EP1184525B1 - Fibreboard - Google Patents

Abstract

The fiberboard, using fibers with a lignocellulose content and a polyurethane glue as the bonding agent, has a mean bulk density of 350 kg/m<3>. The density curve in the core (1) is constant over a range of two-thirds of the board thickness (s), symmetrically to the center (M). The deviation between the mean density at the core and the maximum density at the covering layer (2) is a maximum of 15% and, at the most, 30 kg/m<3>.

Description

The invention relates to a plate of lignocellulosic fibers and and a Polyurethane glue as a binder.

Such a fiberboard is known for example from DE 196 00 478. Such Plates are used as structural panels, to cover ceilings and walls or for example used in the furniture industry. The known plates are based on their size quite heavy and therefore partly cumbersome to handle. Will you used as structural panels, they must be fastened with special screws to prevent the plate from breaking out at the point of attachment and from the substrate can be solved. The cutting of the panels must be done carefully to to avoid a break at the kerf. Overall, the processing requires The building boards have some experience to produce high quality results achieve. In particular, inexperienced home improvement can handle the plates difficult.

The invention has for its object to improve the known plate.

To solve the problem, the plate described above is characterized by a mean density of not more than 350 kg / m ³ , wherein the density profile in the core of the plate over a range of two-thirds of the plate thickness is symmetrical to the center is substantially constant, and the Deviation of the average density in the core to the maximum density in the top layer is not more than 15% but not more than 30 kg / m ³ .

By this configuration, a very light plate with a substantially created constant density gradients. Due to their low weight, the Handle plate well. The substantially constant density gradient leads to a high bending stiffness and also facilitates the processing of the plate. So is it possible to make cutouts of basically arbitrary depth, which makes it well used as a construction and furniture board despite its low weight can be. The constant density allows, for example, building boards easy way to attach to the substructure by using one commercially available compressed air nail device can be angegetackert. The over the cross section constant density ensures that the nail does not pass through the plate can be shot through. It is also possible to see the side edges of the plate provided with a tongue / groove profile. This makes it possible to be contiguous Simply connect panels together and achieve a windproof connection joint which does not need to be isolated.

The maximum density in the cover layer may be smaller or larger than the middle one Density in the core. If the density in the top layer is smaller than in the core, the Impact sound properties of the plate significantly improved.

Due to the special design of the density, a thermal conductivity λ of 0.04 to 0.05 W / mK can be set for a plate with an average density in the range of 180 kg / m ³ . This insulates such a fiberboard as a mineral insulating material.

The low weight of the plate also allows it, even plate thicknesses of 30 mm or 80 mm without the handling of the plate particularly limited would. This allows a very good thermal insulation realized with the plate become. The plate also has a good sound insulation, especially impact sound insulation on. So it can not only as a door panel, but also as a floor substructure for screed-free floors for occupancy with carpets or the like Find use. The plate surface is so fine that cement slurry can not penetrate and the impact sound insulation thereby not destroyed becomes. A floor construction can be made cheaper. So far have been Mineral fiber mats used, on which a barrier film had to be placed, to prevent the penetration of the cement slurry.

Preferably, the plate has a thickness of 30 mm to 80 mm.

Figur 1 -

einen Teilausschnitt einer Platte im Querschnitt;

Figur 2 -

das Rohdichte-Profil bezogen auf den Querschnitt eines ersten Ausführungsbeispiels;

Figur 2a -

das Rohdichte-Profil bezogen auf den Querschnitt eines zweiten Ausführungsbeispiels;

Figur 3 -

eine Distanzkurve zur Herstellung einer erfindungsgemäßen Platte;

With the aid of a drawing, an embodiment of the invention will be explained in more detail below. It shows:

FIG. 1 -

a partial section of a plate in cross section;

FIG. 2 -

the density profile with respect to the cross section of a first embodiment;

Figure 2a -

the density profile relative to the cross section of a second embodiment;

FIG. 3 -

a distance curve for producing a plate according to the invention;

In the ultra-light wood fiber board, a core 1 and two cover layers 2 forming the top and bottom of the board are formed. The plate has an average density which is less than or equal to 350 kg / m ³ . In the core 1, the average density over at least two-thirds of the plate thickness s symmetric to the center line M is constant. The average density in the outer layers 2 deviates by a maximum of 15% from the average density in the core 1, but it is at most 30 kg / m ³ more. On one side edge, a spring (3) can be milled out of the plate, which corresponds to a not shown here on the opposite side edge groove, so that two plates can be nested and a wind and moisture-proof connection is created.

To prepare the plate, the mixed with the binder wood fibers with a residual moisture content of 7% to 12% scattered and formed into a mat. The The mat is warmed up and supplied with additional heat energy in a Contipresse pressed to the plate, the mat is first continuously up to the Set thickness s of the plate (for example, 30 mm) is pressed and the pressing pressure for a longer period of time is kept constant when the target strength s is reached.

Then it is driven on with a constant pressure. The specific one Press time is 7 to 10 seconds. Advantageously, a specific pressing time has Exposed by 8.5 seconds. Very good results were achieved at a feed rate of 130 mm / s.

FIG. 3 shows in the distance curve the setting of the press (distance) over the length of its frame. The corresponding table of values is reproduced below, distance I indicating the setting for a plate of conventional design and distance II indicating the setting for a plate according to the invention. Frame [m] Distance I Distance II 1 44.00 60,00 2 39.00 53,00 3 38.50 50.00 4 37.50 46,00 5 37,00 43,00 6 36.60 40,50 7 37,00 38,00 8th 37,00 38,00 9 37,00 36,50 10 37,00 36,50 11 37,00 34,50 12 37,00 34,50 13 37,00 34,50 14 36.70 33.50 15 36.70 33.50 16 36.70 33.50 17 38,00 33,00 18 38,00 33,00 19 40,00 32.50 20 40,00 32.50 21 41,50 31,95 22 41,50 31,95 23 41,50 31,95 24 41,30 31.85 25 41,30 31.85 26 41,30 31.85 27 40,50 31.65 28 40,50 31.65 29 36,50 31.65 30 36,50 31.65 31 31.50 31.45 32 31.50 31.45 33 31.00 31.45 34 31.00 31.45 35 31.00 31.45 36 31.00 31.45 37 31.00 31.45 38 31.00 31.45 39 31.00 31.45

From Figure 3 it will be seen that for the production of the plate according to the invention the Distance in the press is continuously reduced. Where the starting distance of 60 mm is significantly larger for a plate with the final thickness of 31.45 mm than 44 mm in conventional plate production.

Claims (4)

1. Board made of fibres with a lignocellulose content and a polyurethane glue as the bonding agent, characterized in that the board has a mean bulk density of no more than 350 kg/m³, the density curve in the core (1) being substantially constant over a range of two-thirds of the board thickness (s), symmetrically with respect to the centre (M), and the deviation between the mean density in the core (1) and the maximum density in the covering layer (2) being a maximum of 15% but at most 30 kg/m³.
2. Board according to Claim 1, characterized by a thermal conductivity (λ) of 0.04 - 0.05 W/mK.
3. Board according to Claim 1 or 2, characterized by a thickness (s) of at least 30 mm, in particular 30 mm to 80 mm.
4. Board according to one of Claims 1 to 3, characterized in that a tongue-and-groove profile is formed on at least two opposite side edges.

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