DE19539309A1 - Noise insulation material which can be recycled easily - Google Patents

Abstract

Noise protection or insulation material consisting entirely of a secondary raw material and another material to be mixed with the first, having air noise and / or structure-borne noise insulation characteristics. Also claimed is a process to produce the above insulating material in which cellulose fibres are processed in a pulper (41), then digested in a refiner (42). The aqueous suspension from the refiner is then thickened in a thickener (43), and the second material fed via a screw conveyor (45) from a storage silo (44). The two streams are then mixed (46), and passed to forming (60), dewatering (61) and drying stages.

Description

The invention relates to a soundproofing or Soundproofing material, a building board made of it and a method its or its manufacture.

With the term sound insulation or sound insulation in the rest Senses must be between the so-called air and Structure-borne noise excitation can be distinguished. Is z. B. in one Airborne sound generated by speaking, then they can associated periodic fluctuations in air pressure walls and cause ceilings to vibrate, which in turn stimulate air particles to vibrate again. This Transmission process of sound is with airborne sound Transmission described. The measures to prevent this is called airborne sound insulation.

A distinction must be made between structure-borne noise excitation. Becomes e.g. B. knocked on a wall with a solid object, so this is put into bending vibrations, which again corresponding vibrations of air particles, so too Conduct airborne sound. In this case one speaks of one Structure-borne noise excitation of the wall.

According to this distinction between the two types of sound with regard to their acoustic effect sound-absorbing materials are differentiated into

• a.) porous sound absorbers
• b.) Resonance absorber.

In the first group all materials fall out have open pores or channels, e.g. B. textiles, Mineral wool, felts and wood fiber. A striking one Sound wave penetrates the fine with these materials Channels, with the oscillating air particles experience friction on the channel wall. It becomes part the vibrational energy is converted into thermal energy. The size the absorption depends on the thickness and the Flow resistance of the material, which is not too large and should not be too small. Generally one can say that  practically usable, sound absorbing cladding, if they are attached directly to the wall or ceiling, must be at least 1 cm thick. Sound-absorbing paints or sound-absorbing wallpapers are pretty ineffective for that reason. A special This material damping is important for components Gassed concrete, which has a 2-3 times higher material damping has like other building materials, e.g. B. brick, concrete and. a. Also for lightweight concrete using expanded clay are good Damping properties achievable.

The so-called resonance absorbers consist of a model a mass-spring system that is close to the Resonance frequency a pronounced sound absorption owns. The most important form in practice are here Panels, with air gap in front of a wall or ceiling, e.g. B. plywood, plasterboard or belt floors, being used to increase the absorption of fiber mats in the cavity be introduced. Often both types of Absorbing effects combine by creating porous Sound absorbers can be installed at a distance from the wall. Another important form of resonators are so-called volume resonators. The exist Vibration systems from volumes that have individual openings communicate with the room. The volumes represent the Suspensions that swing back and forth in the openings Air grafting represents the masses of the vibration systems a damping resistor is required, which consists of a The cavity can be filled with porous material.

There are currently a large number of sound insulation and Soundproofing materials, such as various foam materials, e.g. B. foamed polyurethanes, foamed polyethylenes or foamed polystyrene (made by the German company BASF offered and used under the trade name STYROPOR becomes) . Also known as soundproofing materials are mineral wool, mineral felt, glass wool, rock wool, Cork materials in different compositions, Wood fiber boards, wood wool lightweight boards, or pumice concrete.  

With the mentioned soundproofing or soundproofing materials it is generally a matter of more uniform substances Composition, or a combination of substances uniform composition, a so-called Composite system by special manufacturing processes get very special properties.

Take special foaming agents as an example foamed polyurethane mentioned, in which by the Foaming process the desired cavity structure and thus the sound-absorbing effect is achieved. The possibilities the reuse of used polyurethane Soundproofing materials are very limited. Recycling this Materials are only possible to a very limited extent. An attempt is made to recycle the recycled polyurethane material shred and with special binders or adhesives reassemble. The product achieved here is from inferior quality and for use as sound-absorbing Material no longer suitable. The use of these materials is essentially limited to the packaging industry.

For all, carried out with foamed polyurethane Reprocessing procedures must be followed very carefully be that the recycled polyurethane without contamination is present. Any impurities still adhering, such as for example paints, stickers, foils, glued on Papers, plaster or mortar residues, disturb the following Production processes significantly. And especially the one in the Building materials industry used soundproofing or are sound absorbing materials, in the case of repatriation for reprocessing, very dirty and therefore very bad for the existing recycling processes suitable. This fact limits the response rate of these Materials currently close to zero.

Another known method is Reprocessing of STYROPOR. But also with these Processes are only equipped with less strength Insulation boards created. The quality and purity of the  recycled STYROPORS are also very demanding posed.

In the case of fibrous materials such as mineral wool or glass wool currently no commercially usable processes for Reprocessing known. Only at Asbestos fiber products are disposed of, whereby the mineral asbestos fibers are dissolved in special acids will.

Recycling of wood or wood fiber products with the aim of Production of high quality materials is like this complex that an economic assessment is a Commercialization of these processes has so far been prevented.

The also for sound absorbing or sound absorbing Cork products used are only limited for one purpose Suitable for reprocessing. Here, only with less Strength equipped insulation boards produced.

Most of the materials mentioned above are only one limited number of reprocessing cycles possible. The Quality of the materials produced, or those for Generating sufficient quality, always necessary Plant technology, which is becoming increasingly complex, limits the number of recycling cycles that can be reasonably achieved. In the end emerges a non-usable in all of the above-mentioned processes Waste that is then disposed of using special processes or must be deposited.

The object of the invention is therefore to create a sound-absorbing or sound-absorbing insulation or Insulating material or a building board with as diverse as possible physical properties that a use in the allows a wide variety of applications, the Insulation or insulation an excellent Possesses recyclability.  

The further object of the invention is to create a energy-saving process for generation or Production of soundproofing or soundproofing material or Building boards from this.

