate (2) which together form an internal chamber (3) contg. a watertight noise absorbing element, acoustically connected to the face plate (2) the outer face of which is at least partially porous. The face plate (2) thickness is reduced in certain areas to less than 9 mm and noise transmission channels (6) are incorporated at these areas. The projected surface area of the channels (6) in the noise spreading direction is 20-40 % of the projected surface area of the reduced wall thickness areas. Also claimed is a building block with similar characteristics in which the noise absorber element is located inside the face plate (2).

Description

The invention relates to a decorative building block in the form of a brick or Hollow block that can selectively absorb sound waves and upscale decorative Meets requirements. Such building blocks are used in rooms with elevated Noise emission, such as in sports halls or swimming pools. You will also become a Sound absorption used in rooms to meet the special acoustic requirements such as concert halls, recording studios, conference rooms or in living areas with superior comfort.

Plate-shaped building materials made of wood materials, which are known as hollow chambers, are known are formed and the front surfaces have openings or perforations through which Sound waves unhindered on the sound arranged inside the cavity absorbing agents such as slag wool, glass or rock wool. By the If the sound waves penetrate into the absorber material, their energy becomes almost full constantly destroyed. The disadvantage of this solution is that parts of the insulation fibers Glass or rock wool through the openings or perforations into the room unhindered can penetrate. This creates for the people who are in this room a latent health hazard due to the released mineral dusts. On Another disadvantage is the high affinity of the wood materials used against water or water vapor. Hence, this solution comes in for application Wet rooms, such as indoor pools, are not considered. This solution is also not sufficient high aesthetic requirements, such as those of the above mentioned, acoustically designed rooms.

From RILÄNDER, N.M .: Lexicon of Acoustics, Erwin Brochinsky, Frankfurt am Main 1982, page 98, the use of film absorbers and their preferred Use in damp rooms or in rooms with special hygienic Requirements already known.  

An embodiment of the film absorber that is already on the market is being developed by German Rockwool GmbH in the arm of the "Hygiene-Baffeln" and the "ROCKFON-Baf feln "(see ROCKFON Baffle brochures, brochure no. 280/10 / ND of the German Rockwool, Gladbeck).

In a comparable manner, a brochure from Dämpa GmbH, Willich-Schiefbahn, January 1980, the use of imperforate polyethylene hoses wrote that are filled with a mineral wool insert.

Acoustic tiles from ERLUS-Baustoffwerke AG, Hockenheim are also known (Brochure from ERLUS-Baustoffwerke AG "ERLUS acoustic and noise protection system me "). These acoustic tiles in sandwich construction consist of a U-shaped Shell that gives the brick the necessary strength. On the open front surface of the A U-shaped bowl closes with a backdrop plate made of fired clay integrated oblique perforation. There is one between the backdrop and the U-shaped shell Insulation mat arranged with protective fleece. This protective tile that meanders the insulation pulled through, gives it the necessary strength and at the same time reduces that Breaking out of individual insulation articles from the composite. By using it Fired clay as a backdrop material has a high affinity for water and water vapor, so that it cannot be used in damp rooms.

It has also been shown that wide areas of the sound waves to be absorbed during Impact on the front surface of the acoustic tiles are reflected.

The object of the invention is to overcome the disadvantages of the known prior art eliminate and create a building block with a sound absorbing effect, the Sound waves in a wide frequency spectrum as completely absorbed as possible, high aesthetic requirements as a design element is sufficient and for use in Wet rooms is suitable. In addition, the module should be inexpensive to manufacture.

The task is in a generic block by the characterizing Features of claim 1 solved. An alternative design of sound absorbing the building blocks is set out in claim 2. Advantageously, the alternative solutions through the features of the subclaims.  

The block designed as a hollow body consists of a base body ( 1 ), which gives the block the required stability and strength and creates the connection with similar blocks to masonry or a drywall or wall cladding.

A head plate ( 2 ) arranged in front of it in the sound direction is connected to the base body ( 1 ). This head plate ( 2 ) has a wall thickness which is at least locally limited to 9 mm. In these areas with reduced wall thickness, sound-permeable channels ( 6 ) are arranged in a determined or stochastic distribution. The degree of perforation as a measure of the proportion of the surface of the channels ( 6 ) projected in the direction of sound propagation in relation to the surface ( 5 ) of the head plate ( 2 ) projected in the direction of sound propagation is 20 to 40%.

