WO2014184092A1 - Fastening means and method for fastening an insulating-material panel, and corresponding arrangement - Google Patents

Abstract

The invention relates to a fastening means for fastening an insulating-material panel (26) on a substructure (22), wherein the fastening means (10) has a pressure-exerting disc (12) and an elongate fastening element (16) projecting transversely therefrom. A heat-insulating material (14) is arranged in the manner of a heat-insulating disc on an upper side of the pressure-exerting disc, and is advantageously fastened in a non-releasable manner thereon or produced in one piece therewith. The invention also relates to an arrangement having a substructure and an insulating-material panel, and to a method for fastening an insulating-material panel on a substructure.

Description

 description

Fastening means and method for fixing an insulation plate and corresponding

 arrangement

The invention relates to a fastening means according to the preamble of claim 1. Furthermore, the invention relates to an arrangement with a substructure and an insulating panel, which is fastened to the substructure by means of a number of fastening means. Furthermore, the invention relates to a method for fixing an insulating plate to a substructure.

Insulating boards are commonly used to reduce heat conduction through walls and thus save energy for heating or cooling, especially on buildings. They can be made of different materials such as Styrofoam, polyurethane foam or wood wool.

As a substructure for such insulation panels mainly walls of buildings are used. For attachment of insulation boards to such substructures several ways are known. For example, an insulation panel can be glued to the substructure by means of a suitable adhesive. However, this makes it difficult to replace an insulation board. Therefore, the use of fasteners is preferred with which an insulating plate can be releasably secured to the substructure.

A generic fastening means may be formed as a simple screw which holds the insulation plate form-fitting manner to the substructure. A more complex and better adapted to the purpose fastener can be found for example in DE 10159632 B4. The fastener shown there has a cutting device which cuts into the insulation board and thus engages the fastener therein. However, this design is very expensive. Task and solution

The invention is therefore based on the object to provide a fastening means which can be easily applied and at the same time does not affect the insulating effect of the insulation board. Furthermore, the invention has for its object to provide an arrangement with at least one insulating plate and with a substructure, wherein the insulating material plate by means of at least one fastening means according to the invention at the Unterkon- is attached. In addition, the invention has for its object to provide a method for fixing an insulating plate to a substructure by means of a fastener according to the invention.

The invention solves the problem by a fastening means according to claim 1, an arrangement according to claim 13 and a method according to claim 15. Advantageous and preferred embodiments are subject matter of further claims and are explained in more detail below. Some of the features are described only for the fastener, the arrangement or the method. However, they should be able to apply independently for both the fastener and the arrangement and the method independently. The wording of the claims is incorporated herein by express reference.

An inventive fastening means for fixing an insulating plate to a substructure has a thrust washer and a transversely projecting from an underside of the thrust washer elongated fastener on. The elongated fastening element may in particular be a fastening element in the manner of a long threaded screw at the free end. According to the invention, it is provided that thermal insulation material is arranged on the top side of the pressure disk in the manner or in the form of a thermal insulation disk.

The fastening means according to the invention enables the thermal insulation material of the fastening means to partially replace a material from which the insulating panel to be fastened is made. This makes it possible to sink the thermal insulation material of the fastener in the insulation board, so that a smooth outer surface is formed, at the same time the insulating effect of the insulation board or the entire arrangement is almost completely preserved.

The pressure disk can be a flat disk, which typically has a thickness of a few millimeters and a diameter of a few centimeters. On this, a thermal insulation material with a flat surface can be easily applied. The pressure plate is preferably circular, which facilitates a fastening operation by turning the fastening means, for example, as is usual in the attachment of ordinary screws. For example, a round pressure disk can advantageously be introduced into a round depression of the insulation board. Provision of appropriate means, as described in more detail below, can be milled or cut with a round pressure washer and a corresponding recess during the attachment process in an insulation board. The fastening element projects transversely or at right angles, which means that the fastening element assumes an at least approximately right angle to the thrust washer. Preferably, the fastener is perpendicular to the pressure plate, which allows a particularly simple installation. The length of the fastening element is preferably greater than the thickness and the diameter of the pressure disk. In the present case, this is understood to mean, for example, the term "long." In this case, the free end is that end of the fastening element which is opposite the thrust washer The length of the fastening element is typically adapted to the thickness of an insulating panel to be fastened Thrust washer is preferably recessed in the insulation board, and that the fastener should also engage with the substructure in a suitable manner or with sufficient length to secure the insulation board to the substructure.