The object is achieved by the features of claims 1 and 43 solved.

The invention has the advantages over the known that that a soundproofing or soundproofing material is produced, which also has very good thermal insulation properties. Secondary raw materials, such as. B. waste glass, waste paper and other recycling materials are 100% used.

The production processes of the sound insulation according to the invention or soundproofing materials are very energy intensive and environmentally friendly at the same time. As a solvent in Production process only serves water. Otherwise it will no water or air polluting substances used.

The density and thus important physical properties of the obtained sound insulation or sound insulation materials is through the choice or adaptation of a suitable one Manufacturing process selectable within wide limits.

Important strength properties of the sound insulation or Soundproofing materials can, if desired, through the The addition of water-soluble substances is also considerable be increased. This creates the possibility of individual adjustment of the sound insulation or Soundproofing materials for a specific application.

The sound insulation or Soundproofing materials can - whether with or without additives strength-increasing substances - 100% be reprocessed. After use and return the soundproofing and soundproofing materials are made of them Recycling - just like the original one Manufacturing process - very environmentally friendly.  

The soundproofing and soundproofing materials are very suitable well, in combination or in combination with other materials or fabrics to be used. Depending on the application can, if desired, this combination by choosing one suitable production process already during manufacture can be achieved.

The during the manufacturing process in aqueous solution achieved mixing and homogenization of the used Components of soundproofing or soundproofing materials gives the opportunity, if necessary, different geometric shapes by casting the mixture of materials produce. This can be especially true for the generation of various geometric shapes for special sound-absorbing or sound-absorbing components of interest be.

The combination with other materials with the aim It is possible to achieve special product properties.

There are diverse applications in the building materials industry given. Depending on the planned use of the sound insulation or It is soundproofing material by choosing or setting the Manufacturing process possible, targeted important Adjust product properties. Starting materials or Raw materials for the generation of sound insulation or Soundproofing materials should consist of so-called Secondary raw materials, i.e. already used and the Recycling be re-fed substances. The Use of special chemicals or others, environmentally harmful auxiliaries or solvents is complete or largely excluded.

In the case of the use of e.g. B. fine-pored round granules Glass or expanded glass are the quality requirements the materials used are relatively low. Cleaned Recycling glass is finely ground, processed, granulated and inflated at 1000 ° C.  

Pollution components or particles disturb this Manufacturing process not because it is in the product produced be included without disadvantage.

If the sound insulation or Soundproofing materials is reprocessing unlimited possible and with the same Process steps as in the primary production of Products. The quality is no different Way of the quality of the raw materials.

The invention is based on exemplary embodiments with reference to Drawings explained.

It shows:

Fig. 1 is a composite according to the invention from two different secondary raw materials, namely, expanded glass or fine-pored round granulate of glass and cellulose fibers,

Fig. 2 shows a composite material according to the invention from three different secondary raw materials, namely, expanded glass or fine-pored round granulate of glass, polyurethane powder and cellulose fibers,

FIG. 3 is a composite of the invention from two different secondary raw materials, namely rubber granules and cellulose fibers,

Fig. 4 schematically use and impact strength-increasing binder in the sound insulation or soundproofing material,

Fig. 5 is a section through an application-specific sound insulation or soundproofing material, formed from three different secondary raw materials namely, polystyrene granules, expanded glass or fine-pored round granulate of glass and cellulose fibers,

Fig. 6 is a section through an application-specific sound insulation or soundproofing material formed of three different materials namely secondary rubber granules, expanded glass or fine-pored round granulate of glass and cellulose fibers,

Fig. 7 is a section through an application-specific sound insulation or soundproofing material, formed from four different secondary raw materials namely, polystyrene granules, expanded glass or fine-pored round granulate of glass, rubber granulate and cellulose fibers,

Fig. 8 is a section through application-specific sound insulation or sound proofing materials, formed of two different sound insulation or sound proofing materials,

Fig. 9 shows a section through an application-specific sound insulation or soundproofing material, formed from three different sound insulation or sound proofing materials,

Fig. 10 is a section through an application-specific sound insulation or soundproofing material formed from two different sound insulation or sound proofing materials and a cover,

Fig. 11 is a section through an application-specific sound insulation or soundproofing material constituted of a sound insulation or soundproofing material, a composite material and a cover,

Fig. 12 shows schematically a production plant for the stock preparation with fiber resolution, fiber pulping, thickening, and mixing in the second secondary raw material.

Fig. 13 schematically shows a plant for stock preparation additionally in admixture with binder,

Fig. 14 schematically shows a plant for the discontinuous production of the sound insulation and sound insulation material with the possibility of producing multi-layer products,

Fig. 15 is a plant for continuous production of the sound insulation or soundproofing material.

According to the invention, two different secondary raw materials, so waste products combined with each other, or there will be a secondary raw material, for example waste paper with a Neustoff combined. The combination partners instruct different physical and chemical Properties on. This will be done first on one Embodiment of the invention with foamed glass, too Expanded glass or fine-pored round granules made of glass, explained.

In one exemplary embodiment of the invention, expanded glass spheres or fine-pored round granules made of glass 2 ( FIG. 1) are used as the first secondary raw material. Cellulose fibers 4 , for example in the form of waste paper, are used in a different digestion state as the second secondary raw material. Water is added as the sole solvent, which can remove the binding forces between the individual fibers.

The glass fraction of this mixture behaves in relation to that Water inert, d. H. there is no chemical reaction instead of. There is only a minor one Water absorption of the glass fraction, which is primarily from the The nature of the present glass depends.

The low density of the foamed glass material causes the glass granulate 2 to float up immediately. Homogenization of this mixture in water is therefore not possible. By adding a defined amount of disrupted cellulose fibers 4 , the foamed glass granules are kept in solution or homogenized. Only the use of cellulose material, ie the cellulose fibers 4 , enables such processing of foamed glass material.

