DE102019117439A1 - Extruded profile - Google Patents

Abstract

An extruded profile (1, 10) made of a mixture of natural fibers and a polymer material comprises a plurality of hollow chambers (5, 15) which extend in the longitudinal direction of the profile (1, 10), the proportion of the hollow chambers (5, 15) being related to the total volume of the profile (1, 10) is between 10% and 50% and the hollow chambers (5, 15) have a size between 10 mm 2 to 200 mm 2. Less moisture penetrates into the relatively small hollow chambers, even if the profile is installed with the longitudinal direction horizontal.

Description

The present invention relates to an extruded profile made of a mixture of natural fibers and a polymer material, with a multiplicity of hollow chambers which extend in the longitudinal direction of the profile.

For extruded floor panels it is from the DE 20 2007 015 479 U1 known to provide these with hollow chambers so that the weight of the panels is comparatively low in relation to the volume. Even if the panels can be produced with high rigidity with such hollow chambers, there is the disadvantage that they always have to be laid with a gradient in the outside area so that water that penetrates the hollow chambers flows off to one side and does not remain in the panel, which can lead to odor nuisance, mold growth or, in winter, also to cracks from freezing processes. Laying with a slope can lead to errors and the sub-floor can also deform, for example due to ground frost.

Therefore, high-quality floor panels for laying outdoors are mostly made as full profiles without hollow chambers, as is the case, for example, from the EP 2 734 685 B1 is known. Such floor panels can also be laid exactly horizontally and can therefore also be used as a sports floor. In addition, it is known to provide extruded panels with a filler, such as a reinforcement profile, as shown in FIG EP 2 527 559 is known, so that penetration of moisture into the closed structure is prevented. However, this leads to a higher weight in relation to the volume of the panels.

It is therefore the object of the present invention to create an extruded profile made of a mixture of natural fibers and a polymer material, in which the risk of moisture damage is reduced and which has a low weight in relation to the volume.

This object is achieved with an extruded profile having the features of claim 1.

In the extruded profile according to the invention made of a mixture of natural fibers and a polymer material, a large number of hollow chambers are provided, which extend in the longitudinal direction of the profile, the proportion of hollow chambers based on the total volume of the profile being between 10% and 50% and the hollow chambers being one Have a size between 10 mm ² to 200 mm ² . As a result, a large number of smaller hollow chambers are produced, which ensure a certain weight saving, but have the advantage over a few large hollow chambers that only little moisture can penetrate into the hollow chambers. The size of the hollow chambers with a cross-section between 10 mm ² to 200 mm ² does not completely prevent a certain amount of moisture from being absorbed into the hollow chamber, but only a smaller amount of moisture is absorbed per hollow chamber, which is true both when warm Temperatures lead to less impairment than also at minus degrees, since a small amount of water does not lead to the cracks in the material by freezing, as is the case with the panels from the prior art. In addition, due to the increased friction and the capillary forces, the water penetrates less deeply into the profile, so that any liquid in the edge area also dries out more quickly.

The cross-section of the hollow chambers in the profile is preferably between 20 mm ² to 100 mm ² , in particular between 30 mm ² to 80 mm ² . As a result, a large number of small openings are provided which only allow small amounts of moisture to enter. In relation to the total volume of the profile, calculated using the external dimensions of the profile with the hollow chambers, the proportion of hollow chambers is preferably between 20% to 45%, in particular 25% to 42%.

In the profile, in a cross-sectional view, at least two rows of hollow chambers are arranged one above the other, preferably three to six rows of hollow chambers. When the profile is laid horizontally, there are several rows one above the other in the vertical direction, and only a small amount of moisture can flow into each of the hollow chambers.

To prevent the entry of liquid into the hollow chambers, these are preferably V-shaped on their upper side when the profile is in the mounted position, with the tip oriented upwards. As a result, water that runs down the end face of the profile can flow away via the V-shaped design of the hollow chamber in the upper area, mainly along the webs, without flowing into the hollow chamber. The top of the hollow chamber does not have to be designed in an exactly V-shape, but can also be arcuate or with one or more kinks.

In the mounted position of the profile, the webs between the hollow chambers are preferably aligned inclined to the horizontal, in particular at an angle greater than 10 °. As a result, water that runs down the end face of the profile can flow downwards via the webs due to the capillary effect without getting into the hollow chambers. The webs can, for example, be partially aligned vertically and preferably larger at an angle Inclined 20 ° to the horizontal, so that the liquid can flow off over the webs at all points between the hollow chambers.

