EA032321B1 - Locking module for locking roof elements on a roof or facade structure against window suction - Google Patents

Abstract

The invention is related to a locking module for locking roof elements on a roof or facade structure against wind suction. The wind suction locking module comprises a coupling element (1) with a first flange (2) to be engaged under a load-bearing member of a roof or facade structure, and a fixture (3) for holding the coupling element (1). The fixture (3) includes connection means for connecting the fixture (3) with a roof element. The coupling element (1) is retained in the fixture (3) and is movable along a movement axis that is substantially parallel to the roof slope. The first flange (2) is spaced from the movement axis. The coupling element (1) is made as a buckle having a first buckle part (4) and a second buckle part (5), both parts (4, 7) of the buckle being connected to each other at the buckle top (6). At one end of the first buckle part (4), the first flange (2) is of a latching tape, and the second buckle part (5) is disposed, at least partially, on the movement axis, and one end of the first flange (2) is provided with a fastening foot (8). The locking module for locking roof elements on a roof or facade structure against wind suction according to the invention has a support element (7) on the second buckle part (5) in the area of the top (6), on the side facing from the first buckle part (4), said support element lying in a plane formed by the first buckle part (4) and the second buckle part (5); and the fastening foot (8) has several edges (9) disposed essentially in parallel to the movement axis of edges (9) and intended for locking the load-bearing member of the roof structure under a load caused by wind suction, the edges (9) being located at different distances from the movement axis.

Description

The invention relates to a locking module for locking roofing elements on a roof or facade structure from a wind choke. The locking module of the wind choke contains a coupling element (1) with a first shelf (2) for engaging under the load-bearing element of a roof or facade structure, as well as a fastener (3) for holding the coupling element (1). The fastener (3) contains connecting means for connecting the fastener (3) to the roofing element. The coupling element (1) is held in the mount (3) with the possibility of movement along the axis of movement that runs substantially parallel to the direction of the roof slope. The first shelf (2) is located at a distance from the axis of movement. The coupling element (1) is made in the form of a yoke with the first part (4) of the yoke and the second part (5) of the yoke, and both parts (4, 7) of the yoke are connected to each other at the top (6) of the yoke. At one end of the first part (4) of the yoke, the first shelf (2) is hooked, and the second part (5) of the yoke is at least partially located on the axis of movement, and a fixing tab (8) is made at one end of the first shelf (2) . In such a locking module for locking the roofing elements on the roof or facade structure from the wind choke on the second part (5) of the yoke in the region of the apex (6) on the side facing away from the first part (4) of the yoke, the support element (7) is made, which, in particular lies in the plane formed by the first part (4) of the yoke and the second part (5) of the yoke, and on the mounting tab (8) there are several edges (9) arranged substantially parallel to the axis of movement to lock the roof structural member under load as a result wind suction, and the edges (9) are located at different distances from the axis of movement.

FIELD OF THE INVENTION

The invention relates to a locking module for locking roofing elements on a roof or facade structure from a wind choke. Such a wind choke retaining module comprises a coupling member with a first shelf for entering under the roof or facade structure bearing member, and also a mount for holding the coupling member. For its part, the fastener comprises connecting means for connecting the fastener to the roofing element. The coupling element is held in the mount with the possibility of movement along the axis of displacement, located essentially parallel to the direction of the slope of the roof, and optionally can be rotated around the axis of rotation. The first shelf is located at a distance from the axis of movement. The coupling element is made in the form of a yoke with the first part of the yoke and the second part of the yoke, the first part of the yoke and the second part of the yoke connected to each other on top of the yoke. The first shelf is made engaging at one end of the first part of the yoke, and the second part of the yoke is at least partially located on the axis of movement.

State of the art

Such a wind choke locking module is described, for example, in EP 2685022 A1, to which reference is made explicitly here and the disclosure of which is hereby specifically drawn in full.

The first shelf serves to enter under the load-bearing element of a roof or facade structure, for example, to enter under a roofing panel. The first shelf and the axis of movement are spatially separated from each other, at least in the area where the first shelf should act in a displaced state under the carrier element, that is, the first shelf is located at a distance from the axis of displacement, so that entry under the carrier element is possible no problem.

With a roof structure, such as a sloping roof or a steep roof, and similarly, with a facade structure, a lower roof element, for example, a roof tile, is installed on the supporting element, under which the first shelf should enter. The locking module of the wind suction, for its part, is not connected to this roofing element, and the fastening by means of connecting means is connected to the upper roofing element, which, at least partially, for example, in the area of engagement, lies on another roofing element, so that the lower roofing element is between the upper roofing element and the supporting element.

In this case, the direction of the roof slope at each point of the roof corresponds to the direction of the strongest slope in the direction of the earth's surface, and for the facades - vertical. With roof tiles, it is usually also recognizable without the need to move it, since the edges located in the direction of the roof slope at the top and bottom on the lower side of the tile in most cases are different. Also with other roofing elements, the direction of the roof slope, as a rule, can be determined without the roofing elements being moved. That is, we are also talking about the direction that is defined on the roofing element itself. Then the straight first can still be set, for example, obliquely with respect to the axis of movement, and this does not have to relate to the entire region of longitudinal extension. The shelf can also be curved in an arc. This facilitates installation, as well as, first of all, adaptation to different thicknesses of roofing panels and / or roofing elements.