For the production of a composite material 1 ( FIG. 1), expanded glass spheres or fine-pore round granules made of glass 2 and cellulose fibers 4 are mixed by stirring with the addition of a defined amount of water. The cellulose fibers 4 produce a fiber composite system with such a strength that the expanded glass spheres or the fine-pored round granules made of glass 2 are firmly integrated in this composite. The cellulose fibers 4 wet the expanded glass spheres or the fine-pored round granules made of glass 2 and enclose them. Because of the very porous and fissured surface of the expanded glass spheres or the fine-pored round granules made of glass 2 , the cellulose fibers 4 get caught in the cavities of the glass particles 2 near the surface. After this mixture has dried, an extremely stable product with very good strength properties is produced, the expanded glass or the fine-pored round granules made of glass being embedded very stably in the composite of the cellulose fibers 4 . At the same time, the wetting and crosslinking properties of the cellulose fibers 4 prevent the expanded glass or fine-pored round granules made of glass 2 from floating above a certain concentration. The cellulose fibers 4 prevent separation of the individual components of the sound-absorbing or sound-absorbing insulating or insulating material formed from cellulose fibers 4 , expanded glass spheres or fine-pored round granules made of glass 2 and water and guarantee the formation of a homogeneous mixture.

After drying this very homogeneous mixture, a stable fiber composite reached. By training this stable fiber composite during drying is not necessary the need to use a binding or Adhesive for the production of the sound-absorbing or sound-absorbing insulation or insulating material.

Expanded glass or fine-pore round granulate made of glass 2 is characterized by good to very good thermal insulation values. These thermal insulation values are characterized by the X-value or thermal conductivity. Expanded glass or fine-pored round granulate made of glass 2 also has a very low density. The cellulose fibers 4 , for example paper fibers, are known to be a good heat insulation material. However, the values of expanded glass or fine-pored round granules made of glass are not achieved. The density of paper or other cellulose fiber products is generally higher than that of expanded glass or fine-pore round granules made of glass, but the density of these products depends strongly on the grain size used. The following table shows the density values and the thermal conductivity coefficients λ of expanded glass or fine-pore round granulate made of glass for various grain sizes and of ordinary quality paper.

1. Expanded glass or fine-pored round granulate made of glass

2. Paper, ordinary quality

Density (kg / m³): approx. 700; Thermal conductivity coefficient λ (W / mK): approx. 0.12.

An additional insulation effect is achieved by the cavities 5 formed between the cellulose fibers 4 and the expanded glass spheres or the fine-pored round granulate made of glass 2 . These cavities inevitably arise during the manufacturing process and can be varied in size and distribution within wide limits.

Another, technically useful property of expanded glass or fine-pored round granulate made of glass and of Pulp fiber is by building these products justified. Both products are characterized as that they fall into the group of materials contained in their  Inside a very large number of air or gas filled Have cavities. These voids or pores and channels are communicating with the environment. Hereby as already mentioned, the effect is as sound-absorbing material or as porous Sound absorber. Impinging sound waves penetrate into it Material through the fine channels and through the Flow friction that occurs becomes vibration energy in Converted thermal energy, so sound energy reduced. On additional sound absorbing effect is due to the Achieved that during the manufacturing process between the cellulose fibers and the expanded glass balls or the fine-pored round granulate made of glass an additional Cavity system arises.

The combination of the products pulp fibers and expanded glass or fine pore round granulate made of glass, in connection with the production-related generation of the aforementioned Cavity structure result in an excellent Thermal insulation effect as well as excellent sound absorbing or sound absorbing properties that targeted by varying the manufacturing parameters or Choice of the products used, for example the grain size the expanded glass or fine-pored round granules made of glass vary. The combination of expanded glass or offers fine-pored round granules made of glass and cellulose fibers so very good for achieving the mentioned Product features.

As already mentioned, offers itself as a raw material for that required expanded glass or fine-pored round granules made of glass Waste glass on, d. H. already used and again collected glass. The type of glass used is any. The grain size and the cavity structure of the produced expanded glass or fine-pored round granules made of glass is solely through the chosen Manufacturing process discontinued.

Depending on the application, the need may arise the density and thus the acoustic permeability of the  Vary soundproofing or soundproofing material. In wide limits this is due to the increase or decrease of the pulp fiber portion possible. In special cases but the addition of other additives, these are preferably in turn secondary raw materials be.

The soundproofing or soundproofing materials can be on the Visible area then also with the known ones sound absorbing structures.

For the production of such a composite 3 ( FIG. 2), expanded glass spheres or fine-pore round granules made of glass 2 , cellulose fibers 4 and a further additive, in this case exemplified by old polyurethane powder 6, are mixed using a defined amount of water. The much smaller polyurethane particles 6 occupy the gaps or cavities between the cellulose fibers and thus reduce the permeability of the product. Instead of polyurethane, depending on the application, other products such as various plastic powders, quartz sand, wood flour, cement powder, plaster or kaolin are also available.

For many areas of application in sound insulation or Sound insulation technology is special structure-borne sound insulation Properties of the products in demand. In this case, a such structure-borne noise insulation, for example when using as impact sound insulation material using Rubber granulate and STYROPOR (that from the German company BASF is offered under the trade name STYROPOR) getting produced. Depending on the use of the material appropriate additions of STYROPOR and / or Rubber granulate possible, or the structure-borne sound insulation Without airborne sound insulation properties only from the raw materials Cellulose fibers and STYROPOR and / or rubber granulate produced.

In order to produce such a special structure-borne sound-absorbing composite 7 ( FIG. 3), cellulose fibers 4 and said rubber granulate 8 are in turn mixed with water. Instead of rubber granulate 8 , STYROPOR balls can also be used if the application demands it. The simultaneous use of rubber granulate and STYROPOR can also be advantageous, with their mass fractions being determined by the application.

