EP2113350A1 - Material and method for production of same and board made from same material - Google Patents

Abstract

The material has a bonding agent (20) provided at a surface of grains (30) e.g. maize, of granulates. The bonding agent at a portion of fibers (10) is bonded to the surface of coated grains (31) of the granulates. The grains exhibit a porous base material, where pores of the base material are filled with gas or air. Medium density of the grains lies in a range from 0.01 to 2 kilogram per liter, and medium diameter of grain size of the grains lies in a range from 0.5 to 50 millimeter. Medium length of the fibers lies in a range from 100 micrometer to 50 millimeter. Independent claims are also included for the following: (1) a plate or molded part comprising a material (2) a method for manufacturing a material.

Description

The invention relates to a material, for example suitable for the formation of plates, layers and moldings, and a method for producing this material and plates or moldings made of this material.

Today's materials must have a variety of required properties and often meet a whole series of requirements simultaneously. For many materials, such as those used in packaging technology, in building, equipment or mechanical engineering application, appropriate properties, such as stability, strength, flexural rigidity, mass and density, or thermal properties may be essential. Also, additional properties are often important, such as. B. a fire and fire resistance.

Furthermore, an increasing scarcity of raw materials sets additional restrictions with regard to the usable basic and starting materials. A recycling of already used materials and parts, as well as the possibility of re-use of newly produced materials and parts are increasingly desirable. So today already puffed cereal grains are common in packaging and insulation technology. Thus, the use of sustainably renewable raw materials with an inherent environmental friendliness of the materials produced from the raw materials is already combined.

However, such known materials, such as wood substitutes, often achieve only unsatisfactory strength, density, or bulk density, or an unsatisfactory relationship between bulk density and strength.

It is therefore an object of the present invention to provide an improved material, including improved bulk material, an improved plate or chipboard, and an improved molded part. It is a further object of the present invention to provide a method for producing an improved material.

These objects are achieved by the material according to claim 1, the plate according to claim 12 and the method according to claim 14. Further advantageous embodiments of the invention are specified in the dependent claims.

According to a first aspect of the present invention, there is provided a material suitable for forming sheets, sheets and moldings, granules of a granule and a surface comprising granules of the granules. This new material has very good swelling values, in particular for the plates produced therefrom.

According to a second aspect of the present invention, the strength of the plates made with the material is improved when fibers are additionally provided, the binder binding a portion of the fibers to the surface of the granules of the granules.

This material may advantageously have an improved or desired strength. In particular, the material may advantageously be light, d. H. relative to comparable materials lighter or have a lower mass density, defined by the ratio of mass to volume, have. Therefore, the material can provide a favorable relationship between weight or density and strength. Furthermore, by coating the grains with the fibers and / or the binder, the mechanical strength of a single grain, and thus also of the material, can be improved. In addition, the granules of the granules for the density of the material are significantly determining. Significantly in this context may mean that the granules provide more than 50%, more than 75% or more than 90% of the volume of the material. Furthermore, the weight fraction of the fibers and binder relative to the grains of the granules may be less than 50%, less than 25% or less than 10%.

According to a preferred embodiment of present invention, a grain of the granules on a porous base material, wherein the pores are filled with air or with a gas. Examples of corresponding grains for this purpose are popped grains of a cereal, such as. Corn, wheat, oats, or amaranth; Popp grain; Granules of a foamed plastic, of an expanded plastic, of an extruded plastic or of a flexible material; Grains of a foam; Styrofoam, Styrodur, or Styrofoam grains; Grains of a puffed extrudate, granules of crushed carpet, or other recyclable or recycled materials such as packaging material, textiles or the like. As a base material can be used in accordance with natural products or plastics, such as. Example, latex, rubber, rubber, organic material, cereal material, polystyrene (PS), polyvinyl chloride (PVC) or polyurethane (PU). The gases used are air, nitrogen, carbon dioxide, halogenated hydrocarbons and the like. Furthermore, foamed metals, such as grains of aluminum foam, can be used. Grains for the purposes of the present invention may thus be particles, chips, chips or parts of a comminuted material.

