DE202014102942U1 - acoustic absorber - Google Patents

Abstract

An acoustic material and a visible side having acoustic absorber (1) for arrangement in a building space, for example, for attachment, optionally in suspended form, on a building ceiling (2), wherein as acoustic material (4) a nonwoven layer (5, 6, 7) is provided, characterized in that the acoustic material (4) consists of two layered superimposed nonwoven layers (5, 6, 7) of different types, a visual side forming the first nonwoven layer (5) and a second nonwoven layer (7), wherein a thickness (D) of second nonwoven layer (7) corresponds to three times or more the thickness (d) of the first nonwoven layer (5) and wherein both nonwoven layers (5, 7) are based on PET fibers.

Description

The invention relates to an acoustic material and a visible side having acoustic absorber for arrangement in a building room, for example, for attachment, optionally in suspended form, on a building ceiling, being provided as the acoustic material, a nonwoven layer.

Such acoustic absorbers are also referred to as ceiling sails. They have already become known in various ways. It will be around on the EP 1918472 A1 and the EP 1918654 A2 directed.

Acoustic absorbers of this kind must meet a variety of requirements. In addition to a high sound absorption and compliance with other building technical requirements is required.

Proceeding from this, the invention is concerned with the task of specifying an acoustic absorber, for mounting in a building room, which also satisfies other building technical requirements with good sound absorption.

A possible solution of the problem is given in a first inventive concept in an acoustic absorber, in which the acoustic material consists of two layered superimposed nonwoven layers of different types, forming the visible side first nonwoven layer and a second nonwoven layer, wherein a thickness of the second nonwoven layer a triple or more the thickness of the first nonwoven layer corresponds and wherein both nonwoven layers are based on PET fibers.

Because both fleece layers are based on PET fibers, a high fire protection factor can be achieved. The different thicknesses of the nonwoven layers can also achieve a favorable intrinsic stability of the nonwoven layers combined in this way. The result is a stability-promoting sandwich structure. The nonwoven layers can basically be set free, for example in a frame of the acoustic absorber. The fact that it is nonwoven layers, an open-pored material is given in both cases, which is favorable in itself but also in a multi-layer arrangement in terms of the desired sound absorption.

Due to the fact that the nonwoven layers are based on PET, it is also possible to advantageously achieve a desired type purity.

The basing of a nonwoven layer on PET fibers (polyethylene terephthalate fibers) is given in particular when a nonwoven layer to 50 percent or more, even up to 100 percent, PET fibers. In the case that the proportion does not reach 100 percent, in particular also copolymers, for example concerning PA fibers, may be contained.

Further features of the invention are described below, also in the figure description and the drawing, often in their preferred assignment to the already explained concept or illustrated. However, they can also be of importance in an assignment to only one or more individual features that are described here or represented graphically, or independently or in a different overall concept.

Thus, it is preferred that the nonwoven layers are laminated together. Masking together means that no separate adhesive is intended for connection. Rather, the compound, corresponding to about a bond, achieved by sufficient heating of one or both of the nonwoven layers, namely such that thermoplastic components of the nonwoven layer (PET is a thermoplastic) to a sticky state and thus heat in the facing surface areas of each other connecting nonwoven layers can achieve a solid, glue-like connection. A heating in this regard may also be made specifically only in one area or in relation to a thin (upper) layer. Since at the same time, however, the connection is given only according to individual fibers, it is also ensured that there is no noticeable limiting of the acoustic properties of the adhesive layer.

On the second nonwoven layer may be arranged a third nonwoven layer. It is understood that the layers, with respect to an installed state, are arranged one above the other in the vertical direction with respect to a parallel alignment with respect to a ceiling or transversely to the prevailing gravitational force and preferably each extend essentially horizontally. They lie directly flat on each other.

A possibly provided third nonwoven layer is preferably provided based on PET fibers.

It is further preferred that the first nonwoven layer and the second nonwoven layer have basis weights which differ by 10 percent or more. The basis weight of the second nonwoven layer is in this case 10 percent or more higher than that of the first nonwoven layer. Preferably, the third nonwoven layer may have a basis weight corresponding to the first nonwoven layer.