A possibly required density variation, at simultaneous variation of the strength values can turn set within limits with the pulp fiber concentration will. In addition, there is also the possibility here a density increase through the use of others Obtain additives, which due to their low Fill the voids between the cellulose fibers and thus the permeability of the composite simultaneous increase in compressive strength, lower. At This combination of fabrics is the use of various Substances such as plastic powder, quartz sand, polyurethane powder, Wood flour, plaster or cement powder are conceivable.

The cellulose fibers, that is to say the cellulose fibers 4 , for producing the described composite materials 1 , 3 , 7 , that is to say the soundproofing or soundproofing materials, can be obtained, for example, from wood as the primary raw material source or waste paper as the secondary raw material source.

Wood in the broadest sense is a mixture of cellulose, Hemicellulose, lignin and accompanying substances. The cellulose represents the actual fiber substance. Chemically the cellulose from related sugar molecules as highly polymeric compounds, i.e. macromolecules.

All are under the term secondary raw materials Waste paper types that are in the recycling cycle of paper and Carton production can be summarized.

The return rate for waste paper is in Germany Paper industry currently only around 50%. The reason this is due to the lower values with regard to  Fiber length, strength, swelling capacity and color of the fibers. Existing foreign components complicate the Manufacturing process additionally immense. The extension of the Field of application, for example for the generation of Sound insulation or sound insulation, from returning Waste paper would therefore be with a view to increasing the Return rate of waste paper very interesting. Another The advantage is the possibility of unsorted To process mixed waste paper, which in the classic Waste paper processing process to produce higher quality Paper products is rather unpopular.

Are the demands on the strength of the product still higher, for example with special products, can also assorted office paper, with very high demands too bleached long fiber pulp in its pure form or as an additive be used.

The soundproofing or soundproofing material according to the invention can can be recycled indefinitely, i.e. reused. Since the Strength of the sound insulation or sound insulation only generated by hydrogen bonds between the cellulose fibers the drying of the soundproofing or Reprocessing can be designed for sound insulation by dissolving in water using the following procedures happen in order to generate a new raw material. There water is the only solvent in production is used, and the individual process steps Filtration, pressing and drying is what it is Manufacturing process very environmentally friendly.

In certain areas of use of soundproofing or soundproofing materials, it may be necessary that the strength obtained by the sole use of cellulose fibers is not sufficient. Strength-promoting but water-soluble binders 9 ( FIG. 4) can be used here. Due to the 100% water solubility, the very good recyclability is retained.

The mode of action of these strength-increasing additives is based on the fact that they have appropriate charge carriers which are attracted by the cellulose fibers 4 negatively charged on their surface by electrostatic forces.

A popular binder here is starch. Used are degraded starches, for example swelling starch. Experiments have shown that the best results are achieved if 0.5-15% based on otro, i.e. oven-dry Fiber mass is added.

It is also possible to add methyl cellulose (MC) or carboxymethyl cellulose (CMC), which also like that Starch has good strength-increasing properties. Here the tests showed that an addition of 0.5-12% the best in terms of otro, i.e. oven-dry fiber mass Showed results.

The combination of methyl or carboxymethyl cellulose with Starch also show very good results in terms of a strengthening of the sound insulation or Soundproofing material.

Other binders 9 ( FIG. 4) with strength-improving properties are also the mannogalactans (locust bean gum) and alginates. These are herbal products with MC, CMC and starch-like properties.

For certain areas of application of the insulating or insulating material it may be possible that while increasing the Strength values also increase the Moisture resistance is desirable. This increased Moisture resistance worsens the Redissolvability of the insulating or insulating material in water, but improves its applicability to certain Areas of application.

In these cases, binders 9 ( FIG. 4) with strength-improving properties and moisture-resistance-increasing properties are added. Known representatives of this type of binder are so-called binder latex materials.

They generally consist of copolymers, for example are these copolymers of butadiene and acrylonitrile or Copolymers of butadiene and styrene.

It is also possible to add so-called Hydrophobizing agents that primarily do not increase the Strength values but only an improvement in Cause moisture resistance.

In particular, the most varied of these Binder additives and their possibilities u. a. in the Writings EP-A 0 178 612, EP-A 0 123 234, EP-A 0 115 704, EP- A 0 044 399, DE-OS 35 06 710 and EP 0 266 850 B1.

According to one exemplary embodiment of the invention, an application-specific soundproofing or soundproofing material 1 ( FIG. 1) is formed from a mixture of cellulose 4 and expanded glass or fine-pored round granules made of glass 2 .

According to a further exemplary embodiment of the invention, an application-specific soundproofing or soundproofing material 3 ( FIG. 2) is formed from a mixture of expanded glass or fine-pored round granules made of glass 2 , polyurethane powder 6 and cellulose fibers 4 .

According to another exemplary embodiment of the invention, an application-specific soundproofing or soundproofing material 7 ( FIG. 3) is formed from a mixture of rubber granules 8 and cellulose fibers 4 .

According to another exemplary embodiment of the invention, another application-specific soundproofing or soundproofing material 10 ( FIG. 5) is produced from a mixture of expanded glass or fine-pore round granules made of glass 2 , STYROPOR 11 and cellulose fibers 4 .

According to a further exemplary embodiment of the invention, an application-specific soundproofing or soundproofing material 12 ( FIG. 6) is formed from a mixture of expanded glass or fine-pore round granules made of glass 2 , rubber granules 8 and cellulose fibers 4 .

According to another exemplary embodiment of the invention, another, application-specific soundproofing or soundproofing material 14 ( FIG. 7) consists of a mixture of expanded glass or fine-pore round granules made of glass 2 , rubber granules 8 , STYROPOR 11 and cellulose fibers 4 .

According to a further exemplary embodiment of the invention, a further, application-specific soundproofing or soundproofing material 15 ( FIG. 8) consists of a soundproofing or soundproofing material 16 , for example made of cellulose and expanded glass or fine-pored round granules made of glass, and a second soundproofing or Sound insulation 17 , for example consisting of cellulose fibers and rubber granules.