The wall thickness of webs between two adjacent hollow chambers can be in a range between 1.5 to 4 mm, in particular between 1.8 mm to 3 mm, so that on the one hand there is sufficient strength and on the other hand the webs have a thickness on the end faces of the profile own, which is used to guide the liquid flowing down.

The hollow chambers are preferably designed as a hexagon, octagon or round or oval in cross section. If the hollow chambers are designed as polygons in cross-section, a point is preferably directed upwards on the upper side in order to facilitate the outflow of the liquid. The distance between two opposing walls on the hollow chambers is preferably between 3 mm to 8 mm, in particular between 4 mm to 6 mm, so that the hollow chambers are made comparatively small.

The extruded profile made of a mixture of natural fibers and a polymer material preferably has a proportion of natural fibers that is greater than 50%, in particular between 60% and 85%, so that the profile is mainly made from renewable raw materials, which is comparatively environmentally friendly because the profile is made weatherproof by the polymer material. The natural fibers can be of any length, in particular also shorter than 1 mm. Wood chips, wood fibers, rice husks, straw, hay, waste paper or all fibers containing lignocellulose can be used as natural fibers. Polypropylene, polyethylene or other polymers and mixtures of such polymers can be used as the polymer material. The high proportion of natural fibers results in a very viscous mass during extrusion, which can be processed in a similar way to wood when cooled.

The profile is preferably used as a floor panel, which is mounted on a substructure, for example as a terrace floor or as a sports floor, in particular outdoors. Such a floor panel can be designed to be at least 5 times as wide as high in a direction perpendicular to the longitudinal direction, so that even large areas can be effectively covered with the profile.

To increase the slip resistance, the profile can optionally have grooves and ribs on at least one side, in particular an upper side. The profile can also have the same or different profiling on opposite sides. To fix the profile, grooves can be formed on opposite longitudinal sides, in particular wedge-shaped grooves, into which fastening means are inserted in order to fix the profile on a wall or a floor.

• 1A bis 1C mehrere Ansichten eines ersten Ausführungsbeispiels eines Profils, und
• 2A bis 2E mehrere Ansichten eines zweiten Ausführungsbeispiels eines erfindungsgemäßen Profils.

The invention is explained in more detail below on the basis of two exemplary embodiments with reference to the accompanying drawings. Show it:

• 1A to 1C several views of a first embodiment of a profile, and
• 2A to 2E several views of a second embodiment of a profile according to the invention.

A profile 1 can be used as a substructure for a floor covering, but also as a post or beam for other structures outdoors, whereby the profile 1 when used as a substructure for a floor covering, an upper side 2 and a bottom 3 having. There are grooves on opposite long sides 4th provided to the profile 1 to be fixed to a substrate.

The profile 1 comprises a multitude of small hollow chambers 5 which, based on the cross-sectional area, make up between 10% and 50% of the cross-sectional area of the profile 1 take in. The hollow chambers 5 are arranged in several rows one above the other. Every hollow chamber 5 has a size between 10 mm ² to 200 mm ² , in particular between 30 mm ² to 50 mm ² . The shape of the hollow chambers 5 is hexagonal, but can also be octagonal, round, oval or in the form of another polygon. One side a of the hexagon is, for example, in a range between 3 mm and 5 mm. The hollow chambers 5 can be arranged at regular or irregular intervals and, based on a vertical or horizontal plane, also symmetrically in the profile 1 to be ordered.

The profile 1 , like the one in 2 shown profile 10 , consists of a mixture of natural fibers and a polymer material, the proportion of natural fibers preferably being above 50%, for example between 65% to 85%. Wood fibers, wood chips, straw, hay, rice husks or other natural fibers can be used as natural fibers, which can optionally also be mixed with other ingredients, such as a proportion of cement or other substances. In addition, a polymer material is added for the extrusion, for example polypropylene, polyethylene or other polymers or polymer mixtures. The profiles produced in this way 1 and 10 are weatherproof because the natural fibers are embedded in a polymer matrix.

The profile 10 includes on one top 12 Ribs 11 , between which grooves are arranged, to increase the slip resistance. On a bottom 13th can also be arranged grooves or ribs, so that the profile 10 can be laid with both main surfaces facing up. The profile encompasses the opposite long sides 10 Grooves 14th , which are wedge-shaped and are used to fix fastening means by means of which the profile 10 on a substructure such as the profile 1 , can be fixed. The profile 10 is designed as a floor panel, which in cross section has a significantly larger width than height, which is for example at least 5 times greater than the height.

