UA89533C2 - Layered sound absorptive non-woven fabric - Google Patents

Abstract

The invention relates to the layered sound absorptive non-woven fabric containing the resonance membrane and at least one another layer (1,3) of the fibrous material at which the resonance membrane is created by a layer (2) of nanofibres having diameter to 600 nanometers and of surface weight 0,1 to 5 g/m, at the same time the resonance membrane together with at least one layer (1, 3) of fibrous material is formed by cross laying to the required thickness and surface weight.

Description

damping of the vibrating membrane, while the maximum amount of sound energy collected in the resonator is converted into heat. Layer 1 and/or C of the carded fiber web not only provides a sufficient level of damping of the vibrating membrane created by layer 2 of nanofibers, but also absorbs higher frequency sounds. Layers 1, 2, and 3 are linked into one resonant system by superimposing individual layers 1, 2, and C by connecting them, for example, in a chamber with a high-temperature regime. When resonating elements are applied, a material is created that, thanks to the resonant membrane created by layer 2 of nanofibers, absorbs low-frequency sound, and high-frequency sound is absorbed by layers 1 and/or from fibrous card material. The fabric according to the invention has high coefficient of absorption of both low and high frequency sounds, while it is possible to adapt the thickness and specific weight of the material to different needs.

Specific examples of sound-absorbing material according to this invention are given below.

Example 1

The sound-absorbing material contains 1 layer of carded fibrous web with a specific weight of 11,100g/m2, produced on a carding machine for bicomponent fiber of the coated type, consisting of a polyester core and a copolyester coating with a thickness of 5.3 (Fieh. On this layer 1 of fibrous web by electrostatic layer 2 of nanofibers with a specific weight of 2g/m² is applied to the formation. A layer of carded fibrous web is applied to the two layers 1 and 2 prepared in this way from the side of nanofiber layer 2. Then the base material is created according to Fig. 2 and is accordingly formed by cross-lamination into a sound-absorbing material with a total thickness of 25 mm and a specific weight of 630 g/m7. The sound-absorbing material passes through a chamber with a high temperature regime at a circulating air temperature of 140"C, and thus the adjacent layers are interconnected. Such a sound-absorbing material can contain a layer of 2 nanofibers with a specific weight of 2g/m2 to 0.1g/m2.

Fig. 5 shows the dependence of the sound absorption coefficient on the sound frequency and the specific weight of layer 2 of nanofibers directly for the sound-absorbing material of example 1, while curve M1 expresses this dependence for layer 2 of nanofibers with a specific weight of 2g/m2, curve M2 for layer 2 of nanofibers with a specific weight of 1g /m?, the MMZ curve for layer 2 of nanofibers with a specific weight of 0.5g/m?, the MA curve for a layer of nanofibers with a specific weight of 0.3g/m? and curve M5 for layer 2 of nanofibers with a specific gravity of 0.1 g/m2. Curve P shows this dependence for a material with only one layer of carded fibrous web, i.e. without using layer 2 of nanofibers. From the characteristics of individual curves, you can choose the composition of the sound-absorbing material according to actual needs.

Example 2

The sound-absorbing material of Fig. 1 contains layer 1 of a carded fibrous web with a specific weight of 11 g/me, produced on a carded machine for a bicomponent fiber of the coated type, consisting of a polyester core and a copolyester coating with a thickness of 5.3 "ex. Layer 2 of nanofibers with a specific weight of 2 to 0.1 g/m2 is applied to layer 1 of the fibrous web by electrostatic forming, using the method from example 1. The material of the two layers 1 and 2 is then formed by cross-laminating into a sound-absorbing material with a total thickness of 33-5 mm and a specific weight of 630 g /m7, after which they are exposed to heat from example 1, which connects adjacent layers.

The dependence of the sound absorption coefficient of this frequency and the specific weight of layer 2 of nanofibers directly for the material according to example 2 is shown in Fig. b6, while curve 93 expresses this dependence for layer 2 of nanofibers with a specific weight of 0.5 g/me, curve 44 for layer 2 of nanofibers with a specific with a weight of 0.3 g/m, and curve 95 for layer 2 of nanofibers with a specific weight of 0.1 g/m2.

Example C

The sound-absorbing material is prepared according to example 1, while the layer 2 of nanofibers with a specific weight of 2 to 0.1 g/m" is applied by electrostatic formation to the main layer of carded fibrous web. The two layers 1. and 2, prepared in this way, are applied a layer of combed fibrous web from the side of layer 2. After that, the material is formed according to Fig. 2, thus formed by cross-overlapping sound-absorbing material with a total thickness of 35 mm and a specific weight of 630 g/m, after which it is subjected to thermal influence from example 1.

The dependence of the sound absorption coefficient on the frequency and specific gravity of the layer 2 of nanofibers for the sound-absorbing material according to example C is shown in Fig. 7, while the curve M! expresses this dependence for layer 2 of nanofibers with a specific weight of 2g/m?7, curve M2 for layer 2 of nanofibers with a specific weight of 1g/m2, curve MZ for layer 2 of nanofibers with a specific weight of 0.5g/m2, curve MA for layer 2 of nanofibers with a specific weight of 0 ,3g/m:2 and curve M5 for layer 2 of nanofibers with specific 0.1g/m7. Curve P expresses this dependence for a fabric containing only a layer of carded fibrous web, i.e. without using layer 2 of nanofibers.