According to another exemplary embodiment of the invention, another, application-specific soundproofing or soundproofing material 18 ( FIG. 8) consists of a soundproofing or soundproofing material 19 , for example of cellulose and expanded glass or fine-pored round granules made of glass, and a second soundproofing or Soundproofing material 20 , for example formed from cellulose fibers and STYROPOR.

According to a further exemplary embodiment of the invention, a further, application-specific soundproofing or soundproofing material 21 ( FIG. 8) consists of a soundproofing or soundproofing material 22 , for example of cellulose and expanded glass or fine-pored round granules made of glass, and a second soundproofing or Sound insulation 23 , for example consisting of cellulose fibers, rubber granules and STYROPOR.

According to another exemplary embodiment of the invention, a further, application-specific soundproofing or soundproofing material 24 ( FIG. 9) consists of a soundproofing or soundproofing material 25 , for example made of cellulose and expanded glass or fine-pored round granules made of glass, a second soundproofing or Soundproofing material 26 , for example consisting of cellulose fibers and rubber granulate, and a third soundproofing or soundproofing material 27 , for example made of cellulose fibers and STYROPOR.

Another embodiment of the invention provides that a soundproofing or soundproofing material 28 ( FIG. 10) consisting of a soundproofing or soundproofing material 29 , for example a mixture of cellulose fibers and rubber granules and a second soundproofing or soundproofing material 30 , for example Cellulose fibers and expanded glass or fine-pored round granules made of glass are provided with a cover 31 , for example a perforated plate.

Another embodiment of the invention provides that a soundproofing or soundproofing material 32 ( FIG. 11) consisting of a soundproofing or soundproofing material 33 , for example a mixture of cellulose fibers and rubber granulate and a composite material 34 , for example a mineral fiber mat, with a Cover 35 is provided, for example a perforated plate.

Process for the production of sound insulation or Soundproofing material

Sound insulation or sound insulation is obtained by mixing cellulose fibers with a mixing partner according to the relationship:
Cellulose fibers + mixing partner = soundproofing or soundproofing material
The following are suitable for the production of cellulose fibers, each suspended in water:
paper
Waste paper, sorted
Waste paper, unsorted, mixed
cellulose
Pulp, bleached
Pulp, unbleached
Wood sanding.

For the achievement of special physical properties it is also possible to use different cellulose fibers other mixing partners (instead of expanded glass or fine-pored Round granulate made of glass).

The following are suitable as mixing partners:
Polystyrene, foamed
Expanded clay
Perlite
Polyethylene, foamed
Polyurethane, foamed
Rubber or rubber materials
Used tire granulate.

These mixing partners can be in pure form, i.e. without further ones Additions, or in any combination, with any Compositions with others of the aforementioned Mixing partners are mixed with cellulose fibers. The the respective mixing ratio is according to the Requirements set.

For special areas of application, a combination of Sound insulation or sound insulation materials, formed from Cellulose fibers and the aforementioned blend partners with other mixing partners necessary. The goal here is Generation of very special physical properties, for example the improvement of certain Strength values.

The following are suitable as mixing partners for this application:
Polyurethane, not foamed
Polystyrene powder
Polyamide powder
Polyester powder
Polyethylene powder
Wood shavings
Wood flour
Pearlite, uninflated
Pearlite, ground
finely divided clays
kaolin
Montmorillonite
Feldspar
chalk
Diatomaceous earth
mica
Fiber materials
Fiberglass
Mineral fibers
Steel shavings
Steel fibers
Coconut fiber
Jute fibers
Cotton fibers.

These mix partners to achieve special physical properties can in turn be in pure form, So as mono components, or in any combination can be added with any compositions. The Mixing ratio must meet the respective requirements correspond.

An application-specific soundproofing or soundproofing material is produced by adding an additive according to the following relationship:
Soundproofing or soundproofing material + additive = application-specific soundproofing or soundproofing material
Usable additives are:
binder
water-soluble binders (e.g. methyl cellulose)
water-insoluble binders
Binder with increased moisture resistance
Fire retardant substances such as B .:
Boron salts (borax)
Aluminum silicates
Aluminum hydroxides
Phosphates like prim. Sodium phosphate
Various types of plaster
Different types of cements
Sand of different grain sizes
Hydrophobizing agents such as:
Silicones (polysiloxanes)
Waxes.

These additives can be in pure form, as monocomponents or in any combination, with any Mass compositions for sound insulation or Soundproofing material can be added.

Or an application-specific soundproofing or soundproofing material is produced according to the relationship:
Soundproofing or soundproofing material 1 + soundproofing or soundproofing material 2 = application-specific soundproofing or soundproofing material
or an application-specific soundproofing or soundproofing material is produced according to the relationship:
Sound insulation or sound insulation 1 +. . . + Soundproofing or soundproofing material n = application-specific soundproofing or soundproofing material
or an application-specific soundproofing or soundproofing material is produced according to the relationship:
Soundproofing or soundproofing material 1 + composite material = application-specific soundproofing or soundproofing material.

The following composite materials can be used:
Plastic films
Plastic sheets
Metal foils
Metal sheets
Cardboards with different basis weights
Corrugated cardboard
Textile fabrics or textile fabrics
Paper with variable basis weights
Wood veneers
Wooden panels
Wood fiber mats
Fiberboard
Chipboard
Cork sheets
Plasterboard
Plasterboard
concrete
Gas concrete slabs
Foam plastics
bitumen
Bitumen fabric
Bitumen cardboard
Rubber products
rubber
Mineral wool products
Cotton fiber mats
Coconut fiber mats
Coconut fiber boards
Jute mats
Jute boards
HERAKLITH
Glass plates
Glass foils
Glass wool products
Laminated fiberglass fabrics
Stoneware.

The following combinations are conceivable for application-specific further processing of soundproofing or soundproofing materials:
Soundproofing or soundproofing material + coating = application-specific soundproofing or soundproofing material.

