EP1988233A2 - Stone slab - Google Patents

Abstract

The plate (1) has a reinforcement element (5) located on the back of the stone plate. The reinforcement element mechanically strengthens the stone plate particularly with bending loads. The stone plate is made of natural stone material particularly from limestone. An attachment groove is present on the back of the stone plate for the attachment of the reinforcement element.

Description

The invention relates to a stone slab according to the preamble of claim 1.

Generic stone slabs are used in particular, but by no means exclusively, for attachment to house facades. Also, generic stone slabs can be used as ceiling panels use. The stone slabs can either serve for cladding an underlying substructure, for example concrete and / or steel. In addition, uses are conceivable in which the stone slabs serve as shading elements, in particular as shading slats. Another use is the production of stairs.

Due to the installation of stone slabs in public areas, high safety requirements have to be met. So when installing stone slabs to house facades must be ensured that the stone slabs are reliably secured against falling even with improper use, for example when climbing by unauthorized persons. There are therefore attachment systems for fixing stone slabs to the House facade or ceiling construction known in which the stone slabs are edged with encircling metal frame. A disadvantage of this type of attachment, however, is that it is extremely expensive and also the visual impression of the stone slabs is disturbed. In addition, it is often necessary to use relatively thick stone slabs to ensure the required mechanical stability. However, the large thickness of the flagstones leads to a correspondingly high weight and thus in turn requires a considerably higher effort to fix the flagstones.

Based on this prior art, it is therefore an object of the present invention to propose a new flagstone, which avoids the disadvantages of the prior art.

This object is achieved by a stone slab according to the teaching of claim 1.

Advantageous embodiments of the invention are the subject of the dependent claims.

The invention is based on the idea of providing at least one reinforcing element on the back of the flagstones, which mechanically reinforces the flagstones. In particular, the reinforcement should protect against breakage under bending load, since the stone material is relatively sensitive to the tensile stresses occurring during bending stress. By reinforcing the stone slab by means of the attached on the back of the reinforcing element can be achieved that the required mechanical stability is already ensured by relatively very thin stone slabs. In addition, the visual impression of the stone slabs is not disturbed, since the reinforcing element is mounted on the side facing away from the visible side of the back of the stone slab.

What material consists of the flagstone, is basically arbitrary. For example, artificially produced stone slabs, in particular cast stone slabs, conceivable, which are reinforced according to the invention with the reinforcing element. Particularly large advantages of the invention in the reinforcement of natural stone slabs, because natural stone slabs are relatively vulnerable to breakage due to their natural structure and therefore may only be installed in compliance with appropriate safety precautions to house facades or ceilings. The reinforcement of natural stone slabs according to the invention opens up a broad field of application for this material. In particular, for limestone slabs, the reinforcement according to the invention is suitable with reinforcing elements, since limestone material only relatively low tensile loads, as they occur in bending stresses endures.

The way in which the reinforcing element is fastened on the back of the stone slab is fundamentally arbitrary. Thus, the reinforcing element can be glued to the back or fixed with fasteners, such as dowel screws. According to a preferred embodiment, a fastening groove is provided for fastening the reinforcing element on the back of the stone slab. In this fastening groove, the reinforcing element is at least partially, in particular completely, taken. With complete absorption of the reinforcing element in the mounting groove is achieved that when attaching the flagstone no additional space is necessary.

In order to attach the fastening groove on the flagstone, it is particularly advantageous if the fastening groove is introduced by means of a milling process, in particular by face milling. Such grooves can be made with high accuracy and are therefore particularly suitable for fixing the reinforcing element. In addition, the milling of the mounting groove allows a rational and cost-effective production.

The geometry of the mounting groove is basically arbitrary. Thus, the mounting groove may be U-shaped, so that the reinforcing element inserted in a simple manner from behind into the mounting groove and then fixed there, for example, screwed or glued, can be. It is particularly preferred if there is positive locking between the fastening groove and the reinforcing element. This positive locking ensures that a release of the flagstone from the reinforcing element is ultimately excluded. If, for example, a T-shaped or dovetail-shaped fastening groove is introduced into the stone slab, in particular milled in, then a prismatically shaped reinforcing element can be inserted into this fastening groove from the front side, and the undercuts of the fastening groove surround the reinforcing element. Even when breaking the stone slab falling of parts of the stone slab is then excluded because a reliable attachment over the entire length of the reinforcing element is ensured due to the positive connection.

Alternatively or in addition to the attachment of the reinforcing element by means of a positive connection, the reinforcing element can also be fixed by means of an adhesive material in the fastening groove. Even if there is a positive fit between the fastening groove and the reinforcing element, the attachment of an adhesive material is advantageous, because thereby slipping out of the reinforcing element, in particular during assembly of the stone slabs, is reliably precluded.