The mentioned difference in basis weights can go up to 10 times. A possible bandwidth for a basis weight of the first nonwoven layer is 50 g / m ² to 500 g / m ² . A possible Bandwidth for a basis weight of the second nonwoven layer is 400 g / m ² to 3,000 g / m ² . The initial thickness, before compression, is 2 to 8 mm with respect to the first nonwoven layer and 50 to 400 mm with respect to the second nonwoven layer.

The first nonwoven layer can also be a knitted fabric or a structured nonwoven fabric. Here, too, the PET base is retained.

The second nonwoven layer also preferably consists of a volume nonwoven (Bauschvlies).

The interconnected, as described preferably laminated together nonwoven layers are or are then subjected to a densification step. In this case, the first nonwoven layer can assume a thickness, transversely to its surface extent, which is very small compared to the second nonwoven layer, corresponds to one tenth or less of the thickness of the second nonwoven layer. In absolute terms, the second nonwoven layer may have a thickness of 10 to 50 mm, preferably 20 to 40 mm, whereas the first nonwoven layer has a thickness of 0.1 to 2 mm.

The densification of the nonwoven layers and / or the composite achieved by the lamination results in a comparatively very small deflection of the deflection which results within a frame opening (visible side). This relates to a suspension of such an acoustic absorber with perpendicular to the prevailing gravity extending layers. With a free stretched length of 3,000 mm and a free width of 1,250 mm, a deflection of only 5 to 20 mm, preferably 17, 16, 15, 14 or 13 mm, preferably results in the center of the area. This deflection can be measured according to the so-called TAIM procedure. This is the "Technical Manual Metal Ceilings" of the Technical Working Group Industrial Metal Ceiling Manufacturer eV Special reference is made to the November 2003 edition and there especially the execution "test method Dimensional accuracy and slack in metal long-field plates and metal cassettes", which is also applied here to free-spun nonwoven layers. According to local comments under "Panel slack between two DIN rails" a measuring point in the middle between two DIN rails is selected, being selected as the first measuring point, the center of the DIN rail cross-section (in the horizontal direction - in relation to the described suspension - considered perpendicular to gravity) and as a second measuring point the said measuring point in the middle between the mounting rails (with respect to the frame considered here, the center between two mutually opposite running sides of the frame is to take). The sag is then the difference of the absolute height dimension taken in said center to the height dimension taken on the support rail cross-section.

The first nonwoven layer can also achieve a favorable degree of light reflection due to the compression and the selected material. The compression is in particular made so that the degree of light reflection, determined by ISO 2813 , between 50 and 98%. Preferably, it is in the range of 75 to 90%.

The lowermost nonwoven layer, which preferably forms the visible side, can also be structured. This can be achieved in the course of compaction by a roller, between which the nonwoven layers are passed for compaction, is correspondingly surface-structured. The structuring may in this case be such that the lowermost nonwoven layer has a smaller thickness than corresponds to the structure, that is to say with respect to a lower imaginary plane which still touches the nonwoven layer with regard to back deviations from this plane.

With regard to the disclosure, the ranges or value ranges or multiple ranges given above and below also include all intermediate values, in particular in 1/10 increments of the respective dimension, if appropriate also without dimensions, ie if, for example, a thickness of 10 to 50 mm is specified this also a range of 11 to 50 mm, 10 to 49 mm, 11 to 49 mm, etc., on the one hand to delimit the said range boundary from below and / or above, alternatively or additionally but also to the disclosure of one or more singular values a respective specified area.

The acoustic absorber described here, in addition to an application as a ceiling can also find an application as a partition. In this respect, the layers then extend perpendicularly in the direction of gravity. For example, hereby partitions can be formed in a large office or on a desk.

In particular, the ceiling sail can also be formed in combination with lighting elements. For this purpose, for example, on the EP 2 314 782 A2 directed.

In the following, the invention will be explained further with reference to the attached drawing, which, however, represents only exemplary embodiments. Hereby shows:

1 a schematic view of the arrangement of an acoustic absorber, associated with a ceiling of a building room; and

2 a cross-sectional view of the acoustic material with a layered structure.