Possible coatings are:
Paints, varnishes
Resins
Waxes
Liquid plastics
All kinds of binders
Adhesives
Fatty substances
tar
bad luck
Strength
starchy products
Leveling compounds
Cement spatula
Dispersion filler
Finished plasters.

The coatings can be in pure form, as a monocomponent or if necessary in different combinations on the Soundproofing or soundproofing material are applied.

A soundproofing or soundproofing material is produced on a system 40 ( FIG. 12). The cellulose fibers 4 , for example waste paper, cellulose or wood pulp, are processed in a pulper or pulper 41 . The aforementioned products are dissolved in this pulper 41 , that is to say broken down into individual fibers. At the same time, foreign substances are separated. The pulper 41 is followed by fiber processing (fiber fractionation, fiber digestion) in a refiner 42 . A thickener 43 follows the refiner 42 . This is where the thickening takes place, that is to say the increase in the concentration of the aqueous suspension.

The mixing partner of the cellulose fibers 4 is provided in a storage silo 44 , shown using the example of expanded glass or fine-pored round granules made of glass. The feed into the mixer 46 ( FIG. 12) takes place via a screw conveyor 45 , that is to say the two material flows are brought together. The mixed suspension leaving the mixer is transferred at a point 47 to other parts of the plant which carry out the process steps "shaping", "dewatering" and "drying".

In a modification of the aforementioned system, system 50 ( FIG. 13) is used to produce a soundproofing or soundproofing material with increased strength values by using a binder.

The cellulose fibers 4 , for example waste paper, cellulose or ground wood, are first processed in a pulper or pulper 51 . The aforementioned products are dissolved in this pulper 51 , that is to say broken down into individual fibers. At the same time, foreign substances are separated. The pulper 51 is followed by fiber processing (fiber fractionation, fiber digestion) in a refiner 52 . A thickener 53 follows the refiner 52 . In this thickener 53 , the fiber concentration of the aqueous suspension is increased.

The mixing partner of the cellulose fibers 4 is provided in a storage silo 54 , again shown using the example of expanded glass or fine-pore round granules made of glass. Via a screw conveyor 55 , the metering into the mixer 56 ( FIG. 13) takes place, that is, the merging of the two material flows. In addition, in this production variant, a defined amount of binder 9 is added to the mixer 56 in a prepared, liquid form via a metering pump 57 . The three supplied components are then thoroughly mixed within the mixer 56 . The binder 9 which has already been worked up is prepared in a special preparation plant 58 ready for metering in the desired manner. The mixed suspension leaving the mixer is transferred at point 59 to other parts of the plant which carry out the process steps "shaping", "dewatering" and "drying".

Depending on the type of soundproofing or Soundproofing material can be used in the process steps "Forming" and "drainage" between discontinuous and continuous operation.

For discontinuous production ( FIG. 14), a press 60 is provided, in which the mixed suspension is filled into an appropriate mold, and the water, which is also called press water, is removed from the mixed suspension to be shaped and dewatered via a sieve plate 61 . In the exemplary embodiment of the invention, a press 60 that drains on one side is used. Here, the press water is removed from the press in only one direction via the sieve tray 61 . An aqueous mixture of a soundproofing or soundproofing material is supplied via the feeder 62 and an aqueous mixture of another soundproofing or soundproofing material via a feeder 63 . This combination of different soundproofing or soundproofing materials already in the manufacturing process, that is to say in the wet state, results in the very good possibility of producing multi-layer products with specifically adjustable physical or material properties.

Another (not shown in the drawings) Embodiment is through double-sided drainage, for example by a porous or perforated ram the formation of pronounced density gradients in manufactured material sought.

Special density profiles in the material are from the Papermaking well known and call special, desired distributions of strength in the produced product forth. Relevant information about this can be obtained from the Magazine "Wochenblatt für Papierfabrikation" issue 3/1989 "Application of the theory of wet pressing for today's presses", Dr. H. Dahl, and the special print from the "Wochenblatt für Papierfabrikation "1989, No. 2, 3 and 4, the" APV- Annual Meeting 1988 "," The importance of wet pressing for Product and Productivity ".

The continuous production of a soundproofing or soundproofing material is achieved with a system 70 ( FIG. 15). In this exemplary embodiment of the invention, the mixed suspension is fed via a first headbox 71 onto a rotating screen belt 73 . Dewatering takes place through the circulating sieve belt 73 , the escaping water being collected in a sieve box 74 .

Via a second headbox 72 , the aqueous mixed suspension of a second soundproofing or soundproofing material is applied to the first soundproofing or soundproofing material that has already been dewatered and fed through the headbox 71 . The drainage also takes place here through the circulating sieve belt 73 . Following the wire section, formed in this exemplary embodiment from rotating wire belt 73 , headbox 71 , headbox 72 and screen box 74 , there follows a dewatering press 80 , formed from two press rolls 81 and 82 and two press felts 83 and 84 . At a point 85, the product leaves the system 80 and is dried. Such systems for the production of nonwovens using cellulose fibers are well known from the paper manufacturing process, albeit in a greatly modified form.

Even with this continuous production, a single and double-sided dewatering in the dewatering press as well well possible in the wire section. Relevant, from the Papermaking-related information is e.g. B. Special print from the magazine "Wochenblatt für Papierfabrikation ", issue 11-12 / 1987" Formation systems multilayered webs - an overview "by Dr. A. Bubik removable.

Following the drainage of the still damp Sound insulation or sound insulation in a press must Drying on one that corresponds to the environmental conditions Final dry content.

In the drying processes in question, the evaporation of the water contained in the still damp soundproofing or soundproofing material can be caused by:
convective drying
Contact drying
Infrared drying
Microwave drying
Flow drying
respectively.

Depending on the product produced and the desired one In any case, quality characteristics should be the most energy-saving method can be selected.