Due to this, when it engages the first shelf, it, if it does not stop beforehand, can be inserted as far as possible so that the distance between the first shelf and the axis of movement begins to become less than the distance between the axis of movement and the lower edge of the carrier element. In this case, the first side abuts against the lower edge of the supporting element, but does not fulfill the real function of bonding.

The axis of movement passes relative to the direction of the slope of the roof, essentially, that is, within the usual tolerances, in parallel, since in this way the best effect is achieved with respect to the distribution of forces during wind suction and changing the distance of the first shelf. But with particularly small roofing elements it may be appropriate if the axis of movement encloses an angle with the direction of the roof slope, however, this angle differs from 90 °.

The coupling element is mounted in the mount with the ability to move, which is accompanied by insignificant structural complexity and easy manipulation. As an alternative, the coupling element itself can also be connected to a fixture, which then, for its part, is movable.

In a corresponding embodiment, for example with the first shelf mounted obliquely, along with the possibility of movement, it is possible to adapt the locking module of the wind suction, if it is installed by means of a fastening on the roofing element, to almost all systems of roofing elements and load-bearing elements, for example, from roofing tiles and roofing panels. In a typical roof structure, as was mentioned at the beginning, a lower roofing element is located on the supporting element. On it, in turn, with partial alignment is located the upper roofing element, and the combination occurs in the upper region of the upper roofing element in the direction of the roof slope. While the first shelf, when mounted, is engaged under the roof element, on which the lower roof element is mounted, the coupling of the coupling element is connected to the upper roof element by means of connecting means. For mounting, the towing member in the mount moves down along the axis of movement, so that the first shelf engages under the roof structural member. Due to this, it is not the lower roofing element that is fastened directly to the supporting element, but only a weak fixation of the upper roofing element on the supporting element, and there remains a gap from a few millimeters to several centimeters. In this case, the lower roofing element is located between the upper roofing element and the supporting element. That is, the first shelf in the mounted and moved state does not have to be in contact with the supporting element; under certain circumstances, an air gap remains. During a wind load, the upper roofing element rises, and a contact arises between the first shelf and the supporting element, which prevents further lifting of the upper roofing element. Although such a small air gap facilitates the replacement of damaged roof elements, however, under strong wind loads, contact — especially when the first shelves are installed obliquely with respect to the direction of the roof slope and the surfaces of the bearing element — may be too small under certain circumstances, and roof structure may be destroyed. .

To save material, the coupling element, as a rule, is made in the form of a yoke with the first and second parts of the yoke, which are connected to each other at the top of the yoke. The first shelf is made engaging on the free end of the first part of the yoke. The second part of the yoke is at least partially located on the axis of movement. The first shelf can also be part of the first part of the yoke, both can also be identical to each other. As a rule, the shape of the yoke is chosen in order to save material, however, it is also possible to make the area between the yoke in the form of a plate, which is not a problem with the appropriate configuration of the injection mold. Then the yokes, for example, are formations in the form of protrusions on the edge of this plate, if this area must be made reinforced. True, parts of the yoke can also be simply formed by the edge of the plate, and it must be ensured that the second part of the yoke, which is at least partially located on the axis of movement, can also move in this area. The coupling element and the fastener can be made of plastic, for example, by injection molding. Other materials may also be used that are suitable to withstand the expected forces during wind leaks. The coupling element and / or fasteners can be made, for example, of metal.

As already mentioned above, the extreme wind leakage that occurs, for example, during squally winds, can lead to the fact that the upper roofing element is lifted from the lower roofing element, and for structural reasons, an air gap can form. In an unfavorable case, the wind load can even lead to the fact that the fastener is disconnected from the roofing element, which can lead to the destruction of the roof or facade structure.

Description of the invention

The objective of the invention is to improve the locking module for locking the roofing elements on the roof or facade structure from the wind suction of the type described at the beginning, and, first of all, to improve it so that the protection against wind load is further improved.

This task in the locking module for locking the roof elements from the wind suction of the type described at the beginning was solved due to the fact that the supporting element is made on the second part of the yoke in the apex area on the side facing away from the first part of the yoke, and several essentially located parallel to the axis of movement of the edges to lock the bearing element of the roof structure under load as a result of wind suction, and the edges are located at different distances from the axis of movement. The support element is preferably in the form of a protrusion and preferably lies in a plane that is formed or realized by the first part of the yoke and the second part of the yoke. That is, the support element is located on that side of the engagement element which is the most removed from the first shelf and which is also the most removed from the axis of movement of the mount. The supporting element, which, for example, can also be made as a thickening or elevations in the form of a knoll, counteracts the lifting force of the lever caused by the wind suction, preventing the second part of the yoke from deviating too much from the axis of movement in extreme situations. The elevation may be such that the second part of the yoke in the mounted state is held on the axis of movement and does not tip over against it. Due to this, the maximum size of the air gap is reduced in comparison with the locking module for locking the roof elements from the wind suction without such a supporting element. At the same time, the coupling member is fixed so that the peeling of the mount is prevented under strong wind load. As a rule, the fastener is connected to the power circuit only by means of a blind hole in the roofing element and the seal on the fastener that extends in it. In extreme situations, this force could be overcome by a wind load. Due to the support element, the force necessary for this increases so much that even in extreme situations, such as a squally wind, reliable retention is ensured.