The optimal opening width (clear nominal width) of the sound-permeable ducts ( 6 ) is 2 to 10 mm. Smaller nominal diameters are difficult to control in terms of manufacturing technology when designing the top plate ( 2 ) made of ceramic or plastic. Larger nominal sizes influence the design options of the visible front surface of the head plate ( 2 ). An optimum for dimensioning the opening width of the sound-permeable channels ( 6 ) is around 6.0 mm.

Surprisingly, it was found that the passage behavior of sound waves in the middle frequency spectrum can be improved by a diffuse arrangement of the sound-permeable channels ( 6 ) in the wall thickness-reduced areas of the head plate ( 2 ). An asymmetrical, in particular stochastic, distribution of the sound-permeable channels ( 6 ) in the areas of the head plate ( 2 ) with reduced wall thickness results in better absorption behavior of the module than with an even distribution of the channels ( 6 ) (provided the same size and number of channels ( 6 )). At the same time, the arrangement of the channels ( 6 ) can be used as an architectural design element of the head plate ( 2 ).

Through the channels ( 6 ), the sound waves can strike the surface of the sound absorber ( 4 ) arranged behind them almost unhindered. The energy of the waves is almost completely destroyed. Depending on the area of application of the building block (absorption behavior, costs), a suitable material for the sound absorber ( 4 ) is selected. In order to minimize the overall wall thickness of the building block, the use of mineral wool or slag wool as a sound-absorbing material is advantageous. This material can be watertightly pressed or welded in metal or plastic films and loosely inserted or fixed in this pillow shape in the interior ( 3 ) of the module.

In the alternative embodiment according to claim 2, a base body ( 1 ) as a supporting element was dispensed with. The building block with sound-absorbing effect consists of a self-supporting, trough-shaped or bowl-shaped head plate ( 2 ), in the interior ( 3 ) of which a sound absorber ( 4 ) is arranged. Analogously to the solution according to claim 1, the sound absorber ( 4 ) is watertight and is acoustically conductively connected to the head plate ( 2 ). The surface ( 5 ) of the head plate ( 2 ) is at least partially porous and the wall thickness of the head plate ( 2 ) is at least locally reduced to <= 9 mm. In these areas, sound-permeable channels ( 6 ) are arranged in a determinate or stochastically distributed manner or in bundles. The proportion of the surface of the channels ( 6 ) projected in the direction of sound propagation in relation to the surface ( 5 ) of the head plate ( 2 ) projected in the direction of sound propagation in the regions reduced in wall thickness is 20 to 40%.

The sound absorber ( 4 ) is connected to the interior ( 3 ) of the head plate ( 2 ) by gluing or tying. With a corresponding design of the side walls of the interior ( 3 ), the preferably pillow-shaped sound absorber ( 4 ) can also be inserted in a form-fitting manner. In a cost-effective design, the sound absorber ( 4 ) can also be inserted loosely into the interior ( 3 ) of the head plate ( 2 ).

Due to the inherent rigidity of the head plate ( 2 ), the block can be placed directly on flat surfaces, e.g. B. be applied by contact adhesive.

It is also an assembly on superior, standing or hanging, free-swinging Grids, scaffolding or stands possible. The connection of the individual building blocks takes place with known assembly means.  

By arranging the blocks according to claim 2 on such superior cantilevered wall or ceiling facings can be particularly deep Frequent vibrations are absorbed, for example, from neighboring Rooms. Such an arrangement can preferably be used as a bend soft front shell works in concert halls or recording studios to prevent the transmission of structure-borne noise over the wall or ceiling surfaces.

In an alternative embodiment according to claim 1, the mineral wool or slag wool used can be loosely inserted into the base body ( 1 ). A thin-walled, acoustically conductive membrane film ( 7 ) made of metal or plastic, which surrounds the shell-shaped base body ( 1 ) which is open towards the interior ( 3 ), prevents the slag wool from escaping from the base body ( 1 ). On the base body ( 1 ), a head plate ( 2 ) according to the invention described above is applied.