Example 4

The sound-absorbing material is prepared according to example 1, while the layer 2 of nanofibers with a specific gravity of 2 to 0.1 g/m2 is applied by electrostatic formation to the main layer of carded fibrous web. On the two layers 1. and 2 prepared in this way, two layers of card-combed fibrous web are applied from the side of layer 2 of nanofibers. After that, the material is formed according to Fig. 3, thus formed by cross-overlapping sound-absorbing material with a total thickness of 35mm and a specific weight of 63Z0g/ m, after which it is exposed to heat from example 1.

Fig. 8 shows the dependence of the sound absorption coefficient on the sound frequency and specific gravity of layer 2 of nanofibers directly for the sound-absorbing material of example 4, while curve PP1 expresses this dependence for layer 2 of nanofibers with a specific weight of 2g/m?, curve PP2 for layer 2 of nanofibers with specific weight 1g/m2, the RRZ curve for layer 2 of nanofibers with a specific weight of 0.5g/m2, the PPA curve for layer 2 of nanofibers with a specific weight of 0.Zg/m2, and the PRB5 curve for layer 2 of nanofibers with a specific weight of 0.1g/m2.

Example 5

The sound-absorbing material is prepared according to example 1, while layer 2 of nanofibers with a specific gravity from 2 to 0.1 g/m? applied by electrostatic molding on the base layer of carded fibrous web. On the two layers 1 and 2 prepared in this way, three layers of carded fibrous web are applied from the side of layer 2 of nanofibers. After that, the material is formed according to Fig. 4, the sound-absorbing material formed in this way by cross-overlapping has a total thickness of 35 mm and a specific weight of 630 g/m, after which it is subjected to heat from example 1.

Fig. 9 shows the dependence of the sound absorption coefficient on the sound frequency and the specific weight of the layer 2 of nanofibers directly for the sound-absorbing material of example 5, while the curve PPP2 expresses this dependence for the layer 2 of nanofibers with a specific weight of 1g/m2, the curve of PPPZ for the layer of 2 nanofibers with a specific weight of 0 ,5g/m2 and the RRPA curve for layer 2 of nanofibers with a specific gravity of 0.3Zg/m7.

Example 6

The sound-absorbing material is prepared according to example 1, while the layer 2 of nanofibers with a specific gravity of 2 to 0.1 g/m2 is applied by electrostatic formation to the main layer of carded fibrous web. On the two layers 1 and 2 prepared in this way, two layers of card-combed fibrous web are applied from the side of layer 2 of nanofibers. After that, the material is formed according to Fig. 3, the sound-absorbing material formed in this way by cross-overlapping has a total thickness of 35 mm and a specific weight of 450 g/m, after which it is subjected to heat from example 1.

Fig. 10 shows the dependence of the sound absorption coefficient on the sound frequency and the specific weight of the layer 2 nanofibers directly for the sound-absorbing material from example 6, while the curve PP1 expresses this dependence for the layer 2 nanofibers with a specific weight of 2 g/m, the curve PP2 for the layer 2 nanofibers with a specific weight 1g/m2, the curve of PPZ for layer 2 of nanofibers with a specific weight of 0.5g/m2, the curve of PPA for layer 2 of nanofibers with a specific weight of 0.3g/m:2 and the curve of RRB for layer 2 of nanofibers with a specific weight of 0.1g/m7.

Example 7

The sound-absorbing material is prepared according to example 1, while layer 2 of nanofibers with a specific gravity from 2 to 0.1 g/m? applied by electrostatic molding on the base layer of carded fibrous web. On the two layers 1 and 2 prepared in this way, three layers of card-combed fibrous web are applied from the side of layer 2 of nanofibers. After that, the material is formed according to Fig. 4, the sound-absorbing material with a total thickness of 35 mm and a specific weight of 450 g/m is formed by cross-laying in this way, after which it is subjected to heat from example 1.

Fig. 11 shows the dependence of the sound absorption coefficient on the sound frequency and the specific weight of the layer 2 of nanofibers directly for the sound-absorbing material of example 7, while the curve PPP1 expresses this dependence for the layer 2 of nanofibers with a specific weight of 2g/m? curve PPR2 for layer 2 of nanofibers with a specific weight of 1g/m, curve of PPRZ for layer 2 of nanofibers with a specific weight of 0.5g/m? and the PPRA curve for layer 2 of nanofibers with a specific gravity of 0.Zg/m.

The above examples of use are purely illustrative, and the invention also relates to multi-layered sound absorbing materials having layers of carded fiber web with a different specific gravity and/or formed from other layers of nanofibers, which have a different specific gravity and can be selected as needed. The invention is in no way limited to the described number of layers of sound-absorbing material. The shown dependences of the sound absorption coefficient on the sound frequency and the specific weight of the nanofiber prove, according to this invention, a high sound absorption capacity of the material, especially in the range from 500 to 60,000Hz, while the sound absorption coefficient ranges from 0.8 to approximately 1.

The invention can be used by manufacturers of sound-absorbing linings and components for the automotive, aviation, construction industry and industrial equipment, which, in comparison with currently known materials, shows much better results in terms of ensuring the hygiene of the surrounding environment from the point of view of unwanted and harmful sounds. them

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