The support element can be made, for example, in the form of a protrusion, that is, be limited to a small area at the apex, where the lever action is the best. Due to the corresponding curves

- 2 032321 or the rejection of angles ensures that the support element, despite the elevation, is easy to move and turns under certain conditions if the coupling element is held or mounted in the mount in accordance with one preferred option with the possibility of rotation around the axis of rotation. The axis of rotation can also be located essentially parallel to the direction of the slope of the roof, first of all, it can also coincide with the axis of movement. And here it is possible that the mount itself is rotatable, or the coupling element is mounted rotatably in the mount. The pivot axis can also enclose an angle with the pivot axis. The fastening or installation with the possibility of rotation gives the advantage that the locking module of the wind suction, if it is connected to the engaging element already in the manufacture of the latter and is supplied as a unit, is compactly attached to the inside of the roofing element. With a correspondingly flat design of the retaining module of the wind suction and, first of all, the coupling element, the roofing elements are better stored and transported, especially when it comes to roof tiles, which, as a rule, do not have a flat bottom side. Then here it is especially favorable if the first shelf, the axis of movement and the axis of rotation lie in the same plane, since this form of implementation turns out to be especially flat.

In accordance with the invention, at one end of the first shelf, which is opposite the end of the shelf, which is made engaging with the end of the first part of the yoke, a fixing tab is formed. The first shelf and the fixing foot preferably enclose an angle other than 180 °. In this case, the angle between the first shelf and the mounting tab can be adjusted so that the mounting tab in the case of a wind choke lies flat on the underside of the carrier, such as a roof panel, which provides a more favorable distribution of forces and a reduced load. The transition between the fastening foot and the first shelf can also be smooth if, for example, the first shelf is made as a continuation of the first part of the yoke with a slight bend and goes straight into a shank made as a fastening foot. But the mounting tab can also be made separately, for example, from a very hard material, and then connected to the first shelf. It is also possible that the fixing tab has an insert made of a harder material, which is respectively embedded in the injection mold.

As indicated above, in accordance with the invention, several edges arranged substantially parallel to the axis of movement of the edges for locking the load-bearing element of the roof structure under load by a wind suction are made on the mounting tab. The edges are located at different distances from the axis of movement. Due to this, it can be ensured that reliable retention is always guaranteed for different thicknesses of the bearing elements, and the lifting during wind suction is kept as low as possible. If, for example, roof battens are used as load-bearing elements, then typical and permissible thicknesses, for example, in Germany, are 28 and 42 mm. If the fixing foot had only one edge, then it would have to cover the entire area up to 42 mm. When using roof battens, 28 mm thick, it would be possible to raise the upper roof element from the lower roof element by more than 1 cm, which could lead to damage. By using several edges, for example two edges, for roof battens 28 and 42 mm thick, this can be effectively prevented. In this case, the coupling element can be made so that the corresponding edge in the mounted state lies completely on the corresponding mating surface of the bearing element, so that a connection with a force circuit is already formed when the coupling element is fixed in the roofing element by means of fastening.

To improve the connection at the edges, a wave-like or helical profile or other suitable profile for engaging with force closure with the supporting element when loaded by a wind suction is preferably made. There should be a slight backlash or an air gap between the edges and the mating surfaces of the supporting elements in order to make it possible to remove the coupling element, for example, for repair purposes. If the teeth cut directly into the supporting element made of wood, manual removal is only possible with great effort. For smooth edges, this minimum clearance may also be present, but it is not absolutely necessary. If there is no gap, the engagement elements must be pulled down along the axis of movement to get a connection with the carrier with a force closure, since the rearrangement is only due to gravity, as is the case when using fixing tabs with edges that leave a certain clearance on relation to the bearing element is not possible.