In a further, alternative embodiment, the shell-shaped base body ( 1 ) and the head plate ( 2 ) are connected to one another by a circumferential, sealing joint connection. At the same time, the joint connection prevents loose mineral or slag wool from escaping, which is preferably used as a sound absorber ( 4 ). In order to prevent sound absorber particles from escaping through the channels ( 6 ) of the head plate ( 2 ), the preferably flat inner wall of the head plate ( 2 ) is sealed with an acoustically conductive membrane film ( 7 ).

The use of metal foils for the covering of the sound absorber ( 4 ) or its sealing against the head plate ( 2 ) offers the advantage that no toxic gases are released when fires break out, as is the case when plastic foils are burned or burned off.

The watertight separation of the sound absorber ( 4 ) completely prevents parts of the sound absorber material from escaping. The use of metal or polyethylene film also guarantees high long-term stability and service life of the sound-absorbing building block.

To absorb high-frequency sound waves, the surface ( 5 ) of the head plate ( 2 ) has a porous structure. The, at least in the near-surface zone of the head plate ( 2 ) arranged and interconnected pores cause z. B. by communicating an extinction of the energy of the impinging, higher-frequency sound waves (interference effect of the sound waves).

To those necessary for acoustic reasons the wall thickness reduction of the head plate (2) mechanically to master, the head plate (2) preferentially in a further training stiffeners (8), (8 b). These stiffeners ( 8 ), ( 8 b) can be designed as webs or continuous, local thickening of the head plate ( 2 ) and, depending on the aesthetic requirements, on the front or rear surface ( 5 ) of the head plate (seen in the direction of sound) ( 2 ) be trained.

Design aspects are preferably taken into account in the constructive design of the stiffeners ( 8 ), ( 8 b). So elements of reliefs or sculptures, which are arranged on the front of the surface ( 5 ) of the head plate ( 2 ), can be designed so that they mechanically connect the upper and lower edges of the head plate ( 2 ) and thus the function of a Take over pillar or stamp. In the same way, horizontally and vertically acting forces and moments can be safely absorbed by lattice-like arrangements of webs.

For aesthetic reasons, the visible surface ( 5 ) of the head plate ( 2 ) can be designed in one or more colors. For this purpose, pigments or dyes can be added to the construction material of the top plate ( 2 ). Subsequent spraying on of a thin color film using the air-brush method likewise enables the surface ( 5 ) of the head plate ( 2 ) to be colored without reducing the absorption capacity, in particular high-frequency tones.

The preferred use of ceramic materials for the formation of the head plate ( 2 ) offers optimal design options when using this environmentally friendly and fully recyclable material for manufacturing reasons.

To produce the porosity of the surface ( 5 ) of the head plate ( 2 ), the ceramic material can preferably be foamed. In an alternative, likewise preferred form, the ceramic front plate ( 2 ) can be thrown or sprayed with sand, small-sized ceramic particles or clay balls before firing. In the subsequent firing process, these elements are permanently connected to the surface ( 5 ) of the head plate ( 2 ) to form a porous layer.

In a likewise preferred embodiment, the base plate ( 1 ) is produced from waste from new plastic production or from recycled plastic by means of primary shaping or shaping. This makes it possible to recycle materials that are currently largely disposed of in special landfills. Since the base plate ( 1 ) is completely covered by the decorative head plate ( 2 ), the overall aesthetic impression of the block is not adversely affected. In addition, the use of plastic compared to ceramic materials for the base plate ( 2 ) significantly reduces the mass of the module and improves the ease of assembly.

In a further, not detailed further development, the base plate ( 1 ) has grooves and guide strips on the side surfaces, which enable a form-fitting connection of adjacent building blocks in wet or dry construction. By rotating the building blocks or the top plates ( 2 ) against each other by 90 °, 180 ° or 270 °, a greater variety of variants can be achieved in the acoustic and architectural design of rooms.

In another, preferred further development, a tangle is used as the absorber material Long-fiber chips from manufacturing waste used in the manufacture of Plastics or those made from recycled and reprocessed plastics be produced by cutting or cutting processes. This mess will be encased in a thin-walled metal or plastic film that is acoustically conductive and is waterproof.  