In order to anchor the fastening element in the substructure, the fastening element is preferably fastened in a bore in the substructure, similar to an ordinary screw. For this purpose, for example, first a dowel be inserted into the hole in the substructure, in which then the screw is screwed. This allows for reliable anchoring in most situations.

The thermal barrier material preferably has a thickness of 0.5 cm to 3 cm, more preferably from 0.7 cm to 1, 5 cm. Such thicknesses have proven to be advantageous in practice. Based on the diameter of the thermal insulation material, the thickness is preferably between 5% and 30% of the diameter.

Preferably, the thermal insulation material of non-combustible and / or thermally insulating material or corresponding material or has such predominantly, in particular from the group polystyrene, polyurethane foam, insulating cork, wood wool, wood fiber, kosfaser, mineral wool, silicate or phyllosilicate. If a sheet silicate is used, it preferably consists of vermiculite and is more preferably in expanded form. The materials mentioned have proved to be advantageous for the application relevant here, particularly advantageous silicate or phyllosilicate, especially with regard to fire resistance and fire resistance. More preferably, the thermal insulation material covers the thrust washer without overhanging. This enables the thrust washer to provide a flat and thus reliable underlay for the thermal insulation material and at the same time, when the combination of pressurized disc and thermal insulation material in an insulating plate, the thermal insulation material a recess provided for it almost completely fills. The formation of gaps in the insulation is thus avoided.

According to a preferred embodiment, at least one protruding cutting rib is arranged as a milling or cutting device on the underside of the thrust washer. This is used for milling out the insulation board when pulling or driving the thrust washer in the insulation board, wherein preferably a plurality of cutting ribs are provided, in particular in a symmetrical arrangement to the fastener or evenly distributed around it. This allows the fastener to be tightened during the fastening operation, i. Typically, while the fastener is anchored by a rotational movement in the substructure, cuts or mills a depression in the insulation board. Therein, the thrust washer and the thermal insulation material are added after the end of the attachment process. To be executed before attaching the fastener operation with separate cutting or milling such a depression in the insulation board can be dispensed with in order to save working time.

Two possible embodiments of the connection of the thermal insulation material and the pressure plate will be described below.

According to a first embodiment, the thermal insulation material is inseparably or non-detachably connected to the upper side of the pressure disk, wherein preferably thrust washer and thermal insulation material consist of the same material and form a common part. Particularly preferred in this case pressure washer and thermal insulation material are made in one piece. This can also mean that thrust washer and thermal insulation material are no longer clearly distinguishable from each other. Then the fastener can be attached to it, for example, glued. According to a second embodiment, the thrust washer and the thermal insulation material form a common part as a heat-insulating disc, which is produced by producing two separate discs and then connecting the two by gluing or pressing. Preferably, the thrust washer and the thermal insulation material made of different materials. This design allows the use of different and therefore optimized for the particular purpose materials for the pressure washer on the one hand and the thermal insulation material on the other. For example, a metal such as iron may be used for the thrust washer, which has advantages in terms of strength. For the heat By contrast, one of the abovementioned materials which has thermal insulation advantages can be used.

Two possible embodiments of the combination of the elongate fastening element with the pressure disk will be described below. According to a first embodiment, the elongate fastening element and the pressure plate made of different materials. This allows use for the particular purpose of optimized materials. For example, for the elongated fastener, a metal such as iron may be used, which has advantages in strength. For example, plastic can be used for the thrust washer, which can be connected more easily to the thermal insulation material.

According to a second embodiment, the fastening element and the pressure plate are integrally made of the same material, for which in particular metal, plastic or one of the above-described non-combustible and / or thermally insulating materials can be used. This one-piece design allows the production in one operation, the otherwise necessary operation for connecting the fastener is avoided with the pressure plate. In addition, such a one-piece design may have advantages in terms of stability, since there is no joint between the fastener and the pressure washer.