Removing the roofing elements is in principle possible if the coupling element moves along the axis of movement against the direction of the roof slope, that is, up until the fixing tab or the first shelf no longer enters under the supporting element. This can be facilitated by the implementation in which the coupling element comprises a second shelf for engagement between the two roofing elements, the second shelf having a smaller distance to the axis of movement than the first shelf, and the first shelf connected to the second shelf and the second part of the yoke by means of a cross member, and the first shelf forms with the second rest essentially the shape of a bracket. Then on the cross member there is a nozzle element for the nozzle of the tool, which for reasons of stability

- 3 032321 of the area is preferably partially covered by the cross member and the second shelf. This nozzle element can be, for example, a dovetail recess in which a corresponding slider is inserted, which can also be made in the form of a dovetail, but with a swallow tail 90 ° offset. The nozzle prevents the tool from sliding up or down when moving against the direction of the roof slope to detach the roof element. The nozzle element may also be in the form of a funnel, so that slipping in any direction is prevented. Then, for example, a mandrel or screwdriver for cross-head screws is suitable as a tool. In the nozzle element, all suitable molds can be implemented to prevent slipping of the tool. With an appropriate calculation of materials and their thickness, you can abandon the first part of the yoke.

Although the second shelf forms the shape of a bracket with the first shelf, it does not realize the function of fastening. As a result of the second shelf engaging between the roofing elements, the lower roofing element is additionally held on the supporting element. True, this suggests that there is a corresponding hollow space between the roofing elements, which often takes place, for example, with roofing tiles with the corresponding surface geometry, and in any case, as a rule, this can be done due to minor changes in the surface geometry. In addition, the second shelf can also serve to determine the end point for moving the coupling element along the axis of movement in the direction of the roof slope and thus limit the movement as an abutment. First of all, the distance of the second shelf to the axis of movement can be zero. Then the second shelf forms an extension of the axis of rotation or movement and / or the second part of the yoke, which makes it easy to manufacture and provides advantages for the transfer of forces. The connection of the first shelf with the second shelf can be rigid, it can occur, for example, directly through the connecting element in the form - also restricting movement - of the cross member, and the first shelf, second shelf and the cross between both shelves can be made in one piece. But the connection can also occur so that both shelves are variable in distance from each other and / or in angle relative to each other and, if necessary, are fixed at a selected distance or at a selected angle to each other. For example, the second shelf may be stationary, and the first shelf with the help of the remote element can be fixed in its position relative to the axis of movement, and the position of the first shelf with respect to the axis of movement can optionally also be adjusted using the remote element. Then, corresponding locks or the like can be made on the cross member. Although the first and second shelves are connected essentially in the form of a staple, they do not have the function of a staple, because there is no spring element that would ensure the staple function.

Even if the cross-member and the first yoke enclose a substantially right angle, the area in which they are joined to improve stability and for technological reasons, as a rule, is not exactly rectangular or made at a desired angle with a sharp edge, but at this point it is made with a rounded thickening. If the coupling element is mounted in the mount with the ability to move and rotate in a linear guide made on it, that is, in this linear guide, a part of the second part of the yoke lying on the axis of movement is installed, the linear guide having two ends, then at one end of the linear guide that indicates away from the top, a chamfer is made. It can take a curve between the cross member and the first part of the yoke, which contributes to the stability of the stop module of the wind choke under wind load.

Finally, in yet another embodiment, the mount has a rod-shaped, at least partially reversibly deformable, fitting piece for insertion into a blind hole on the roofing element. The fitting part has a lower portion for insertion into the blind hole and an upper portion which is located above the blind hole and above the mount, so that it is visible in the mounted state.

The fitting part has a hole in the upper section for inserting a tool to remove the fastening from the roofing element. This is especially rational when the fastening is made in the form of a part obtained by injection molding, and therefore is designed for single use. The tool can be made as a screw or screw and screwed into the hole, and it cuts the thread on the inner wall of the hole. Then on this screw the mount can be removed.

Due to the hole, the mechanical stability of the fitting part is slightly reduced compared to the incomplete fitting part along the axis of symmetry. Therefore, in the upper section, the fitting part preferably has rib-shaped elevations on the circuit, this improves the stability of the connection of the driven fitting part with the blind hole and reduces the risk of the mounting being pulled out of the blind hole under wind load, since the connection with a power circuit improves.

The fastening described above requires that a blind hole be made in the roofing element during manufacture. In the case of piece-making tiles or the like, which is pressed in its own

- 4 032321 forms, this is achieved without much expense due to the fact that the form used for pressing is slightly modified, and a special tool is built into the form, which is described, for example, in EP 2684659 A1. However, there are also roofing elements which, across the direction of the roof slope or along it, always have the same cross-sectional shape. Such roofing elements are simpler and more economically made continuously from a strip, for example, in a continuous profile pressing method in which the material to be cured is pressed through an opening of the corresponding cross section, or in an extrusion method in which the material is continuously introduced into molds transported on the conveyor and then pressed .

With such manufacturing methods, blind holes by undercutting are only difficult to perform, since this would usually mean interruption of continuous material transport or continuous production.

Therefore, in one particularly preferred embodiment of the invention that is particularly suitable for the manufacture of roofing elements from concrete mixtures, the fastening is made in the form of a bracket with two opposite arms of the bracket, spring connecting both arms of the bracket in each case at one end with a middle part.