Shown and described is an in 1 illustrated acoustic absorber 1 , the here as a so-called ceiling canopy of a building ceiling 2 is arranged assigned. He is from the building ceiling 2 suspended, for example, at a distance of 10 to 100 cm (top) to the building ceiling 2 arranged.

The acoustic absorber 1 has outside a surrounding frame 3 on. It may, for example, be an aluminum frame. This aluminum frame may further detail, for example, a C-shaped profile, with an opening inwards, or an L-shaped profile, with the horizontal portion of the Ls - based on the in 1 illustrated suspension state - arranged below. In the C-space or lying on the L-section of the L-profile, the acoustic material 4 , please refer 2 be supported or restrained.

The acoustic material 4 consists in the embodiment of a first nonwoven layer 5 , a second nonwoven layer 6 and a third nonwoven layer 7 ,

The fleece layers 5 . 6 . 7 are arranged one above the other in the horizontal direction. They are firmly connected, namely laminated.

All fleece layers 5 . 6 . 7 are PET based. They consist of at least 50 percent or more of PET fibers.

While the first fleece layer 5 and the second nonwoven layer 7 have a comparatively very small thickness d, has the third nonwoven layer 6 a large thickness D on.

The first or second nonwoven layer 5 . 7 also points to the third nonwoven layer 6 a different basis weight. The basis weight of the third nonwoven layer 6 may be 10 percent or more greater than the basis weight of the first nonwoven layer 5 or second nonwoven layer 7 ,

The first fleece layer 5 or second nonwoven layer 7 can in principle be made of the same nonwoven layer as the third nonwoven layer 6 , namely from a volume fleece. This volume fleece is compressed, although with respect to the volume fleece then for the said different nonwoven layers different basis weights, as preferred, are used to achieve this illustrated and described smaller thickness d.

LIST OF REFERENCE NUMBERS

1

 acoustic absorber

2

 building ceiling

3

 frame

4

 acoustic material

5

 nonwoven layer

6

 nonwoven layer

7

 nonwoven layer

d

 thickness

D

 thickness

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1918472 A1 [0002]
• EP 1918654 A2 [0002]
• EP 2314782 A2 [0023]

Cited non-patent literature

• "Technical Manual Metal Ceilings" of the Technical Working Group Industrial Metal Ceiling Manufacturer eV Special reference is made to the November 2003 edition [0018]
• ISO 2813 [0019]

Claims (9)

An acoustic material and a visible side having acoustic absorbers ( 1 ) for placement in a building space, for example for attachment, optionally in suspended form, on a building ceiling ( 2 ), being used as acoustic material ( 4 ) a nonwoven layer ( 5 . 6 . 7 ), characterized in that the acoustic material ( 4 ) of two layer-like superimposed nonwoven layers ( 5 . 6 . 7 ) of different kind, a visual side forming the first nonwoven layer ( 5 ) and a second nonwoven layer ( 7 ), wherein a thickness (D) of the second nonwoven layer ( 7 ) three times or more the thickness (d) of the first nonwoven layer ( 5 ) and wherein both nonwoven layers ( 5 . 7 ) based on PET fibers. An acoustic absorber according to claim 1, characterized in that on the second nonwoven layers ( 7 ) a third nonwoven layer ( 6 ) is arranged. Acoustic absorber according to one of the preceding claims, characterized in that the nonwoven layers ( 5 . 6 . 7 ) are laminated together. Acoustic absorber according to one of claims 2 or 3, characterized in that the third nonwoven layer ( 6 ) is provided based on PET fibers. Acoustic absorber according to one of the preceding claims, characterized in that the first nonwoven layer ( 5 ) and the second nonwoven layer have basis weights that differ by 10 percent or more. Acoustic absorber according to one of the preceding claims, characterized in that all nonwoven layers are provided based on PET fibers. Acoustic absorber according to one of the preceding claims, characterized in that one or more nonwoven layers are compressed. Acoustic absorber according to one of the preceding claims, characterized in that the second nonwoven layer ( 7 ) consists of a volume fleece. Acoustic absorber according to one of the preceding claims, characterized in that the first nonwoven layer ( 5 ) consists of a compressed volume fleece.

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