According to a particularly advantageous embodiment, which brings together two of the above-described embodiments, so to speak, fastener, pressure washer and thermal insulation material or heat-insulating disc are made of the same material, in particular integrally made of the same material. By such a total one-piece fastener made of a common material, the production can be further simplified, especially if it is done in a single operation. Less different materials are needed and the integral strength is better. Although in general a material of the abovementioned noncombustible and / or thermally insulating materials, in particular a mineral material or mineral wool, silicate or phyllosilicate, is suitable as the material. Particularly good results have been achieved in experiments with a one-piece production of the entire fastener in a single operation of vermiculite, preferably in expanded form.

Preferably, an opening extends through the heat-insulating material as far as the pressure disk, with the pressure disk also preferably having a tool engagement in the region of the opening, which is designed in particular as a slot, Phillips, hexagon socket or inner star. This makes it possible to push a tool such as a screwdriver or a hexagon socket key through the opening to the tool engagement and thus to rotate the fastener. The arrangement of the tool engagement on the pressure plate allows a direct power transmission to the pressure plate, which is made more stable in many embodiments than the thermal insulation material. From there, the force can be transmitted directly to the fastener for anchoring in the substructure.

Alternatively or additionally, such a tool engagement may also be formed on a free side or upper side of the thermal insulation material, in particular with an aforementioned shape. This is particularly in question when the thermal insulation material has sufficient strength to reliably transmit a force exerted on the tool engagement force on the pressure plate. By providing a further tool engagement on the thermal barrier material in addition to a tool engagement on the thrust washer, the fastener may be formed to be mounted with different tools. Under a free side is typically understood that side of the thermal insulation material, which is opposite to the pressure plate.

The arrangement according to the invention has a substructure, advantageously a building wall or slatted construction, and at least one insulating panel, which is fastened to the substructure with a number of fastening means according to the invention. The free sides of the thermal insulation materials of the fasteners are flush with an outer surface of the insulation board. The invention allows a shapely execution of such an arrangement, because a substantially flat outer surface is obtained. On this example, a plaster can be applied without problems.

These and other features will become apparent from the claims but also from the description and drawings, wherein the individual features each alone or more in the form of sub-combinations in an embodiment of the invention and in other fields be realized and advantageous and protectable Represent embodiments for which protection is claimed here. The subdivision of the application into subheadings and individual sections does not limit the general validity of the statements made thereunder.

Brief description of the drawing Further advantages and embodiments of the invention will be apparent to those skilled in the embodiments described below with reference to the accompanying drawings. Hereby show:

1 shows a first embodiment of a fastening means, Fig. 2A shows a second embodiment of a fastening means,

2B shows a third embodiment of a fastening means,

Fig. 3 shows an arrangement with an insulating plate and a substructure, and

Fig. 4 shows a method for fixing an insulating plate to a substructure.

DETAILED DESCRIPTION OF THE EXEMPLARY EMBODIMENTS FIG. 1 shows a first exemplary embodiment of a fastening means 10. It has a pressure plate 12 and a heat-insulating material 14 fastened thereto in the form of a heat-insulating pane. The pressure plate 12 is in this case made of a plastic. The thermal insulation material 14 is a non-combustible phyllosilicate, advantageously blown vermiculite, and adhered to the pressure plate 12. It can be seen that the thermal insulation material 14, the pressure plate 12 just covers, without standing over. In other words, the pressure plate 12 and the thermal insulation material 14 have the same radius and are concentric with each other.

From the pressure plate 12 is a fastener in the form of a long screw 16. The long screw 16 is presently made of metal. At its free end, i. at that end, which is opposite to the pressure plate 12, it is provided with an external thread 18.

For rotation, an opening 15 is formed in the thermal insulation material 14, in which a tool can be inserted. In the region of this opening 15, the pressure plate 12 has a tool engagement in the form of a hexagon socket, with which the tool such as a corresponding key can engage for rotation of the fastener 10th

Fig. 2 shows a slightly modified compared to that of Fig. 1 embodiment of a fastener 10. Also, this fastener 10 has a pressure plate 12 with a thermal insulation material 14 mounted thereon, wherein from the pressure plate 12, a fastening element in the form of a long screw 16 projects with an external thread 18 at right angles.

In contrast to the embodiment of Fig. 1, in the embodiment of Fig. 2A, the fastener 16 and the pressure plate 12 made of the same material, in this case metal, integrally formed. In other words, the thrust washer 12 together with the fastening element 16 is a component. This can be produced in a single work step, for example in the casting process.