The shoulders of the staple can be straight, and the middle part can enclose a right angle with both sides of the opening and also be straight, so that the bracket in cross section forms approximately the shape of and. But the middle part can also be arched, so that it adjoins the shoulders of the bracket at an angle of 180 °. Moreover, the shape covers all intermediate steps between these extremes, that is, the approximate shape of the arc, in which the middle side consists of several straight partial elements, and the angle depends on the number of partial elements.

The bracket surrounds the second part of the yoke at least partially and thereby limits the mobility of the second part of the yoke perpendicular to the axis of movement in at least one direction. In the case of execution in the form of a rectangular bracket, mobility limits at least the middle part, namely in the direction from the roofing element. Depending on the embodiment, the arms of the staple also surround the second part of the yoke, so that mobility perpendicular to the axis of movement is effectively prevented in three directions.

First of all, the middle part can also be made with an almost round cross section, so that the second part of the yoke is almost completely surrounded by it, except for a small gap in which the brackets of the bracket are adjacent to the middle part and which is required to insert the coupling element into the mount. The shoulders of the bracket can also be made integral and offset relative to each other in the middle part so that gearing occurs in the longitudinal direction along the axis of movement, so that the second part of the yoke in the middle is ultimately completely surrounded, which improves the quality of retention.

On the shoulders of the staples, for example, along the length, for example, due to a certain molding, and / or still preferably at the free ends, that is, those ends that are connected to the middle part and in the form and, for example, mark the opening form and made fastening means for connecting the bracket to the roofing element.

These fastening means can be made in different ways, the bracket later, that is, after the roof element has cured, is connected to the latter, or already during manufacture, for example, it is pressed into concrete at the same time in a non-dried state, and the locking element of the retainer has been previously positioned accordingly wind choke module. In this case, the fastening means can be made, for example, in the form of hooks, which, after curing, prevent the cramp from being pulled out of the cured material under wind load.

In one particularly preferred embodiment of the wind choke retaining module with this fastener, fastening means for connecting to the roofing element comprise at least one fastening foot, which is preferably made on the free end of at least one shoulder of the bracket and is spaced apart from it in the opposite direction at an acute angle that is, an angle less than 90 °, preferably at an angle less than 45 °. Depending on how the installation is carried out on the roofing element, the fastening means can be made facing either the inside of the bracket in shape and, for example, in the direction of the middle part between both arms of the bracket, or to the outside.

These structural forms can also be incorporated into a material that has not yet been cured, but are particularly suitable for subsequent installation on an already cured roofing element, if provided with appropriate active agents. It also makes it possible to replace the bracket if replacement of the retaining module of the wind choke or parts thereof is required.

Such a fastening foot in its basic form can be provided with a smooth straight edge, however, any profiles, for example, with elevations, for example, a wavy profile, can be knocked out at this edge. To improve the connection between the roofing elements and the fastening of the wind choke locking module, at least one of the fastening tabs has at least one row with elevations in the form of teeth or hooks for engagement with the power closure

- 5 032321 with a roofing element. The implementation of the teeth is also technologically preferable if the bracket, for example, is stamped from metal, as then the teeth can be cut out.

Preferably, the bracket is made of metal. This material, in comparison with plastic, has the advantage of higher elasticity or elastic deformability, which has a positive effect under wind load.

The fastening means may also be such that the bracket is suitable for use with such roofing elements in which a blind hole has already been made, for example, if the retaining module of the wind suction is to be replaced. In this case, the length of the bracket shoulder at the free end approximately corresponds to the diameter of such a blind hole or is slightly less, and the fastening means at the free end of the bracket shoulder contain, for example, a half-rail extension perpendicular to the longitudinal axis of the bracket shoulder, which in the inserted state also corresponds to the longitudinal axis of the blind hole . Then, on the outer contour of the half-chested expansion, at an acute angle, the backs are made in the inserted state as indicating teeth in the direction of opening of the blind hole or the like.

Logically, the invention also relates to a system of a roofing element with a locking module of the wind suction with a bracket made in the form of a bracket. At the same time, the groove-like recesses or essentially bar-shaped protrusions are made on the roofing element as engaging means for fastening the locking module of the wind suction. The height of the protrusions or the depth of the grooves is set by the side walls of the grooves or protrusions, and they do not have to be located at right angles to the surface of the roofing element in the place where the groove or protrusion is made. Then the fastening means for connecting the staples to the roofing element are made on at least one of the side walls, engaging with it.

To increase the stability of the recess or the protrusions may have a trapezoidal cross-section, and the side walls correspond to the inclined sides of the trapezoid. Moreover, the angle that the inclined sides of the trapezoid enclose with the perpendicular of the parallel sides is preferably smaller than the angle that the fastening tabs enclose with the sides of the opening. This, on the one hand, facilitates the installation of brackets and, when bonded, increases the stability of the connection, since the roofing element in this area only has blunt edges, which reduces the risk of destruction due to material fatigue.

It goes without saying that the above and yet to be explained further features are applicable not only in these combinations, but also in other combinations or independently, without going beyond the scope of the present invention.

Brief Description of the Drawings

Further, by way of example, the invention is explained in even more detail in the accompanying drawings, which also disclose features essential for the invention.

