The present invention relates to a fastening element for dry construction elements and to a method for the production of such a fastening element.
Swiss patent specification CH 486 281 describes a corrugated panel made of metal with two corrugations that intersect each other. The corrugations form a depression on one side of the corrugated panel, and an elevation on the other side. In order to produce the corrugated panel, a strip of metal is fed between two toothed rollers.
Another sheet metal material having projections and recesses is known from European patent application EP 0 674 551 B1, which describes a method for the production of such a material. According to this publication, the rollers used for the production have teeth in involute form.
In the method known from European patent application EP 0 891 234 B 1, the rollers used for the deformation of a sheet metal material are rollers that have rounded teeth on the top.
PCT/GB81/00095 discloses a metal sheet with a plurality of projections as well as a method for its production.
Fastening elements for dry construction elements are normally affixed with screws that are screwed into or through the sheet metal material. If the fastening element is configured to be flat at the screwing site, it is not always easy to precisely position the screws, since the screws can slip away when they are being screwed in, which is normally done with a battery-operated screwdriver. The provision of a corrugated area alone as is known from the state of the art, however, would not lead to optimal handling of the fastening element.
Therefore, an objective of the present invention provides a fastening element for dry construction elements that can be mounted especially easily, as well as a method for the production of such a fastening element.
The present invention provides a fastening element for dry construction elements that has a sheet metal material having at least one joining section, whereby the sheet metal material is provided with a plurality of depressions in the area of the at least one joining section, whereby the depressions are formed by deformed areas of the sheet metal material, so that the depressions on one side of the sheet metal material form elevations on the opposite side of the sheet metal material, whereby the depressions are each surrounded by sliding surfaces that are at least partially slanted relative to an imaginary center line of the sheet metal material and that are meant for connecting means that are to be inserted into or through the joining section.
The sliding surfaces allow an especially simple affixation of the fastening element. If screws are used for this purpose then, thanks to the effect of the sliding surfaces, they can slide into the next depression and be screwed in there. In this manner, the screws can always be inserted at precisely defined positions without this calling for any extra effort.
Screws can be inserted especially easily if the sliding surfaces each have an inclination angle of more than 5°, especially more than 7°, relative to the imaginary center line of the sheet metal material.
According to an especially advantageous embodiment of the invention, it is provided that, in the at least one joining section, the sheet metal material has no surface that is parallel to the imaginary center line of the sheet metal material, except for the depressions and/or elevations.
According to the invention, it has proven to be especially advantageous for the center point distance between the individual depressions to range between three times and ten times the thickness of the sheet metal material, especially between four times and six times the thickness of the sheet metal material. The term ‘thickness’ here refers to the thickness of the sheet metal material itself, that is to say, without taking depressions and elevations into account. In this context, it is achieved at the same time that the fastening element is easy to mount and has high stability values.
Moreover, it has proven its worth for the elevations and the depressions to be provided on both sides of the sheet metal material.
High stability, along with easy mounting, are also promoted by the fact that the elevations have a height that is between 0.8 times and 1.4 times the thickness of the sheet metal material, measured from the imaginary center line of the sheet metal material, and/or in by the fact that the depressions have a depth between 0.3 times and 2.0 times, especially between 0.3 times and 1.0 time the thickness of the sheet metal material, measured from the outer enveloping surface of the sheet metal material. The outer enveloping surface is formed by the highest points of the elevations.
According to an advantageous embodiment of the invention, it is provided that the thickness of the sheet metal material is between 0.2 mm and 2.0 mm, especially between 0.3 mm and 0.8 mm, preferably between 0.4 mm and 0.7 mm.
According to the invention, it can also be provided that the total height of the deformed sheet metal material in the joining section amounts to between two times and three times the thickness of the sheet metal material. The total height here—in contrast to the material thickness—is measured, taking into account the elevations that might be present on both sides.
According to the invention, the fastening element can be configured especially as a C-section, U-section, L-section, top hat section, T-section or Z-section.
An objective upon which the invention is based provides means of a method for the production of a fastening element according to the invention, in which an essentially flat sheet metal material is fed through a nip formed between a top roller having first teeth and a bottom roller having second teeth, in order to create the depressions and elevations as well as the slanted sliding surfaces.
Since the top roller and/or the bottom roller has a plurality of toothed disks arranged next to each other, depressions and elevations can be created in several rows next to each other. Such top rollers and bottom rollers are also very easy and cheap to produce since the individual toothed disks can be processed separately and are only joined at the end to form the top rollers and bottom rollers.
It is advantageously provided that the toothed disks have a row of first or second teeth on their circumference.
According to the invention, it has proven worthwhile for the teeth to each have four straight flanks that are preferably slanted by 25° to 35°, preferably by 30°, relative to the center plane of the disk.
Furthermore, it can be provided according to the invention that the first teeth of the top roller and the second teeth of the bottom roller intermesh and/or the top roller and the bottom roller are arranged in such a way that one of the first teeth protrudes into the middle of a gap between two of the second teeth.
Additional objectives, features, advantages and application possibilities of the present invention ensue from the description below of embodiments making reference to the drawings. In this context, all of the features described and/or illustrated, either on their own or in any desired combination, are the subject matter of the invention, also irrespective of their formulation in individual claims or of their referring back to other claims.