Furthermore, the embodiment of FIG. 2A differs from that of FIG. 1 in that a total of four milling ribs 13 are provided as milling means on the underside of the pressure plate 12, which in the present case extend in the form of radial ribs from the shoulder of the screw 16 to the outside , These milling ribs 16 serve to mill or mill material of an insulation board during the fastening process, so that the pressure disk 12 and the thermal insulation material 14 can be accommodated in a recess formed in this way in the insulation board. This is done by a abrasive action of the milling ribs 13 during a rotational movement occurring during the fastening process. Another step is thus avoided, which saves working time.

Fig. 2B shows in comparison to the fastening means shown in Figures 1 and 2A, a previously mentioned embodiment of a further fastening means 1 10. This fastening means 1 10 has a pressure plate 1 12 mounted thereon with thermal insulation material 14 1. It can be seen that pressure plate 1 12 and thermal insulation material 1 14 are made in one piece, since no division between the two is provided. The pressure plate 12 is essentially formed by the lower region or only the underside of the disk-shaped thermal insulation material 14. From the pressure plate 1 12 is a fastener in the form of a long screw 1 16 with an external thread 1 18 from right angles. Here is also the screw 1 16 integrally with the pressure plate 1 12 and thus also be made with the thermal insulation material 1 14, all of the same material. The entire fastener 1 10 can thus be made in a single step from a single material, be pressed advantageously. As a material here is a non-combustible and thermally insulating material, advantageously a mineral material such as the aforementioned silicates or a layered silicate, advantageously vermiculite, which is particularly advantageous in expanded form. By appropriate compression of these materials, possibly by adding from the state of Technically known binders such as water glass or the like., A relatively stable fastening means 1 10 can be made. Again, it may be provided to facilitate screwing into an insulating plate, that are provided on the underside of the pressure plate 1 12 four milling ribs 1 13 as prescribed milling means. Also for this milling function the abovementioned materials are suitable, in particular also the named vermiculite.

3 shows an arrangement 20 with a substructure 22 and an insulation panel 26 mounted thereon. The insulation panel 26 is fastened to the substructure 22 by a total of four fastening means 10. One of these fastening means 10, namely that which can be seen in Fig. 3 lower left, is described in more detail below and can be seen in more detail by a corresponding section in the view. The other fasteners 10 are also connected to the substructure 22.

For anchoring a respective fastening means 10, a respective associated bore 23 is formed in the substructure 22, which in the present case is a customary house wall. In the hole, a dowel 24 is inserted, in which the external thread 18 of the screw 16 is turned on. Thus, a reliable anchoring of the screw 16 and thus of the fastener 10 in the substrate 22 is achieved in a known manner.

The respective fastening elements 10 are each driven so far into the bore 23, that a respective free side of the respective thermal insulation material 14 is flush with an outer surface 27 of the insulating plate 26. In this way, it is achieved that the outer surface 27 of the insulating panel 26 is almost not interrupted by the fastening means 10.

FIG. 4 shows a flowchart of a method of attaching an insulation panel to a substructure.

In step S1, a hole in the insulation board is first formed for this purpose. In step S2, a bore is formed in the substructure, which is arranged in alignment with the bore in the insulation board. It should be understood that steps S1 and S2 may be performed immediately after one another in a contiguous operation, for example using a drilling machine.

In step S3, the fastener is driven through the insulation plate in the bore of the substructure or rotated. At the same time a recess in the insulation board Milled, in which after completion of the process, the pressure plate and the thermal insulation material of the fastener are added.

It should be understood that between steps S2 and S3, a further step of inserting a dowel into the bore formed in the substructure will often take place.

In step S4, the driving is terminated exactly when the respective free side of the thermal insulation material is flush with the outer surface of the insulation board. This achieves the advantages already described above.

The method according to the invention can be carried out, for example, with one of the fastening means 10 shown in FIG. 1, FIG. 2A or FIG. 2B. It can be used to make an arrangement according to FIG. However, other embodiments of a fastener may be used, and another embodiment of an assembly may be obtained. Therefore, in the description of the method to the specification of the known from Figs. 1 to 3 reference numerals has been omitted.