In order to exclude stresses between the stone material and the reinforcing element, as they can occur in particular with temperature fluctuations, the adhesive material should be elastically deformable. In particular, a silicone-based adhesive material can be used.

Optimal reinforcement with respect to bending loads in particular is achieved when the fastening groove and thus the reinforcing element fastened therein extend along the longitudinal axis of the flagstone. The highest tensile stresses in bending stress occur namely in the middle of the longitudinal axis of the stone slab.

Depending on the dimensioning of the flagstone, several reinforcing elements can be provided side by side on the flagstone. In particular, the reinforcing elements can be mounted parallel to one another, for example along the longitudinal axis of the stone slab.

As already described, the mounting groove can be milled in a particularly simple manner in the stone material of the flagstone. In the simplest form is thereby etched through from one end face of the stone plate to the other end face of the stone plate, so that the fastening groove is open at both ends. To achieve special optical effects, for example when attaching the flagstones in the corner of house facades, it is particularly advantageous if the mounting groove is open only at one end of the stone slab. On the opposite end face of the stone slab, however, the fastening groove is closed, so that the visual impression on this end face, which can be arranged in particular in the corner of the house facade, is not disturbed.

The material of which the reinforcing element is made is in principle arbitrary. It is particularly inexpensive and easy if metal profiles are used to reinforce the stone slab. Such metal profiles can be easily inserted, in particular in prismatic fastening grooves. When using aluminum profiles or stainless steel profiles results in a high corrosion resistance at the same time relatively low weight.

In what way the stone slabs are fixed during later use, for example, to fix the stone slabs on the house facade or a ceiling, is basically arbitrary. However, since the stone slabs according to the invention are provided with the mechanically loadable reinforcing element, it is particularly advantageous if at least one fastening point for fastening the stone slabs to a substructure, for example a house facade or ceiling, on the reinforcing element is provided. In other words, this means that the force flow in the transmission of the weight forces of the reinforcing element from the material of the stone slab in the attachment point of the reinforcing element and from there via the corresponding fastening means in the substructure. The reinforcing element takes on a double function, namely once for reinforcing the stone slab and once for fixing the stone slab. The transmitted forces are introduced by the reinforcing element over a large area in the material of the flagstone. In addition, the attachment of the flagstone by means provided on the reinforcing element attachment points allows a fastening solution that is invisible from the visible side.

In order to realize an attachment point in the reinforcing element, the reinforcing element can be provided with a recess. Through this recess, a fastening means, for example a screw or a bolt, can be pushed through. This fastener is then on the back of the stone plate so far over the surface of the stone slab that it can be attached to the underlying substructure.

According to a preferred embodiment, the recess is formed in the reinforcing element in the manner of a slot. Through the slot a relative movement between the fastening means and flagstone is made possible, so that when mounting the flagstone with the substructure, an orientation of the fastening means can be made relative to the substructure. In this way, the assembly work is greatly facilitated.

Which function the stone slab takes over is fundamentally arbitrary. Particularly preferred is the use of stone slabs according to the invention for the realization of shading elements, in particular if they are designed in the manner of a shading slat. Especially with shading elements, it is important that this relatively slim and can be formed daintily, which is made possible by the reinforcement of the stone slabs by means of the reinforcing element according to the invention in a simple manner.

A further particularly great advantage offers the use of the reinforcing element according to the invention, when the stone slab is adjustable, in particular rotatable, to be stored. In this case, the reinforcing element can at the same time take over the function of a bearing element for the adjustable mounting of the flagstone. In this way, the necessary positioning movements can be easily and safely transferred to the flagstone.

A particularly simple possibility for realizing an adjustable mounting of the flagstone is given when the reinforcing element protrudes laterally over the flagstone. The ends of the reinforcing element may then be part of a pivot bearing. The ends of the reinforcing element are end equipped with bearing journals which are rotatably mounted in frame-fixed bearing blocks.

As far as a drive device is provided in order to adjust the flagstone, it is particularly advantageous if this drive device comes into engagement with the reinforcing element. As a result, the necessary driving forces can be easily and safely transferred to the flagstone.

Two embodiments of the invention are shown schematically in the drawings and are explained below by way of example.