Shown in FIG. 1 - coupling element for the locking module of the wind suction, FIG. 2A, 2B are views of the fastening for the retaining module of the wind choke, FIG. 3A, 3B - the first version of the bracket, FIG. 4A, 4B - bracket from FIG. 3 in perspective view, FIG. 5A, 5B - the second variant of the bracket, FIG. 6A, 6B - bracket from FIG. 5 in perspective view, FIG. 7A-7B is a third embodiment of the bracket, FIG. 8A-8G are other variants of the bracket, FIG. 9A, 9B is an embodiment of a bracket for insertion into a blind hole.

Detailed Description of Drawings

In FIG. 1 shows a coupling member 1 for a retaining module of a wind choke for roofing elements on a roof or facade structure. The coupling element 1 is made with the first shelf 2 for engagement under the bearing element of the roof or facade structure. In addition, the wind choke locking module comprises a fastener 3 for holding the coupling member 1, such a fastener 3 is shown in FIG. 2A and 2B. The fastener 3 comprises connecting means for connecting the fastener 3 to a roof element not shown. The coupling element 1 is held in the fastener 3 with the possibility of movement along the axis of movement, which runs substantially parallel to the direction of the roof slope, and optionally, as in this case, can be rotated around the axis of rotation. In this case, the axis of movement and the axis of rotation coincide. The first shelf 2 is located at a distance from the axis of movement. The coupling element is made with the first part 4 of the yoke and the second part 5 of the yoke. The first part 4 of the yoke and the second part 5 of the yoke are connected to each other at the top 6 of the yoke. The first shelf 2 is hooked at the end of the first part 4 of the yoke, and the second part 5 of the yoke is at least partially located on the axis of movement, that is, the second part 5 of the yoke also corresponds to the axis of movement, which simultaneously corresponds to the axis of rotation.

On the second part 5 of the yoke in the region of the apex 6, a support element 7 is made on the side facing away from the first part of the yoke, which lies in the first part of the yoke and the second part of the yoke

- 6 032321 plane and here is made in the form of a protrusion.

At one end of the first shelf 2, a fixing tab 8 is provided here, the first shelf 2 and the fixing tab 8 preferably enclosing an angle different from 180 ° for better fit to the carrier when the wind is sucked. On the mounting tab 8, several edges 9 are arranged substantially parallel to the axis of movement for fixing the roof structure bearing member under load as a result of wind suction, the edges 9 being located at different distances from the axis of movement. Due to this, it is possible to adapt to different allowable thicknesses of the bearing elements, so that for each thickness of the bearing element is set the same maximum air gap with wind suction. In addition, in the edges 9, an helical profile 10 is made as an example for engagement with the supporting element with a force circuit under load due to wind suction.

In addition, the coupling element 1 contains a second shelf 11 for engagement between the lower and upper roofing elements. The second shelf 11 has a smaller distance to the axis of movement than the first shelf 2, here it is parallel to it, but it can also form an extension of the axis of movement, that is, the second part 5 of the yoke, or be at an angle to it. The second shelf 11, as well as the first shelf 2, may have a curved shape, if circumstances so require. The first shelf 2 through the cross member 12 is connected to the second shelf 11 and the second part 5 of the yoke. Due to this, the first shelf 2 forms with the second shelf 11, essentially, the shape of the bracket, without, however, assuming the function of the bracket in the sense of a spring element. The straight segments of the first part 4 of the yoke and the second part 5 of the yoke can be made shorter, so that the bend in the opposite region of the top of the yoke can be reduced, that is, the first part 4 of the yoke and the second part 5 of the yoke enclose a larger angle than shown. On the cross member 12, there is a nozzle element 13 for the nozzle of the tool. The nozzle element 13 for higher stability against the effects of forces is preferably partially covered by the cross member 12 and the second shelf 11.

In the embodiment shown here, the first shelf 2, the displacement axis, the pivot axis, and the second shelf 11 lie in the same plane, which provides advantages in storing roofing elements that are already made with retaining modules of the wind choke. The second shelf 11 is not made here as an extension of the displacement axis or the second part 5 of the yoke, which, however, is possible in principle, but at a distance specified by the dimensions of the roofing elements to the displacement axis, it is directly adjacent to functioning as a distance element for both sides 2, 11 cross member 12. And the first shelf 2 can also be made so that it starts on the cross member 12. This allows, for example, to design steeper yokes with shorter parts of the yoke. An reinforcing strut 14 is located between the cross member 12 and the first part 4 of the yoke, it is favorable for stabilizing the stop module of the wind suction, but is not absolutely necessary for its function. The reinforcing strut 14 serves to distribute forces under tensile load as a result of wind suction.

In the area in which the cross member 12 and the first part 4 of the yoke are adjacent to each other, they enclose an angle of 90 °. For mechanical reinforcement of the coupling element 1, a rounded curve 15 is made in this area. Accordingly, between the first part 4 of the yoke and the second part 5 of the yoke there is an optional plate reinforcement 16, which stabilizes the region of the vertex 6. Here it occupies only a small area of the coupling element 1, but the reinforcement can also extend over a large area while the movability of the coupling member remains possible.