Claims

claims

1 . Fastening means for fixing an insulating plate (26) to a substructure (22), wherein the fastening means (10, 1 10) comprises a thrust washer (12, 1 12) and an elongated fastening element (12, 12) projecting transversely from an underside of the thrust washer (12, 12). 16, 1 16), characterized in that on an upper side of the thrust washer (12, 1 12) thermal insulation material (14, 1 14) is arranged in the manner of a heat-insulating disc.

2. Fastening means according to claim 1, characterized in that the thermal insulation material (14, 1 14) has a thickness of 0.5 cm to 3 cm, in particular 0.7 cm to 1, 5 cm, and / or 5% to 30% of its diameter.

3. Fastening means according to claim 1 or 2, characterized in that the thermal insulation material (14, 1 14) consists of non-combustible and / or thermally insulating material, in particular selected from the group: Styrofoam, polyurethane foam, insulating cork, wood wool, wood fiber, Coconut fiber, mineral wool, silicate and phyllosilicate, wherein in particular a phyllosilicate is vermiculite, preferably vermiculite in expanded form.

4. Fastening means according to one of the preceding claims, characterized in that the thermal insulation material (14, 1 14), the thrust washer (12, 1 12) covers without overhanging.

5. Fastening means according to one of the preceding claims, characterized in that at the bottom of the thrust washer (12, 1 12) at least one protruding Fräsrippe (13, 1 13) is arranged as a milling device or cutting device for milling the insulating plate (26) when driving the Thrust washer (12, 1 12) in the insulating plate (26), wherein preferably a plurality of milling ribs (13, 1 13) are provided, in particular in a symmetrical arrangement to the fastening element (16, 1 16) or evenly distributed around it.

6. Fastening means according to one of the preceding claims, characterized in that the thermal insulation material (14, 1 14) with the top of the thrust washer (12, 1 12) is inseparably or non-detachably connected, wherein preferably thrust washer (12, 1 12) and thermal insulation material (14, 1 14) made of the same material and form a common part and are made in one piece in particular for this purpose.

7. Fastening means according to one of claims 1 to 5, characterized in that the pressure disc (12) and the thermal insulation material (14) form a common part as a thermal insulation disc, which by producing two separate discs and then connecting the two by Gluing or pressing is made, in particular, the thrust washer (12) and the thermal insulation material (14) made of different materials.

8. Fastening means according to one of the preceding claims, characterized in that the elongate fastening element (16) consists of metal and the thrust washer (12) consists of plastic.

9. Fastening means according to one of claims 1 to 7, characterized in that the fastening element (16, 1 16) and the pressure disc (12, 1 12) are integrally made of the same material, in particular of metal or plastic.

10. Fastening means according to one of claims 1 to 6, characterized in that the fastening element (1 16), the pressure disc (1 12) and the thermal insulation material or the thermal insulation disc (1 14) are made of the same material, in particular are made in one piece and / or in one operation from the same material.

1 1. Fastening means according to one of the preceding claims, characterized in that an opening (15) through the thermal insulation material (14, 1 14) to the thrust washer (12, 1 12) extends and in the region of the opening the thrust washer (12, 1 12) Having a tool engagement, in particular as a slot, Phillips, hexagon or inner star.

12. Fastening means according to one of the preceding claims, characterized in that on a free side of the thermal insulation material (14, 1 14) a tool engagement is formed.

13. Arrangement, comprising a substructure (22) and at least one insulating plate (26), which with a number of fastening means (10, 1 10) according to one of claims 1 to 12 attached to the substructure (22), wherein respective free sides the heat-insulating materials (14, 1 14) of the fastening means (10, 1 10) with an outer surface (27) of the insulating plate (26) are arranged flush.

14. Arrangement according to claim 13, wherein the respective pressure discs (12, 1 12) and thermal insulation materials (14, 1 14) of the fastening means (10, 1 10) in respective recesses of the insulating plate (26) are arranged.

15. A method for fixing an insulating plate (26) on a substructure (22), wherein a number of fastening means (10, 1 10) according to one of claims 1 to 12 by the insulating plate (26) and so far into the substructure (22). be driven, that respective free sides of the thermal insulation materials (14, 1 14) of the fastening means (10, 1 10) with an outer surface (27) of the insulating plate (26) are flush.