The profile 10 also includes a plurality of hollow chambers 15th , which are designed as a hexagon, each hollow chamber in the assembled position 15th is V-shaped at the top, so that the material of the profile 10 is arranged inclined to the horizontal in this area. As in the enlarged views of the 2C to 2E shown are located between adjacent hollow chambers 15th vertical bars 16 and 18th where water streamed on one face of the profile 10 runs along, can flow downwards. Between the vertical bars 16 and 18th are bridges 17th formed, which are also aligned inclined to the horizontal, preferably at an angle between 20 ° and 50 °. This allows the water to flow over the bars 18th , 17th and 16 flow downwards and only a small proportion reaches the hollow chambers 15th .

With the profile 10 are several rows of hollow chambers 15th arranged one above the other. In the illustrated embodiment, there are three rows of hollow chambers 15th provided one above the other, the number of rows of hollow chambers 15th between 2 and 10 depending on the design of the profile 10 .

The bridges 16 , 17th and 18th between the hollow chambers 15th preferably have a wall thickness which is between 1.5 mm to 4 mm, in particular 1.8 mm to 3 mm, so that water on the end face of each profile 10 along the footbridges 16 , 17th and 18th can flow away. The proportion of hollow chambers 15th based on the total volume of the profile 10 is, as in the previous exemplary embodiment, between 10% and 50%, for example between 25% and 42%. Every hollow chamber 15th has a size between 30 mm ² to 80 mm ² , with one side length a of the hexagon can be in a range between 3.5 mm to 6 mm.

The geometry of the hollow chambers 15th does not necessarily have to be hexagonal, but can also be triangular, square, pentagonal, heptagonal, octagonal or formed by another polygon. They can also be used as hollow chambers 15th round shapes or mixtures of round and square shapes can also be used, for example a circle or an oval.

For mounting the profiles 1 and 10 these are cut to the desired length and then fixed to a floor or wall using fasteners.

List of reference symbols

1

profile

2

Top

3

bottom

4th

Groove

5

Hollow chamber

10

profile

11

rib

12th

Top

13

bottom

14th

Groove

15th

Hollow chamber

16

web

17th

web

18th

web

a

Side length

QUOTES INCLUDED IN THE DESCRIPTION

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

Patent literature cited

• DE 202007015479 U1 [0002]
• EP 2734685 B1 [0003]
• EP 2527559 [0003]

Claims (13)

Extruded profile (1, 10) made of a mixture of natural fibers and a polymer material, with a multiplicity of hollow chambers (5, 15) which extend in the longitudinal direction of the profile (1, 10), characterized in that the proportion of hollow chambers (5, 15) based on the total volume of the profile (1, 10) is between 10% and 50% and the hollow chambers (5, 15) have a size between 10 mm ² to 200 mm ² . Profile according to Claim 1 , characterized in that the hollow chambers (5, 15) have a size between 20 mm ² to 100 mm ² , in particular between 30 mm ² to 80 mm ² . Profile according to Claim 1 or 2 , characterized in that the proportion of the hollow chambers (5, 15) based on the total volume of the profile (1, 10) is between 20% to 45%, in particular 25% to 42%. Profile according to one of the preceding claims, characterized in that in a cross-sectional view at least two rows of hollow chambers (5, 15) are arranged one above the other, preferably three to six rows of hollow chambers (5, 15). Profile according to one of the preceding claims, characterized in that the hollow chambers (15) in the assembled position of the profile (10) are V-shaped on their upper side with a point upwards. Profile according to one of the preceding claims, characterized in that in the mounted position of the profile (10) the webs (16, 17, 18) between the hollow chambers (15) are aligned inclined to the horizontal, in particular at an angle greater than 10 °. Profile according to one of the preceding claims, characterized in that the wall thickness of webs (16, 17, 18) between adjacent hollow chambers (15) is between 1.5 mm to 4 mm, in particular 1.8 mm to 3 mm. Profile according to one of the preceding claims, characterized in that the hollow chambers (5, 15) are designed in cross section in the shape of a hexagon, octagon or round. Profile according to one of the preceding claims, characterized in that the distance between two opposing walls of a hollow chamber (5, 15) is between 3 to 8 mm, in particular between 4 to 6 mm. Profile according to one of the preceding claims, characterized in that the proportion of natural fibers in the mixture is greater than 50%, in particular between 60% and 85%. Profile according to one of the preceding claims, characterized in that the profile (10) is at least 5 times wider than it is high in the direction perpendicular to the longitudinal direction. Profile according to one of the preceding claims, characterized in that the profile (10) has a profile with grooves and ribs (11) on at least one side. Profile according to one of the preceding claims, characterized in that the profile (1, 10) has a groove (4, 14) on opposite longitudinal sides for inserting fastening means in order to fix the profile (1, 10) to a wall or a floor .

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