Fig. 1

die Befestigung einer ersten Ausführungsform einer Steinplatte in Ansicht von oben;

Fig. 2

die Befestigungslösung gemäß Fig. 1 im Querschnitt entlang der Schnittlinie I-I;

Fig. 3

die Steinplatte gemäß Fig. 1 in Ansicht von vorne;

Fig. 4

die drehbare Lagerung einer zweiten Ausführungsform einer Steinplatte in Ansicht von vorne;

Fig. 5

die Befestigungslösung gemäß Fig. 1 im Querschnitt entlang der Schnittlinie II-II;

Fig. 6

die Steinplatte gemäß Fig. 4 in Ansicht von oben;

Fig. 7

eine weitere Ausführungsform einer Steinplatte mit schwalbenschwanzförmiger Befestigungsnut im Querschnitt.

Show it:

Fig. 1

the attachment of a first embodiment of a stone slab in top view;

Fig. 2

the fixing solution according to Fig. 1 in cross-section along the section line II;

Fig. 3

the flagstone according to Fig. 1 in front view;

Fig. 4

the rotatable mounting of a second embodiment of a stone slab in front view;

Fig. 5

the fixing solution according to Fig. 1 in cross-section along the section line II-II;

Fig. 6

the flagstone according to Fig. 4 in top view;

Fig. 7

a further embodiment of a stone plate with dovetail-shaped fastening groove in cross section.

Fig. 1 shows a mounting solution for fixing stone slabs 01 to the substructure 02 of a house facade or ceiling. At the substructure 02 right and left mounting brackets 03 are screwed to which then turn the stone slabs 01 are attached. Mounting brackets 03 are after screwing part of the substructure 02. The stone slabs 01 serve as shading blades for shading a building facade.

Fig. 2 shows the mounting solution for fixing the stone slabs 01 to the substructure 02 in cross section along the section line II. On the back of the stone slab 01 a T-shaped mounting groove 04 is milled into the inserted from the open sides of the stone slab 01 a reinforcing element 05 inserted is. As a reinforcing element 05 serves the portion of an aluminum profile with a rectangular cross-section, which is positively encompassed by the crossbar of the T-shaped mounting groove 04. Before inserting the reinforcing element 05 into the fastening groove 04, a silicone adhesive compound is introduced into the fastening groove 04 in order to realize an elastically deformable adhesive bond between the stone plate 01 and the reinforcing element 05.

The undercuts of the mounting groove 04 engage around the reinforcing element 05 and realize in this way a positive connection between the stone slab 01 and reinforcing element 05. To fix the stone slab 01 to the mounting brackets 03 are fixing screws 07. Before inserting the reinforcing member 05, the screws 07 through recesses 06 (please refer Fig. 3 ), which are formed in the manner of oblong holes, pushed through. With their countersunk head, the fastening screws 07 are completely received in the reinforcing element 05, so that the reinforcing element 05 can be easily inserted into the fastening groove 04. The screw shaft of the mounting screws 07 passes through the T-shaped mounting groove to the back and stands on the back of the stone slabs 01 so far over that it can be pushed through mounting holes in the mounting brackets 03. To avoid Thcrmos voltages also an elastomer plate 08 is disposed between the stone plate 01 and the mounting bracket 03. By tightening the nut 09, the stone plate 01 is then fixed to the mounting bracket 03. The fastening nut 09 is preferably designed as a locknut to safely exclude an unwanted loosening of the mounting nut 09.

As a result, the Verstärkungselezzaent 05 thus not only used to arm the stone slab 01, but also realized by means of the screws 07, which are pushed through the slot-like recesses 06, attachment points for fixing the stone slab 01 on the substructure 02. The fixation is the front of the Stone plate 01 out not visible, so that the visual impression on the building is not disturbed by the fastening means.

Fig. 4 to Fig. 6 show a second embodiment 10 of a stone slab according to the invention, which is reinforced with a reinforcing element 11. The attachment of the reinforcing element 11 in the stone plate 10 corresponds to the in Fig. 1 to Fig. 3 illustrated embodiment, ie in the stone plate 10, in turn, a T-shaped mounting groove 12 is provided, which surrounds the reinforcing element 11 in a form-fitting manner. The reinforcing element 11 protrudes laterally beyond the stone plate 10 and is rotatably supported by bearing journals 13 in pivot bearing blocks 14. In this way, a rotatable mounting of the stone plate 10 is realized about an axis of rotation 15. The pivot bearing blocks 14 are fixed to the frame fixed to a substructure 16.

To drive the stone plates 10 when pivoting about the axis of rotation 15 is a drive means 17 which consists of a lever 18 and a vertical drive rod 19. The levers 18 are each secured to the reinforcing elements 11, for example, welded and connected by means of bearing pin 20 with the vertical drive rod 19. By means of the vertical drive rod 19 a plurality of stacked stone plates can be pivoted simultaneously. If the vertical drive rod 19 is pulled upwards or downwards, the stone plates 10 pivot about a corresponding angle about the axis of rotation 15. Of course, embodiments are also conceivable in which the stone plates can be pivoted through 360 °.