The simplest way of drying is done by a Temporary storage in suitable drying chambers, whereby the drying takes a very long time. With regard to this topic, turn to relevant References from the field of paper production, in the detailed the different drying processes of cellulose fiber products are described and evaluated. For this, the lecture series "Drying paper", Special print from the magazine "Wochenblatt für Papierfabrikation "1974, No. 1 to 4, on the APV- Annual meeting 1978, lecture series "Energy analysis and Importance of energy consumption in the pulp and Paper industry ", on the special print from the magazine "Wochenblatt für Papierfabrikation" (1979) No. 1 to 3, on das "Papiermacher Taschenbuch", 5th edition, 1989, Dr. Curt Haefner Verlag GmbH, Heidelberg, on the "Handbook for Pulp & Paper Technologists ", 1982, Tappi, Atlanta, USA and on the Book "Paper in our World", 1990, Econ Verlag, Düsseldorf referred.

Claims (46)

1. Soundproofing or soundproofing material, characterized in that the soundproofing or soundproofing material consists exclusively of a secondary raw material and a mixture partner with airborne soundproofing and / or structure-borne soundproofing properties. 2. Soundproofing or soundproofing material according to claim 1, characterized in that the mixing partner is expanded glass or fine-pored round granules made of glass ( 2 ). 3. Soundproofing or soundproofing material according to claim 1, characterized in that the mixing partner consists of rubber or rubber material ( 8 ). 4. Soundproofing or soundproofing material according to claim 1, characterized in that the mixing partner consists of STYROPOR balls ( 11 ). 5. Soundproofing or soundproofing material according to claim 1, characterized in that the mixing partner with airborne and / or structure-borne soundproofing properties consists of STYROPOR balls ( 11 ) and rubber granules ( 8 ) or rubber material ( 8 ). 6. Soundproofing or soundproofing material according to one of claims 1 to 5, characterized in that the secondary raw material consists of cellulose fibers ( 4 ). 7. Soundproofing or soundproofing material according to claim 6, characterized in that the cellulose fibers ( 4 ) consist of sorted or unsorted waste paper. 8. Soundproofing or soundproofing material according to claim 6, characterized in that the cellulose fibers ( 4 ) are bleached or unbleached cellulose fibers. 9. Soundproofing or soundproofing material according to claim 6, characterized in that the cellulose fibers ( 4 ) are obtained from ground wood. 10. Soundproofing or soundproofing material according to claim 6, characterized in that the cellulose fibers ( 4 ) are paper fibers. 11. Soundproofing or soundproofing material according to one of claims 1 to 10, characterized in that the soundproofing or soundproofing material contains strength-increasing binders ( 9 ) to be processed in aqueous solution. 12. Soundproofing or soundproofing material according to claim 11, characterized in that the strength-increasing binder ( 9 ) also has a property which improves the moisture resistance of the soundproofing or soundproofing material. 13. Soundproofing or soundproofing material according to claim 12, characterized in that a binder latex is added as a binder ( 9 ). 14. Soundproofing or soundproofing material according to claim 6, characterized in that delignified long-fiber cellulose is used as cellulose fibers ( 4 ). 15. Soundproofing or soundproofing material according to one of claims 1 to 14, characterized in that it contains starch as a binder ( 9 ). 16. Soundproofing or soundproofing material according to claim 15, characterized in that the starch is degraded starch. 17. Soundproofing or soundproofing material according to claim 16, characterized in that the degraded starch swelling starch is.   18. Soundproofing or soundproofing material according to claim 16, characterized in that the degraded starch oxidized Strength is. 19. Soundproofing or soundproofing material according to claim 16, characterized in that the degraded starch is cationic Strength is. 20. Soundproofing or soundproofing material according to claim 11, characterized in that it contains an additive of methyl cellulose as a binder ( 9 ). 21. Soundproofing or soundproofing material according to claim 11, characterized in that carboxylmethyl cellulose is added as a binder ( 9 ). 22. Soundproofing or soundproofing material according to claim 11, characterized in that a combination of methyl or carboxylmethylcellulose with starch is added as a binder ( 9 ). 23. Soundproofing or soundproofing material according to claim 11, characterized in that mannogalactanes are added as binders ( 9 ). 24. Soundproofing or soundproofing material according to claim 11, characterized in that alginates are added as binders ( 9 ). 25. Soundproofing or soundproofing material according to one of the claims, characterized in that it consists of a first soundproofing or soundproofing material ( 16 ), preferably made of cellulose and expanded glass or fine-pored round granules made of glass, and a second soundproofing or soundproofing material ( 17 ), for example consisting of cellulose fibers and rubber granules, is formed. 26. Soundproofing or soundproofing material according to one of claims 1 to 24, characterized in that it consists of a first soundproofing or soundproofing material ( 19 ), preferably made of cellulose and expanded glass or fine-pored round granules made of glass, and a second soundproofing or sound insulation ( 20 ), for example consisting of cellulose fibers and STYROPOR, is formed. 27. Soundproofing or soundproofing material according to one of claims 1 to 24, characterized in that it consists of a first soundproofing or soundproofing material ( 22 ), preferably made of cellulose and expanded glass or fine-pored round granules made of glass, and a second soundproofing or soundproofing material ( 23 ), for example consisting of a mixture of cellulose, STYROPOR and rubber granulate. 28. Soundproofing or soundproofing material according to one of claims 1 to 24, characterized in that it consists of a first soundproofing or soundproofing material ( 25 ), preferably made of cellulose fibers and expanded glass or fine-pored round granules made of glass, and a second soundproofing or soundproofing material ( 26 ) consisting for example of cellulose fibers and rubber granules, and a third soundproofing or soundproofing material ( 27 ) consisting of cellulose fibers and STYROPOR, for example. 29. Soundproofing or soundproofing material according to one of the claims, characterized in that it consists of a first soundproofing or soundproofing material ( 30 ), preferably made of cellulose fibers and expanded glass or fine-pored round granules made of glass, and a second soundproofing or soundproofing material ( 29 ), for example consisting of cellulose fibers and rubber granules, and a cover ( 31 ) is formed. 30. Soundproofing or soundproofing material according to one of the claims, characterized in that it consists of a soundproofing or soundproofing material ( 33 ), preferably consisting of cellulose fibers and rubber granules, and a composite material ( 34 ), for example consisting of a mineral fiber mat, and one Cover ( 35 ) is formed. 31. Soundproofing or soundproofing material according to one of claims 29 and 30, characterized in that the cover ( 31 ) or ( 35 ) is a perforated plate. 32. Soundproofing or soundproofing material according to one of the preceding claims, characterized in that Cellulose fibers and a blend partner are provided. 33. Soundproofing or soundproofing material according to claim 32, characterized in that foamed as a mixture partner Polystyrene, expanded clay, pearlite, foamed polyethylene, foamed polyurethane, rubber or rubber materials, or used tire granules are used. 34. Soundproofing or soundproofing material according to claim 32 and 33, characterized in that as a second Mixing partner unfoamed polyurethane, polystyrene powder, Polyamide powder, polyester powder, polyethylene powder, Wood shavings, wood flour, unexpanded pearlite, finely divided clays, Kaolin, montmorillonite, feldspar, chalk, diatomaceous earth, mica, Fiber materials, glass fibers, mineral fibers, steel chips, Steel fibers, coconut fibers, jute fibers or cotton fibers is added. 35. Soundproofing or soundproofing material according to one of the preceding claims, characterized in that a Soundproofing or soundproofing material and an additive are provided. 36. Soundproofing or soundproofing material according to claim 35, characterized in that a water-soluble additive or water-insoluble binder, preferably Methyl cellulose, a fire retardant chemical, a fire retardant, a hydrophobizing agent Gypsum, a cement, and / or a sand is used.   37. Soundproofing or soundproofing material according to one of the Claims 1 to 36, characterized in that it consists of a first soundproofing or soundproofing material and a second Soundproofing or soundproofing material is formed. 38. Soundproofing or soundproofing material according to one of the Claims 1 to 36, characterized in that it consists of a Soundproofing or soundproofing material and a composite material is formed. 39. Soundproofing or soundproofing material according to claim 38, characterized in that the composite material is either a Plastic film, a plastic plate, a metal foil, a Metal plate, a cardboard, a corrugated cardboard, a textile fabric, a textile fabric, a paper, wood veneer, a wooden plate, a chipboard, a cork board, a plasterboard, one Plasterboard, concrete, a gas concrete slab, a Foam plastic, bitumen, a bitumen fabric, bitumen cardboard, a Rubber product, a rubber, an insulating material, a Mineral wool product, a glass wool product, a Cotton fiber mat, a wood fiber mat, one Wood fiber board, a coconut fiber mat, a coconut fiber board, a jute mat, a jute board, HERAKLITH, one Glass plate, a glass foil, a laminated fiberglass fabric or stoneware. 40. Soundproofing or soundproofing material according to one of the Claims 1 to 36, characterized in that it consists of a Soundproofing or soundproofing material and a coating is formed. 41. Soundproofing or soundproofing material according to claim 40, characterized in that the coating is either a Paint, a varnish, a resin, a wax, a liquid plastic, a binder, an adhesive, a fatty substance, tar, Bad luck, a starch, a starchy product, one Putty, a cement putty, a dispersion putty or is a finished plaster.   42. Building board, characterized in that it consists of one Soundproofing or soundproofing material according to claims 1 to 41 is formed. 43. A method for producing a soundproofing or soundproofing material according to one of claims 1 to 41 or a building board according to claim 42, characterized by the method steps:

• (a) Cellulose fibers ( 4 ) are processed in a pulper ( 41 ),
• (b) a mixing partner is kept in a storage silo ( 44 ),
• (c) in a refiner ( 42 ), the cellulose fibers ( 4 ) are subjected to fiber treatment and fiber digestion,
• (d) the aqueous suspension from the refiner is thickened in a thickener ( 43 ),
• (e) the mixing partner is conveyed from the storage silo ( 44 ) into the mixer ( 46 ) via a screw conveyor ( 45 ),
• (f) the material flows from the screw conveyor ( 45 ) and from the thickener ( 43 ) are brought together in a mixer ( 46 ) and given off as a mixed suspension to plant components downstream of the mixer ( 46 ) for shaping, dewatering and drying.

44. A method for producing a soundproofing or soundproofing material according to one of claims 1 to 41 or a building board according to claim 42, characterized by the method steps:

• (a) Cellulose fibers ( 4 ) are processed in a pulper ( 51 ),
• (b) a mixing partner is kept in a storage silo ( 54 ),
• (c) in a refiner ( 52 ), the cellulose fibers ( 4 ) are subjected to fiber treatment and fiber digestion,
• (d) the aqueous suspension from the refiner is thickened in a thickener ( 53 ),
• (e) the mixing partner is conveyed from the storage silo ( 54 ) into the mixer ( 56 ) via a screw conveyor ( 55 ),
• (f) a defined amount of binder ( 9 ), already in prepared, liquid form, is added to the mixer ( 56 ) via a metering pump ( 57 ),
• (g) in a binder preparation plant ( 58 ), the binder ( 9 ) is prepared for metering in the desired manner,
• (h) the material flows from the screw conveyor ( 55 ), from the thickener ( 53 ) and the binder preparation ( 58 ) are brought together in a mixer ( 56 ) and as a mixed suspension on, the mixer ( 56 ) downstream system parts for shaping, dewatering and Dried out.

45. Process for shaping and dewatering the mixed suspension coming from the mixer ( 46 ) or ( 56 ), characterized by the process steps that

• (a) the mixed suspension is given a predetermined shape by means of a press ( 60 ), and
• (b) the water is discharged through a sieve tray ( 61 ).

46. Process for shaping and dewatering the mixed suspension coming from the mixer ( 46 ) or ( 56 ), characterized by the process steps that

• (a) the mixed suspension is given a predetermined shape by means of a press, and
• (b) the water is removed via a double-sided drainage by means of a porous press ram.