The coupling member 1 is movably and pivotally mounted in the linear guide 17, which is shown in FIG. 2 on the fastener 3. The second yoke part 5 lying on the axis of movement is located in this linear guide 17. The linear guide 17 has two ends. A chamfer 18 is made on the side pointing away from the end of the vertex 6. It serves to ensure that the curve 15 on the engaging element 1 can abut against it, so that the mechanical stability of the locking module of the wind suction is improved and the coupling of the coupling element 1 is facilitated in connection with lack of sharp edges that can cause warping.

In order to prevent inadvertent rotation of the coupling element 1 during transportation or during installation of the roofing element, the fastener 4 has a transport fuse 19, which, as can be seen from FIG. 2A - here is made in the form of a locking connection with a clamping block. Here, the fastening is additionally made with the guide protrusion 20 parallel to the linear guide 17. The guide protrusion 20 enters the corresponding guide groove on the lower side of the roofing element - not shown here - if it is made there. Thus, the fastener 3, for its part, is protected from twisting, which is an advantage when the fastener is not connected to the roofing element with dowels, glue or screws, but is inserted into the blind hole, which is made on the inside of the roofing element, using at least partially reversibly deformable fitting part 21. Moreover, the blind hole along its contour is at least partially made in the form of a truncated cone with a shape tapering to the opening. In the direction of the blind hole, that is, perpendicular to the surface of the tile, in this way can be obtained compounds

- 7 032321 geometrical and power short circuits, since the fitting part 21 is partially compressed so that it can be inserted through the opening into the blind hole, and expands again after insertion.

The fitting part 21 in the upper section has an opening 22 for inserting a tool for removing the fastening 4 from the roof element. For example, a screw can be screwed in there, which cuts the thread in the fitting part 21. On it, the fastener 3 can be extended. In addition, the fitting part 21 in the upper section has rib-shaped protrusions 23 on the contour, which serve to improve the stability of the bolt in the blind hole. These rib-shaped protrusions are only indicated here, here they are located in the middle on the fitting surfaces of the bolt or fitting part 21, which, for insertion into the blind hole, are compressed to their common axis of symmetry and then moved apart again.

In FIG. Figure 3 shows the fastener, which is suitable, first of all, for the manufacture of tiles or concrete tiles by means of continuous profile pressing, since the necessary means for fastening the fastenings to the tiles can be integrated without problems into the molds or holes used for molding. Here, the mount is made in the form of a bracket 24 and is shown in FIG. 3A in cross section, and in FIG. 3B - in the future. It comprises at least two opposing arms of the bracket 24 and a spring portion 26 connecting the arms of the bracket in a spring-like manner. The bracket covers, as shown in FIG. 3B, the second part 5 of the yoke, at least partially with the middle part 26 suppressing the movement of the second part 5 of the yoke in the plane of the drawing up. Fastening means for connecting to the roofing element 28 are made on the brackets of the bracket; the latter is shown to explain the principle of operation of the bracket 24 in the form of a fragment in FIG. 3B.

In the bracket 24, the fastening means comprise two fastening tabs 27. They are made on the free ends of the arms 25 of the bracket and are spaced apart from them at an acute angle in the opposite direction — here inward in the direction of the middle part 26. On the fastening tabs 27 — as shown in FIG. 4A, a series of protrusions are made in the form of teeth 32, which improve the entry with a force closure into the roofing element 28. If the bracket is made of metal, then the teeth 32 are cut from the fastening legs 27.

Further, the principle of operation is illustrated in FIG. 3B and 4B, in which, in each case, a system is shown consisting of a roofing element 28 and a retaining module for locking the roofing element 28 on a roof or facade structure from a wind choke, here represented by a fragment of the second part 5 of the yoke. On the roofing element 28, bar-shaped protrusions 29 are made with a height that is limited by the side walls 30. The bar-shaped protrusions 29 serve as hooking means for attaching the locking module of the wind suction. The fastening means here the fastening tabs 27 with the teeth 32 are made on the side walls crashing into them. The beam-shaped protrusions 29 form, together with the middle part 26 of the bracket 24, a guide for the second part 5 of the yoke, and thereby for the coupling element of the locking module of the wind suction. In case of loading as a result of wind suction, the acting wind tries to push the second part 5 of the yoke up. The middle part 26 is pressed up and bends as an arc of shape and. As a result of this, the arms 25 of the bracket are pressed inward, and the teeth 32 made on the fastening legs 27 act more strongly on the side walls 30 than would be without a wind choke. That is, the action of the wind suction action of the bracket 24 is enhanced. In this case, the bracket 24 dispenses with absolutely no additional fastening means, such as screws or the like, it is itself a fastening means.