In a likewise preferred embodiment, the base body ( 1 ) and head plate ( 2 ) are made of polypropylene using the injection molding process. By foaming the poly propylene, the surface of the head plate ( 2 ) has a porous structure that absorbs impinging, high-frequency tones. A correspondingly porous surface can also be realized when using smooth plastic surfaces by applying plastic beads, which are applied to the surface ( 5 ) and, under the influence of temperature, melt with one another and with the surface ( 5 ) of the top plate ( 2 ) locally.

A porous surface ( 5 ) of the top plate ( 2 ) can also be created by applying gravel with an average grain size of approx. 5 mm. For this purpose, the gravel of appropriate grain size is wetted with a synthetic resin adhesive and then applied to the surface ( 5 ) of the head plate ( 2 ).

In another preferred embodiment, the base body ( 1 ) is made of plastic or ceramic in the form of a trough. The sound absorber material is loosely inserted into the trough-shaped cavity of the base body ( 1 ). Leakage of components of the sound-absorbing material and penetration of moisture into the sound-absorbing material is prevented by a membrane film ( 7 ), such as a thin-walled metal or plastic film, which surrounds the edge of the trough-shaped base body ( 1 ) in a watertight manner.

In a further, alternative embodiment, the shell-shaped base body ( 1 ) and the head plate ( 2 ) are connected to one another by a circumferential, sealing joint connection. At the same time, the joint connection prevents loose mineral or slag wool from escaping, which is preferably used as a sound absorber ( 4 ). In order to prevent sound absorber particles from escaping through the channels ( 6 ) of the head plate ( 2 ), the preferably flat inner wall of the head plate ( 2 ) is sealed with an acoustically conductive membrane film ( 7 ).

For design reasons, it is also advantageous to use a colored membrane film ( 7 ). The membrane film ( 7 ), which is partially visible through the sound-permeable channels ( 6 ), can thus be used as a design element in order to match the color design of the visible surface ( 5 ) of the head plate ( 2 ) with the colored membrane film ( 7 ) arranged behind it .

In the same way, it is advantageous if the visible surface ( 5 ) of the head plate ( 2 ) is colored. When using ceramic materials for the head plate ( 2 ), this can be done by throwing colored, ceramic granules, which binds to the surface of the head plate ( 2 ) in the subsequent firing process. At the same time, due to the diffuse coating with ceramic particles corresponding grain or nominal size on the surface ( 5 ) of the head plate ( 2 ) porous structures that serve to absorb the high-frequency sound waves.

It is also advantageous if the base body and head plate are made of ceramic material. The natural raw materials used for this can be provided without any problems and a brick made from it can later be disposed of in an environmentally friendly manner. In addition, ceramic materials offer a wide range of options for the individual and industrial design of the head plate ( 2 ).

Various types of flame-retardant plastics can also be used advantageously for the production of the base body ( 1 ) and the top plate ( 2 ). This makes it possible to make the building material extremely thin-walled and light. If necessary, additional beads or webs can be molded into the non-visible areas of the base body ( 1 ) and the invisible part of the head plate ( 2 ) facing the interior ( 3 ) in order to give the module the necessary inherent rigidity.

It is advantageous if recycled plastic residues or waste from the plastic production are used for the production of parts of the module. In particular, the base body ( 1 ) can be produced from plastics, some of which are of inferior quality, by known primary molding processes. Foreign inclusions, slight voids or other imperfections do not affect the overall aesthetic impression of the block, as the visible area is completely covered by the head plate ( 2 ).

It is also advantageous if long-fiber tangled chips are used as the sound absorber material Plastic are used, as they arise during machining. In order to these industrial wastes can be re-used commercially be fed.

For indoor wall and ceiling cladding, it is particularly advantageous if the building block is not only lightweight but also very compact. In particular, the wall thickness of the module consisting of the base body ( 1 ) and the head plate ( 2 ) placed in front of it should be as small as possible in order to minimize the loss of space due to the installation of acoustically designed wall or ceiling panels.

To achieve minimal dimensions, it is advantageous if mineral wool is used as the sound absorber ( 4 ), which has a comparatively good sound absorption capacity. As a rule, it is sufficient if an approximately 20 mm thick mineral wool layer is watertightly enclosed by an acoustically conductive, thin-walled membrane film ( 7 ) made of aluminum or polyethylene or an equivalent material with a wall thickness of <= 50 µm. This means that the entire thickness of the sound-absorbing building block can be reduced to approx. 30 mm.