The following is shown:
a: a perspective view of a fastening element according to the invention, in a first embodiment;
b: an enlarged view of a cross section through part of the joining section of the fastening element of
a-4c: screwing in of a screw into a joining section of a fastening element according to the invention;
a: a schematic view of a top roller and a bottom roller according to the invention;
b: an enlarged section of
a: a schematic top view of a toothed disk of the top roller or bottom roller;
b: the toothed disk of
a: a schematic top view of another toothed disk of the top roller or bottom roller;
b: the toothed disk of
a-8c: enlarged details of the individual teeth of the toothed disks of
a: a schematic simplified view of the arrangement of the individual toothed disks of the top roller and bottom roller;
b: an enlarged detail of
a, 2 and 3 each show a fastening element 1, 1′, 1″ for dry construction elements. The fastening elements 1, 1′, 1″ are each made of a profiled sheet metal material having a bottom section 2 at whose ends bent leg sections 3 are provided. The leg sections 3, each of which forms a fastening flange, extend essentially perpendicular to the bottom section 2.
In the embodiments shown in
The fastening element 1″ shown in
The described fastening elements 1, 1′, 1″ can be employed in dry construction as support structures, for example, for building partitions, suspended ceilings, etc.
The fastening elements 1, 1′, 1″ shown are made of metal, especially of galvanized sheet steel and, by means of a shaping procedure, are converted from an essentially flat sheet metal material into the three-dimensional shapes of the fastening elements 1, 1′, 1″ shown.
The sheet metal material of the fastening elements 1, 1′, 1″ has at least one joining section 5. In the embodiments shown in
The fact that, in the fastening elements 1, 1′ shown in
b shows an enlarged partial section through the sheet metal material of the fastening element 1 shown in
Here, the depressions 6 are each surrounded, at least partially, by sliding surfaces 9 that are slanted relative to an imaginary center line M of the sheet metal material and that are meant for connecting means that are to be inserted into or through the joining section 5. The sliding surfaces 9 here have an inclination angle N of more than 5°, especially more than 7°, with respect to the imaginary center line M of the sheet metal material. Accordingly, areas leading to the appertaining depression 6 are formed around the depression 6. As a consequence, screws can slide on the sliding surfaces 9 towards the depressions 6, as will be described in detail below.
It is also clear from
According to the invention, the center point distance A between the individual depressions 6 preferably amounts to between three times and ten times the thickness S of the sheet metal material, especially between four times and six times the thickness S of the material. If, as shown, the depressions 6 are present on both sides of the joining section 5, the center point distance A between two adjacent depressions 6 is taken, irrespective of the side of the sheet metal material where the depression 6 in question is formed.
The elevations 7 preferably have a height H between 0.8 times and 1.4 times the thickness of the sheet metal material, measured from the imaginary center line M of the sheet metal material.
The depressions 6 have a depth T between 0.3 times and 2.0 times, especially between 0.3 times and 1.0 time the thickness S of the sheet metal material, measured from the outer enveloping surface F of the sheet metal material. The outer enveloping surface F is formed by the highest point of the individual elevations 7.
The thickness S of the sheet metal material preferably amounts to between 0.2 mm and 1.0 mm, especially between 0.3 mm and 0.8 mm, preferably between 0.4 mm and 0.7 mm.
Here, the depressions 6 and elevations 7 have the effect of increasing stability. This means that, at the same material thickness, the fastening element is considerably stronger than conventional fastening elements. This makes it possible to reduce the thickness S of the sheet metal material and thus also the production costs and yet to achieve a high strength.
The depressions 6 and elevations 7 are configured in such a way that the total height of the deformed sheet metal material in the joining section 5 amounts to between two times and three times the thickness S of the sheet metal material.
a, 4b and 4c illustrate the advantageous effect of the sliding surfaces 9. If, as shown in
For the production of the fastening elements 1, 1′, 1″, an essentially flat sheet metal material 15 is fed through a nip formed between a top roller 12 having first teeth 11 and a bottom roller 14 having second teeth 13. This can be clearly seen in
The sheet metal material 15 processed in this way can then be shaped in subsequent steps (not shown here) so as to yield, for instance, the C-section shown in
The top roller 12 and the bottom roller 14 each have a plurality of toothed disks 16, 17 arranged next to each other, which are shown in greater detail in
The toothed disks 16, 17 each have a cavity 20 in their center that serves to accommodate a drive shaft (not shown here). Feather key grooves 21 are formed in the toothed disks 16, 17 in order to generate a positive fit between them and the drive shaft.
The toothed disks 16, 17 shown in
a illustrates in schematic form how the individual toothed disks 16, 17 are combined to form the appertaining top roller 12 and bottom roller 14.
The top roller 12 and the bottom roller 14 are only shown schematically and in a section in
The top roller 12 and bottom roller 14 also have several spacers D. They allow the sheet metal material to be fed between the top roller 12 and the bottom roller 14 without the sheet metal material becoming deformed in the areas formed by the spacers.
The top roller 12 and bottom roller 14 are each synchronously driven by toothed gears, as shown in
As can be seen in
Number | Date | Country | Kind |
---|---|---|---|
DE102006021556.7 | May 2006 | DE | national |
PCT/EP2007/003902 | May 2007 | EP | regional |
This is a divisional application of U.S. patent application Ser. No. 12/291,152, filed on Nov. 6, 2008, which claims priority to German patent application No. DE 10 2006 021 556.7 filed on May 8, 2006, through PCT/EP2007/003902 filed on May 3, 2007, hereby incorporated by reference herein.
Number | Date | Country | |
---|---|---|---|
Parent | 12291152 | Nov 2008 | US |
Child | 13212704 | US |