Advantageously, therefore, materials already used or recycled, and possibly also otherwise not otherwise usable, can be used as raw materials for a material according to an embodiment of the invention. Furthermore, the use of renewable, environmentally friendly and environmentally compatible raw materials can be made possible in a further advantageous manner. Furthermore, but also, regardless of the substances whose basic properties are selected or adapted specifically for the material. Another advantage may lie in a cost-effective production of the material.

In a further embodiment, a mean density of the grains is below 0.1 kg / l, below 1 kg / l, or below 2 kg / l. This average density, where the density is averaged over a representative plurality of grains, may correspond to the density of Styrofoam, Poppkorn, and may be lower than the average density of solid wood, e.g. Spruce, chipboard or medium density fibreboard (MDF). Advantageously, therefore, a material can be obtained whose density is in a range of a density of light materials. Further, a mean diameter of a grain size of the grains according to another embodiment may be in a range of 0.5 mm to 5 mm, in a range of 1 mm to 10 mm, or even more than 10 mm. A grain shape can correspond to possible or conventional forms such. As a spherical shape, ellipsoidal shape, granule shapes, Schnitzelformen, chip forms, blister or teardrop shapes, or other, possibly also irregularly shaped, shape.

Furthermore, according to one embodiment of the invention, a mean diameter of the fibers may be in a range of 10 μm to 100 μm, in a range of 100 μm to 500 μm, or more than 500 μm. Furthermore, according to a further embodiment, an average length of the fibers may be in a range of 100 μm to 1 mm, in a range of 1 mm to 10 mm, or even over 10 mm. examples for Applicable fibers include wood fibers, staple fibers, medium density fibers, fibers of renewable resources, natural fibers, hemp, flax, straw, textile fibers, glass fibers, metal wires or metal shavings, plastic fibers, and the like.

According to another embodiment of the present invention, the binder comprises a cured adhesive, a partially cured adhesive or a curable adhesive. Curing or partial curing of the adhesive can be carried out by evaporation or partial evaporation of a solvent, a heat treatment or a polymerization. For this purpose, the binder may be mixed with a hardener. Furthermore, a comprehensive curing by special storage or handling such. As a cooled storage, initially be suppressed. Thus, in an advantageous manner, the fibers can already be firmly or finally firmly bonded to the surface of the grains, while further processing, reshaping of the material or bonding of the grains to each other is still possible.

Examples of binders in this context are thermosets, urea-formaldehyde (urea-formaldehyde, UF), melamine-formaldehyde (MF), phenol-formaldehyde (PF), isocyanate, diphenylmethane diisocyanate, epoxy resin, acrylic resin, dispersion glues, glues, adhesives, starch , Proteins, polymers and the like.

According to a further preferred embodiment of the present invention, the material comprises constituents, for example granules of a further granulate, wherein the granules of the granules with the grains of the further granules can be mixed. Furthermore, the mixing ratio of the grains of the granules to the grains of the further granules may vary within the material or a unit made therefrom, for example in order to advantageously influence or determine the mechanical properties. Furthermore, by adding granules of the further granules, the mechanical, chemical or physical properties of the material can advantageously be changed or adjusted independently of the properties of the granules, of the fibers or of the binder.

For example, the strength can be further increased, the weight can be further reduced, or else a fire resistance can be increased, for example by mixing in flame retardants. Furthermore, it is also possible to increase the weight or the density of the material by adding a correspondingly heavy further granulate, if necessary and / or advantageous. Examples of other granules include wood chips, fibers, particles, grains of certain active chemical substances such as flame retardants or hydrophobic or hydrophilic substances, rock or metal particles, natural or synthetic grains or the like. Also, the material may once again comprise the fibers with which the granules of the starting granules are coated, d. H. The fibers are additionally added to the material, independently of the bond to a surface of a grain of the granules, in the sense of a further granulate.