The decorative building block with sound-absorbing effect is described in several below Described embodiments and shown in drawings.

Show it:

Figure 1 is a ceramic block in front view, top view and a sectional view.

Fig. 2 shows the block of Figure 1 in a spatial representation.

Fig. 3 is a block whose top plate and the base body are made of polypropylene, in an exploded view;

Fig. 4 is a block according to Fig 3 in a sectioned representation.

Fig. 5 is a block according to Figures 3 and 4, in a partial magnification.

Fig. 6 shows an alternative design of the head plate ( 2 ) of the module according to Fig. 3;

Fig. 7 shows an alternative design of the head plate (2) of the block of FIG. 3.

Fig. 1 and 2 show a ceramic block with a tile-like, quadra tables head plate (1).

The base body ( 1 ) is formed by a trough-shaped, ceramic shell. The pillow-shaped sound absorber ( 4 ) is inserted in this bowl. The sound absorber ( 4 ) consists of mineral wool, which is welded into a membrane film ( 7 ) made of polyethylene. Top plate ( 2 ) and base body ( 1 ) are connected to each other by a circumferential adhesive joint ( 10 ). The top plate ( 2 ) has a circumferential reinforcement ( 8 ) in the edge regions. This reinforcement ( 8 ) also forms the outer edge of the top plate ( 2 ). Adjacent building blocks butt against each other during assembly on these outer edges. Larger, coherent wall or ceiling surfaces can be designed acoustically and architecturally without any joints. An asymmetrical, arch-shaped stiffener ( 8 b) is molded in to absorb additional forces and moments.

The ceramic stiffeners ( 8 ), ( 8 b) on the visible surface ( 5 ) of the head plate ( 2 ) serve in addition to the safe absorption of forces and aesthetic design. The arrangement of the stiffeners ( 8 ), ( 8 b) on the head plate ( 2 ) is therefore determined by the forces and moments to be absorbed and by the architectural requirements. If necessary, the stiffeners ( 8 ) can only be arranged on the invisible rear side of the head plate ( 2 ) facing the interior ( 3 ) of the building block if, from an architectural point of view, the building block should not have any raised or strongly structured areas.

In the lower areas of the head plate ( 2 ), channels ( 6 ) are arranged in the form of irregular openings, which have an average width of 2 to 10 mm.

Fine-grained silicates with an average grain diameter of <= 3 mm are glued to one another and to the surface ( 5 ) of the head plate between the channels ( 6 ) and in the open areas of the head plate ( 2 ). The porous surface created in this way absorbs the high-frequency sound waves and at the same time gives the head plate ( 2 ) a warm character.

The membrane film ( 7 ) is colored and can thus be used as a contrast or complementary element for the front surface design of the surface ( 5 ) of the head plate ( 2 ).

FIGS. 3 to 5 show a block whose base body (1) and head plate are made of polypropylene (2).

Design modifications of the head plate ( 2 ) are shown in FIGS. 6 and 7.

A mineral wool cushion plate is inserted in the base body ( 1 ), which is watertightly sealed by a membrane film ( 7 ) made of aluminum.

In an alternative, not shown embodiment, a 20 mm thick, loose layer of mineral wool is inserted in the box-shaped base body ( 1 ) as sound absorber ( 4 ). A membrane film ( 7 ) made of polyethylene seals the mineral wool watertight against the side walls of the base body ( 1 ).

In a further, alternative embodiment, the shell-shaped base body ( 1 ) and the head plate ( 2 ) are connected to one another by a circumferential, sealing joint connection. At the same time, the joint connection prevents loose mineral or slag wool from escaping, which is preferably used as a sound absorber ( 4 ). In order to prevent sound absorber particles from escaping through the channels ( 6 ) of the head plate ( 2 ), the preferably flat inner wall of the head plate ( 2 ) is sealed with an acoustically conductive membrane film ( 7 ).

The head plate ( 2 ) is positively placed on the base body ( 1 ). The cohesion between head plate ( 2 ) and base body ( 1 ) is established by a snap-in connection. The outer side surfaces of the base body ( 1 ) have a circumferential groove ( 9 ). Adjacent blocks can be fixed in their position and connected to one another via this groove ( 9 ) and associated feather keys. This simplifies mounting on walls and ceilings.