Fig. 7 shows a further embodiment of a stone plate 21 with a dovetail-shaped mounting groove 22 in cross section. In the mounting groove 22, a rectangular reinforcing element 23 is used for reinforcing the stone plate 21, in particular made of natural stone, which is encompassed form-fitting manner by the fastening groove 22.

LIST OF REFERENCE NUMBERS

01

stone slab

02

substructure

03

mounting brackets

04

mounting groove

05

reinforcing element

06

elongate recess

07

fixing screw

08

elastomer plate

09

fixing nut

10

stone slab

11

reinforcing element

12

mounting groove

13

pivot

14

Pivot bracket

15

axis of rotation

16

substructure

17

driving means

18

lever

19

Vertical drive shaft

20

pivot

21

stone slab

22

mounting groove

23

reinforcing element

Claims (18)

Stone slab (01, 10, 21), in particular for attachment to a house facade, a ceiling or stairs, with a visible side and a back,
characterized,
that on the back of the stone slab (01, 10, 21) a reinforcing element (05, 11, 23) is arranged, which mechanically reinforces the stone slab (01, 10, 21), in particular during bending loads. Stone slab according to claim 1,
characterized,
that the stone plate (01, 10, 21) made of natural stone material, in particular limestone, is prepared: Stone slab according to claim 1 or 2,
characterized,
in that for fastening the reinforcing element (05, 11, 23) on the rear side of the stone slab (01, 10, 21) there is a fastening groove (04, 12, 22) in which the reinforcing element (05, 11, 23) is at least partly especially complete. Stone slab according to claim 3,
characterized,
in that the fastening groove (04, 12, 22) is designed in the manner of a milling groove. Stone slab according to one of claims 2 to 4,
characterized,
that between fastening groove (04, 12, 22) and reinforcing element (05, 11, 23) is a positive connection, in particular that the fastening groove (04, 12, 22) is T-shaped or dovetail-shaped and a prismatic reinforcing element (05, 11, 23 ) engages positively. Stone slab according to one of claims 2 to 5,
characterized,
in that the reinforcing element (05, 11, 23) is fixed in the fastening groove (04, 12, 22) by means of an adhesive material. Stone slab according to claim 6,
characterized,
in that the adhesive material is elastically deformable, in particular that the silicone-based adhesive material is produced. Stone slab according to one of claims 2 to 7,
characterized,
in that the fastening groove (04, 12, 22) extends along the longitudinal axis of the stone slab (01, 10, 21). Stone slab according to one of claims 2 to 8,
characterized,
that a plurality of reinforcing elements are provided next to one another, in particular parallel to one another, on the stone slab. Stone slab according to one of claims 2 to 9,
characterized,
that the fastening groove is open at one end face of the stone slab and the opposite end face of the slab is closed. Stone slab according to one of claims 1 to 10,
characterized,
in that the reinforcing element (05, 11, 23) is made of a metal profile, in particular of an aluminum profile or a stainless steel profile. Stone slab according to one of claims 1 to 11,
characterized,
that the reinforcing element (05, 11) at least one attachment point for attachment of the stone slab (01, 10), in particular for attachment of the stone plate (01, 10) to a substructure (02, 03, 16). Stone slab according to claim 12,
characterized,
that a recess (06) is provided in the reinforcing member (05) on which a fastening means, in particular a screw (07) or a bolt, is so attached that the attachment means extends beyond the rear side of the stone slab (01) and (with the substructure 02, 03) is connectable. Stone slab according to claim 13,
characterized,
that the recess (06) is designed in the manner of a slot and allows an orientation of the fastening means (07) relative to the substructure (02, 03). Stone slab according to one of claims 1 to 14,
characterized,
that the stone plate (01, 10) in the manner of a shading element, in particular in the manner of a shading plate is formed. Stone slab according to one of claims 1 to 15,
characterized,
in that the reinforcing element (11) forms at least part of a bearing element for adjustable, in particular rotatable, mounting of the stone slab (10). Stone slab according to claim 16,
characterized,
in that the reinforcing element (11) projects laterally beyond the stone plate (10) and bearing journals (13) are provided at the ends of the reinforcing element (11) at the end. Stone slab according to claim 16 or 17,
characterized,
that a drive means (17, 18, 19) for adjusting the stone plate (10) comes to engage the reinforcement member (11).

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