According to a further embodiment of the present invention, the material comprises a further binder, wherein the further binder is the coated granules of the granules and / or the grains of the further granules binds to each other. The further binder may correspond to the binder which binds the fibers to the grains, so that advantageously only one binder is used.

According to a further aspect, a bulk material is provided which comprises a material according to an embodiment of the present invention. The grains of the granules or granules are not bound to each other, d. H. On the one hand, the bulk material can provide the advantageous properties of the material and on the other hand, in an advantageous manner, it can also be present independently of an application or use form. In this case, the transport, manufacture and / or handling can advantageously be simpler and / or less expensive. The bulk material can be brought into almost any shape at a distance, or it can also be introduced into openings, molds or cavities before the material is stabilized. This stabilization can be carried out by complete curing of the binders used or else by adding a further binder.

A next aspect provides a plate comprising or made of a material according to an embodiment of the present invention. The grains of granules or granules are bound together, so that they form a solid, coherent and stable material. A corresponding plate can represent an insulation board or a building board in building or equipment construction according to one embodiment.

According to a further aspect of the invention, a chipboard is provided which comprises a first chipboard layer, a second chipboard layer and a material layer. The material layer has a material according to an embodiment of the invention and is arranged between the first chipboard layer and the second chipboard layer. A chipboard according to the invention can advantageously increase the strength of the board, wherein at the same time the weight and / or the board thickness can be advantageously reduced in comparison to a chip board with comparable strength.

Another aspect provides a molded article comprising or made of a material according to an embodiment of the present invention. The granules of the granules, optionally mixed with granules of another granulate, are bound together, and can thus form a stable molded part with the advantageous properties of the material. A the corresponding molding can be provided as a component in equipment or mechanical engineering or packaging technology. Advantageously, the molded article can provide stable force transfer or thermal, shock or vibration isolation while minimizing density and weight. Furthermore, a lightweight and stable molded part can be provided as a packaging aid, which gives the material its advantageous properties, and also possibly ensures a recycling or environmentally friendly disposal.

According to a next aspect of the present invention there is provided a method of making a material comprising the steps of: providing granules; Coating the granules of granules with fibers and a binder; Stabilizing the binder so that the fibers are stably bonded to a surface of the grains. With the method, a material according to an embodiment of the present invention can be produced and provided with its advantageous properties. A material produced by this method is new and advantageous.

An embodiment of the present invention comprises providing the granules by crushing a source material to a predetermined average grain size and / or a predetermined grain shape. Grain size and shape correspond to an embodiment of the present invention. Thus, advantageously, a granule can find use in a process according to an embodiment of the present invention regardless of the starting material or raw material. Furthermore, in an advantageous manner, undefined starting material, such as recyclable recyclables and recycled materials such. As carpets, textiles or used packaging material, be useful in the context of the present invention.

According to a next embodiment of the present invention, coating the grains comprises wetting the surface of the grains with the binder and applying the fibers to a surface of the grains. Furthermore, however, in the In the reverse order, the coating of the grains comprises wetting the fibers with the binder and applying the wetted fibers to the surface of the grains. Coating may further include fiber spraying, a coating technique as used in the manufacture and / or processing of medium density fibers (MDF), or co-extrusion. The glued fiber casing can put itself so arming for a grain.

According to another embodiment of the present invention, the stabilization comprises at least partial curing of the binder. Thus, further processing of the material may be advantageously enabled, although the fibers are stably bound on the surface of the grains. A final curing can therefore take place only after mixing with other granules, fibers or binders, or after a final shaping. For this purpose, the granules coated with the fibers can be mixed with a further granulate during production and / or mixed with a further binder which binds the grains to one another.

• Die Figuren 1A bis 1C schematische Darstellungen eines Werkstoffes gemäß Ausführungsformen der vorliegenden Erfindung
  und
• die Figuren 2A bis 2C schematische Darstellungen von Platten und Schichten gemäß Ausführungsformen der vorliegenden Erfindung.