The head plate ( 2 ) has on its visible surface ( 5 ) two horizontally and vertically extending braces ( 8 ), which are additionally supplemented by three arched braces ( 8 b). By means of these webs, the average wall thickness of the head plate ( 2 ) can be limited to 3.0 mm.

Sound-permeable channels ( 6 ) with a nominal width of 2.0 mm to 10.0 mm are stochastically distributed between the stiffeners ( 8 ), ( 8 b). The channels ( 6 ) are arranged in relation to one another according to acoustic and design aspects. Between the channels ( 6 ) and on the free surface ( 5 ) of the head plate ( 2 ), a granulate ( 11 ) made of plastic is arranged, which gives the plate sufficient porosity in these areas of the surface ( 5 ).

The base body ( 1 ), which is also made of plastic, is trough-shaped. A 25 mm thick fleece of mineral wool is inserted in the trough-shaped body ( 1 ). The protection of the acoustically designed room from emerging mineral wool fibers is realized by an aluminum foil that spans the side walls of the base body ( 1 ) in a form-fitting manner and that which includes mineral wool loosely inserted in the tub-shaped base body ( 1 ).

In a further, alternative embodiment, the shell-shaped base body ( 1 ) and the head plate ( 2 ) are connected to one another by a circumferential, sealing joint connection. At the same time, the joint connection prevents loose mineral or slag wool from escaping, which is preferably used as a sound absorber ( 4 ). In order to prevent sound absorber particles from escaping through the channels ( 6 ) of the head plate ( 2 ), the preferably flat inner wall of the head plate ( 2 ) is sealed with an acoustically conductive membrane film ( 7 ).

At the same time, the aluminum foil, which is preferably used as a membrane foil ( 7 ), prevents moisture from penetrating into the sound absorber ( 4 ), which would significantly reduce its absorption capacity. The aluminum foil is fixed by the head plate ( 2 ) placed on the protruding edge of the base body ( 1 ).

In the interest of extremely lightweight construction, the bottom of the trough-shaped base body ( 1 ) can be omitted. In this case, the mineral wool used as sound absorber ( 4 ) is pillow-shaped and is completely watertight sealed by a 50 µm aluminum foil. In order to give the base body ( 1 ) sufficient inherent rigidity despite the lack of floor, additional beads or stiffeners ( 8 ) are provided in the areas near the floor or on the side surfaces of the base body ( 1 ).

The head plate ( 2 ) is connected to the base body ( 1 ) by means of a form-fitting, latchable connection, which creates a releasable connection when the head plate ( 2 ) is pushed onto the base body ( 1 ). The assembly of the base body ( 1 ) on a wall or ceiling surface is facilitated in that the base body ( 1 ) has a circumferential groove ( 9 ). With the help of parallel keys, not shown, the adjacent base bodies ( 1 ) are locked together and fixed in their position. This considerably simplifies the assembly of the base body ( 1 ) on larger areas.

The detachable connection of the base body ( 1 ) and head plate ( 2 ) also enables disassembly and possible replacement of the head plates ( 2 ). In this way, leaky membrane films ( 7 ) can be replaced, if necessary, without having to remove all or part of the veneered wall or ceiling surface. Likewise, the decorative head plates ( 2 ) can be easily replaced in order to meet changed architectural requirements or to carry out an acoustic fine-tuning of the room.

An embodiment of the invention according to claim 2 consists of a head plate ( 2 ) made of polypropylene, as shown in FIGS. 3 to 5.

The trough-shaped head plates ( 2 ) have a 30 µm thick membrane film ( 7 ) made of aluminum in the interior ( 3 ), which is fixed to the inside of the head plate ( 2 ) by means of pressure-sensitive adhesive. A 30 mm thick mineral wool layer is inserted in the trough-shaped interior ( 3 ). The emergence of the mineral wool due to the missing rear wall of the head plate ( 2 ) is prevented by a second, 50 µm thick membrane film ( 7 ) made of aluminum, which spans the interior ( 3 ) and is glued all round to the side edges of the trough-shaped head plate ( 2 ) . A film-like pressure sensitive adhesive, which is applied to the back of the head plate ( 2 ), can be easily installed on appropriately prepared wall or ceiling surfaces.