Embodiments of the present invention will be explained below with reference to the accompanying drawings. Show it:

• The FIGS. 1A to 1C schematic representations of a material according to embodiments of the present invention
  and
• the FIGS. 2A to 2C schematic representations of plates and layers according to embodiments of the present invention.

The Figure 1A shows a schematic representation of a bulk material according to an embodiment of the present invention. Accordingly, a bulk material 100 comprises coated grains 31. The grains 31 comprise grains 30 of granules which are coated on their surface, at least partially, with fibers 10 and a binder 20. The individual grains 31 may vary both in shape and in size, and are not bound together according to this embodiment, so that the bulk material 100, even when touching the grains 31 with each other, is freely deformable or deformable or remains.

The FIG. 1B shows a schematic, general representation of a material according to an embodiment of the present invention. Accordingly, a material 110 comprises the coated grains 31, which are bonded together with another binder 21 to each other. This further binder 21 may correspond to the binder 20, as it is in connection with the Fig. 1A has been described and according to the fibers 10 binds to the surface of a grain 30.

The Figure 1C shows a schematic, general representation of a material according to an embodiment of the present invention. Accordingly, a material 120 comprises the coated grains 31, as well as grains 32 of a further granulate and further fibers 11, which are bonded to each other with the further binder 21 to each other. Although these Representation of both the grains 32 of the other granules and other fibers 11, also inventive and advantageous materials are possible in which either the grains 32 of the other granules or the other fibers 11 are missing.

The FIG. 2A shows a schematic representation of a plate according to an embodiment of the present invention. Accordingly, a plate 130 comprises a material according to an embodiment of the present invention with the coated grains 31 and the further binder 21. The plate 130 may be in the form of a single-layer plate, so that they z. B. can be used in a cost effective manner in equipment, machinery or building application, such as insulation board or load-bearing plate. However, multilayer plates or a coated plate 130 are also possible in order to provide further desired or advantageous properties.

The FIG. 2B shows a schematic representation of an insulating board according to another embodiment of the present invention. Accordingly, an insulating board 140 comprises a material having the coated grains 31 and the further binder 21 according to an embodiment of the present invention or made of this material. The insulation board 140 also has knobs 141, which advantageously increase a surface of the insulation board 140 and / or absorb sound, vibrations, shocks or even heat, intercept or dam.

The Figure 2C further shows a schematic representation of a chipboard according to a Embodiment of the present invention. Accordingly, a chipboard 150 comprises a first chipboard layer 151 and a second chipboard layer 152, between which a material layer 153 is arranged, which comprises a material according to an embodiment of the invention.

The material layer 153 can advantageously improve the mechanical, physical or other properties compared to a normal particle board, wherein a normal chipboard without a material layer 153 or a material inclusion would be provided. By the arrangement of the material layer 153 between the chipboard layers 151, 152 can according to this embodiment also preserve an optical impression of a chip, wood or veneer plate, although although advantageous properties of the material desired, but z. B. the optical properties and / or its aesthetic impression of the material layer 153 are not desirable.

Example in general: For the production of all chipboard, industrially processed chips were used as grains of the additional granules, as far as the middle layer is concerned. The chips were removed from the belt scale after drying and immediately before gluing. The material is composed of various raw material assortments and is subdivided into cover and middle layer fractions due to the process.

Example 1: Production of UF resin bound, three-layer chipboards with low bulk density and with 33% pure Maisextrudat than the Granules of the granules according to independent claim 1 in the middle layer (middle layer chips).

From the industrially produced Spangut and the pure Maisextrudat 20 mm thick three-layer chipboard with a density of 500 kg / m ³ were prepared with an industrially standardized binder composition as another binder. The middle layer shavings were admixed with 33% pure maize trudate.

For the cover and middle layer chips an aqueous solution of a urea-formaldehyde condensation product of the brand Dynea Prefere 10F102 with a solids content of about 68% was used. As a curing accelerator, a 33% aqueous ammonium sulfate solution was used. The hydrophobing agent used was a paraffin-based emulsion of the brand "HYDRAWAX 138" from SASOL GmbH with a solids content of about 50%. The glue liquor of the middle layer as a further binder consisted of 8% UF solid resin, based on dry chip, 2% ammonium sulfate solution (hardener) based on dry solid resin and 1% water repellent based on atro chip.

The glue liquor of the cover layer consisted of 11% UF solid resin based on dry chip, 0.5% ammonium sulfate solution on dry solid resin and 1% water repellents based on dry chip. The chip cake was pressed at 195 ° C for 6 s / mm and a specific pressure of 2.5 N / mm ² .

Example 2: Production of UF resin bonded, three-layer chipboard with less Bulk density and 33% fiber-reinforced maize trudate as the granules of the granules according to independent claim 1 and the fibers on their surface according to dependent claim 2 in the middle layer (middle layer chips).

From industrially produced spun and Maisextrudat, which is reinforced with the fibers bonded to its surface, 20 mm thick three-layer chipboard with a density of 500 kg / m ³ were prepared with an industrially standardized binder composition.

The middle-layer chips 33% of the fiber-reinforced extrudate according to claim 1 and 2 were admixed in this case. For this purpose, the extrudate was coated with 10% fiber type C120 from Rettenmeier. The fixation of the fiber on the extrudate surface was carried out by the adhesive effect of starch from the corn as a binder.

For the cover and middle layer chips an aqueous solution of a urea-formaldehyde condensation product of the brand Dynea Prefere 10F102 with a solids content of about 68% was used. As a curing accelerator, a 33% aqueous ammonium sulfate solution was used. The hydrophobing agent used was a paraffin-based emulsion of the brand "HYDRAWAX 138" from SASOL GmbH with a solids content of about 50%. The glue liquor of the middle layer as a further binder consisted of 8% UF solid resin, based on dry chip, 2% ammonium sulfate solution (hardener) based on dry solid resin and 1% water repellent based on atro chip.

The glue liquor of the cover layer consisted of 11% UF solid resin based on dry chip, 0.5% ammonium sulfate solution on dry solid resin and 1% water repellents based on dry chip. The chip cake was pressed at 195 ° C for 6 s / mm and a specific pressure of 2.5 N / mm ² .

Example 3: Preparation of low bulk density three-layer chipboard bound UF resin and 33% acrylate (as binder) reinforced maize trudate as the granules of the granule of independent claim 1 in the middle layer (middle layer chips).

From industrially produced spangenut and the maize trudate reinforced with acrylate as the binder, 20 mm thick three-layer chipboards having a bulk density of 500 kg / m ³ were prepared with an industrially standardized binder composition.

The middle layer shavings as further granules were admixed with 33% acrylate as binder reinforced extrudate as granules. For this purpose, the extrudate was glued with 12.5% percent of a 50 percent acrylate dispersion type BV 595 of the polymer latex polymer and dried at 60 ° C in a stream of hot air.

As a binder for the top and middle layer chips an aqueous solution of a urea-formaldehyde condensation product of the brand Dynea Prefere 10F102 was used with a solids content of about 68%. As a curing accelerator, a 33% ammonium sulfate aqueous solution was used. As a water repellent came a Paraffin-based emulsion of the brand "HYDRAWAX 138" from SASOL GmbH with a solids content of about 50% is used. The glue liquor of the middle layer as a further binder consisted of 8% UF solid resin based on dry chip, 2% Ammonioumsulfatlösung (hardener) based on dry solid resin and 1% water repellents based on atro chip.

The glue liquor of the cover layer consisted of 11% UF solid resin based on dry chip, 0.5% ammonium sulfate solution on dry solid resin and 1% water repellents based on dry chip. The chip cake was pressed at 195 ° C for 6 s / mm and a specific pressure of 2.5 N / mm ² .