Reference list

1 basic body
2 headstock
3 interior
4 sound absorbers
5 surface (of the head plate)
6 channel
7 membrane film
8 stiffening
9 groove
10 adhesive joints
11 granules

Claims (18)

1. block characterized by sound-absorbing effect ,
that a sound absorber ( 4 ) is arranged in the interior ( 3 ) of the module, which is formed by the base body ( 1 ) and head plate ( 2 ),
that the sound absorber ( 4 ) is watertight and acoustically conductively connected to the head plate ( 2 ),
that the surface ( 5 ) of the head plate ( 2 ) is at least partially porous,
that the wall thickness of the head plate ( 2 ) is at least locally reduced to <= 9 mm and that sound-permeable channels ( 6 ) are arranged in these areas,
that the proportion of the surface of the channels ( 6 ) projected in the direction of sound propagation in relation to the surface ( 5 ) of the head plate ( 2 ) projected in the direction of sound propagation is 20 to 40% in the regions reduced in wall thickness. 2. block characterized by sound-absorbing effect,
that a sound absorber ( 4 ) is arranged in the interior ( 3 ) of a head plate ( 2 ),
that the sound absorber ( 4 ) is watertight and acoustically conductively connected to the head plate ( 2 ),
that the surface ( 5 ) of the head plate ( 2 ) is at least partially porous,
that the wall thickness of the head plate ( 2 ) is at least locally reduced to <= 9 mm and that sound-permeable channels ( 6 ) are arranged in these areas,
that the proportion of the surface of the channels ( 6 ) projected in the direction of sound propagation in relation to the surface ( 5 ) of the head plate ( 2 ) projected in the direction of sound propagation is 20 to 40% in the regions reduced in wall thickness. 3. Module according to claim 1 or 2, characterized in that the sound-permeable channels ( 6 ) in the reduced wall thickness areas of the head plate ( 2 ) are arranged stochastically. 4. Module according to one of claims 1 to 3, characterized in that the average opening width of the sound-permeable channels ( 6 ) is 2 mm to 10 mm. 5. Module according to one of claims 1 to 4, characterized in that the sound absorber ( 4 ) with respect to the head plate ( 2 ) is sealed by a membrane film ( 7 ) made of metal or plastic. 6. Module according to claim 5, characterized in that the membrane film ( 7 ) consists of polyethylene. 7. Module according to claim 5 or 6, characterized in that the membrane film ( 7 ) is colored. 8. Module according to claim 1 or 2, characterized in that the head plate ( 2 ) between the sound-permeable channels ( 6 ) has stiffeners ( 8 ). 9. Module according to one of claims 1 to 8, characterized in that the local wall thickness reductions of the head plate ( 2 ) are designed as structured reliefs or as design elements in the visible area of the head plate ( 2 ). 10. Module according to one of claims 1 to 9, characterized in that the visible surface ( 5 ) of the head plate ( 2 ) is colored. 11. Block according to one of claims 1 to 10, characterized in that the head plate ( 2 ) consists of ceramic material. 12. Module according to one of claims 1 or 3 to 11, characterized in that the base body ( 1 ) consists of ceramic material. 13. Module according to one of claims 1 to 10, characterized in that the head plate ( 2 ) consists of plastic. 14. Module according to one of claims 1 or 3 to 11 or 13, characterized in that the base body ( 1 ) consists of plastic. 15. Module according to claim 14, characterized in that the base body ( 1 ) consists of waste plastic production or recycled plastic. 16. Block according to claim 13, characterized in that the top plate ( 2 ) or its surface ( 5 ) consists of foamed poly propylene. 17. Module according to one of claims 1 to 16, characterized in that the sound absorber ( 4 ) consists of long-fiber tangled chips from manufacturing residues that arise in the production of plastics or from recycled and reprocessed plastic, which consists of a thin-walled membrane film ( 7 ) made of metal or plastic are acoustically conductive and watertight. 18. Module according to one of claims 1 to 17, characterized in that the sound absorber ( 4 ) consists of mineral wool or slag wool, which is enclosed by a thin-walled membrane film ( 7 ) made of metal or plastic, acoustically conductive and waterproof.