Example 4: Production of UF resin bonded, three-layer chipboard with low bulk density and 33% with acrylate as a binder reinforced Maisextrudat grains of the granules according to independent claim 1 and fibers on the surface in the middle layer (middle layer chips).

From industrially produced spangenut and the maize trudate, which is reinforced with fiber and acrylate, 20 mm thick three-layer chipboards were produced with a density of 500 kg / m ³ with an industrially standardized binder composition. The middle layer chips were mixed with 33% fiber- and acrylate-reinforced extrudate.

For this purpose, the extrudate was glued with 12.5 percent of a 50% acrylate dispersion type BV 595 of the polymer latex, coated with 10% fiber type C120 Fa Rettenmeier and then at 60 ° C in Warm air stream dried.

As a binder for the top and middle layer chips an aqueous solution of a urea-formaldehyde condensation product of the brand Dynea Prefere 10F102 was used with a solids content of about 68%. As a curing accelerator, a 33% aqueous ammonium sulfate solution was used. The hydrophobing agent used was a paraffin-based emulsion of the brand "HYDRAWAX 138" from SASOL GmbH with a solids content of about 50%. The glue liquor of the middle layer as a further binder consisted of 8% UF solid resin, based on dry chip, 2% ammonium sulfate solution (hardener) based on dry solid resin and 1% water repellent based on atro chip.

The glue liquor of the cover layer consisted of 11% UF solid resin based on dry chip, 0.5% ammonium sulfate solution on dry solid resin and 1% water repellents based on dry chip. The chip cake was pressed at 195 ° C for 6 s / mm and a specific pressure of 2.5 N / mm ² .

Example 5: Production of UF resin bonded, three-layer chipboard with low bulk density and 33% acrylate reinforced as a binder Maisextrudat grains of the granules with fibers on the surface in the middle layer (middle layer chips).

From industrially produced Spangut and Maisextrudat, which is reinforced with fiber and acrylate, were 20 mm thick three-layered Particleboard with a density of 500 kg / m ^{3 made} with an industrially standardized binder composition. The middle layer chips were mixed with 33% fiber- and acrylate-reinforced extrudate.

For this purpose, the extrudate was glued with 12.5 percent of a 50 percent acrylate dispersion type DV 455 of the polymer latex polymer coated with 10% fiber type C120 Fa Rettenmeier and then dried at 60 ° C in a stream of hot air.

As a binder for the top and middle layer chips an aqueous solution of a urea-formaldehyde condensation product of the brand Dynea Prefere 10F102 was used with a solids content of about 68%. As a curing accelerator, a 33% ammonium sulfate aqueous solution was used. The hydrophobing agent used was a paraffin-based emulsion of the brand "HYDRAWAX 138" from SASOL GmbH with a solids content of about 50%. The glue liquor of the middle layer as a further binder consisted of 8% UF solid resin based on dry chip, 2% Ammonioumsulfatlösung (hardener) based on dry solid resin and 1% water repellents based on atro chip.

The glue liquor of the cover layer consisted of 11% UF solid resin based on dry chip, 0.5% ammonium sulfate solution on dry solid resin and 1% water repellents based on dry chip. The chip cake was pressed at 195 ° C for 6 s / mm and a specific pressure of 2.5 N / mm ² .

Example 6: Preparation of UF resin bonded, three-layer chipboard with low density of pure industrial chips as a reference.

From pure industrial manufactured Spangut 20 mm thick three-layer chipboard with a density of 500 kg / m ³ and an industrially standardized binder composition were prepared. The size of the glue liquor corresponded in its composition and amount to the experiments described in Examples 1, 2, 3 and 4. All other production parameters are completely identical to Examples 1, 2, 3 and 4. The values of the mechanical properties of Examples 1, 2, 3 and 4 as well as the data of Reference Pattern 5 are shown in Table 1 below. Table 1: Mechanical technological properties of the three-layer, UF resin-bonded chipboard, wherein Extr. extrudate Acrylic. acrylate Rohd. density Q 02h Swelling after 2 hours Q 24h Swelling after 24 hours example Extr. Acrylic. fiber Rohd. lateral tension Q 2h Q 24h [kg / m ³ ] [N / mm ² ] example Extr. Acrylic. fiber Rohd. lateral tension Q 2h Q 24h 1 With without without 497 0.28 4.49 16.86 2 With without With 505 0.30 3.46 13.57 3 With DV646 without 511 0.27 4.99 17.91 4 With DV646 With 505 0.38 8.59 18.76 5 With DV455 With 510 0.40 7.89 19.14 6 without without without 502 0.33 6.55 18.88 (Reference)

Claims (20)

For the formation of plates, layers and moldings suitable material (100, 110, 120) comprising: - grains (30) of granules, - A provided on the surface of the grains (30) of the granules binder (20). Material according to claim 1, characterized in that additionally fibers (10) are provided, wherein the binder (20) binds a part of the fibers (10) to the surface of the coated granules (31) of the granules. Material according to claim 1 or 2,
characterized in that a grain (30) of the granules comprises a porous base, and
characterized in that the pores of the base material are filled with air or with a gas. Material according to one of the preceding claims, characterized in that an average density of the grains (30) is in a range of 0.01 kg / l to 2 kg / l. Material according to one of the preceding claims, characterized in that a mean diameter of a grain size of the grains (30) is in a range of 0.5 mm to 50 mm. Material according to one of the preceding claims, characterized in that a mean diameter of the fibers (10) is in a range of 10 microns to 1 mm. Material according to one of the preceding claims, characterized in that an average length of the fibers (10) is in a range of 100 microns to 50 mm. Material according to one of the preceding claims, characterized in that the binder (20, 21) comprises a cured adhesive, a partially cured adhesive or a curable adhesive. Material according to one of the preceding claims, characterized in that the material comprises constituents, for example grains (32) of a further granulate, characterized in that the coated granules (31) of the granules with the Grains (32) of the further granules are mixed. Material according to one of the preceding claims, wherein the material comprises a further binder (21), characterized in that the further binder (21) binds the coated grains (31) of the granules and / or the grains (32) of the further granules together. Material according to one of the preceding claims, characterized in that the grains (31, 32) to form bulk material (100) are not bound together. Plate (130, 140, 150) or molding comprising a material according to any one of the preceding claims, characterized in that the grains (31, 32) are bonded to one another. A slab (150) comprising a first wood-based material, eg chipboard layer (151), a second wood-based material, eg chipboard layer (152) and a material layer (153) comprising a material according to one of the preceding claims, characterized in that the material layer (153) is arranged between the first chipboard layer (151) and the second chipboard layer (152). Method for producing a material, in particular according to one of the claims, full: - Providing a granulate; - coating the granules (30) of the granules with fibers (10) and a binder (20); - Stabilizing the binder (20), so that the fibers (10) are stably bonded to a surface of the grains (30). A method according to claim 14, characterized in that the provision of the granules comprises comminuting a starting material into grains (30, 32) to a predetermined average grain size. Method according to one of the preceding method claims, characterized in that the coating of the grains (30) comprises wetting the surface of the grains (30) with the binder (20) and applying the fibers (10) to a surface of the grains (30) , A method according to any one of the preceding method claims, characterized in that the coating of the grains (30) comprises wetting the fibers (10) with the binder (20) and applying the wetted fibers to a surface of the grains (30). Method according to one of the preceding method claims, characterized in that the stabilization comprises an at least partial curing of the binder (20). Method according to one of the preceding method claims, characterized in that the method comprises mixing the granules coated with the fibers (10) with a further granulate. Method according to one of the preceding method claims, characterized in that the method comprises bonding the grains (31, 32) to one another with a binder (20) and / or a further binder (21).

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