Similar to that shown in FIG. 4, it is also possible for the system that the bracket has outwardly fastening tabs 27 and respectively fits between two beam-shaped protrusions 29, and in each case only one shoulder 25 of the bracket is in each case between the second part 5 of the yoke and one of the side walls 30 of the beam-like protrusions. Finally, instead of the bar-shaped protrusions 29 on the roofing element 28, groove-shaped recesses can also be equivalently provided. If the corresponding surface of the roofing element 28 is provided with a corrugated structure, then there are simultaneously protrusions and recesses.

In FIG. 5 and 6 show another bracket 31, in FIG. 5A is a cross-sectional view, and in FIG. 6A is a perspective view, and in FIG. 5B and 6B, respectively, in a system with a roofing element 28. In contrast to that shown in FIG. 3, the brackets here are made spaced apart on both sides of the shoulders 25 of the bracket, the fastening tabs 27, on which the teeth 32 are also made. By double fastening, the action of the bracket is enhanced on each side and the resistance to wind suction is improved.

Another embodiment is shown in FIG. 7A-7B. The bracket 33 shown therein comprises a middle portion 26 with an almost circular cross section, so that the middle portion 26 almost completely surrounds the second yoke portion 5 and thereby forms a guide for it. One of the arms 25 of the bracket is made, as described, with a fastening tab 27, the other of both arms 25 of the bracket is provided with a profile 34, so that it only adjoins the side wall of the corresponding protrusion or recess, but does not develop a counteracting effect under wind load. Then the action of the bracket depends, among other things, on the depth of the profile, the diameter of the middle part 26 and on the distance of both side walls 30 of the bar-shaped protrusion 29 or the groove-shaped recess, between which the bracket 33 is placed.

The brackets can also be made so that at least one fastening tab 27 has two or more rows of protrusions or teeth 32 located one above the other, or

- 8 032321 on at least one shoulder 25 of the bracket two or more fastening tabs 27 are made, if necessary with rows of protrusions or teeth 32. Such a structural form is shown for the bracket in FIG. 8A shown in FIG. 8B and 8B, the bracket corresponds to bracket 24. Shown in FIG. 8G, the bracket 36 is similar to that shown in FIG. 7, bracket 33, but the diameter of the second part 5 of the yoke is substantially smaller than the diameter of the middle part, so that the first has a significantly larger backlash.

In FIG. 9A in cross section, and in FIG. 9B, a cross-section in perspective shows a bracket 37, which can also be used with a blind hole 38. The teeth 32 here are made directly on the arms 25 of the bracket and are spaced apart in several directions to provide the bracket with good hold in the blind hole 38.

List of reference designations.

one Coupling element one First shelf 3 Mount four The first part of the yoke five The second part of the yoke 6 Vertex 7 Supporting element eight Fixing foot 9 Edge ten Helical profile eleven Second shelf 12 Cross member 13 Nozzle element 14 Reinforcing strut 15 Rounding sixteen Gain 17 Linear guide 18 Chamfer nineteen Transport fuse 20 Guide 21 Fitting part 22 Hole 23 Rib protrusion 24 Staple 25 Staple shoulder 26 middle part 27 Fastening foot 28 Roofing element 29th Beam-shaped ledge thirty Side wall 31 Staple

32 Tooth 33 Staple 34 Profile 35.36.37 Staple 38 Blind hole

Claims (15)

CLAIM 1. A locking module for locking the roofing elements on the roof or facade structure from the wind choke, comprising a coupling element (1) with a first shelf (2) for engaging under the load-bearing element of the roof or facade structure, and also a mount (3) for holding the coupling element (1), and the mount (3) contains connecting means for connecting the mount (3) with the roofing element, and the coupling element (1) is held in the mount (3) with the possibility of movement along passing essentially parallel to the direction Kata roof displacement axis of the coupling element (1) and the first shelf (2) is located at a distance from the axis of movement, - 9 032321 and the coupling element (1) is made in the form of a yoke with the first part (4) of the yoke and the second part (5) of the yoke, which are connected to each other at the top (6) of the yoke, and at one end of the first part (4) of the yoke the first shelf (2) is made engaging, and the second part (5) of the yoke is at least partially located on the axis of movement, moreover, at one end of the first shelf (2) there is a mounting tab (8), characterized in that the second part (5) of the yoke in the region of the apex (6) on the side facing away from the first part (4) of the yoke, the support element (7) is made, and on the fixing tab (8) has several edges (9) arranged substantially parallel to the axis of movement to lock the roof structural member under load as a result of wind suction, the edges (9) being located at different distances from the axis of movement. 2. The locking module according to claim 1, characterized in that the supporting element (7) is made in the form of a protrusion and / or is located in the plane formed by the first part (4) of the yoke and the second part (5) of the yoke. 3. The locking module according to one of claims 1 or 2, characterized in that the first shelf (2) and the fixing tab (8) enclose an angle different from 180 °. 4. The locking module according to claim 3, characterized in that preferably a wavy profile or helical profile (10) is made on the edges for engaging with a force circuit with the supporting element under load as a result of wind suction. 5. The locking module according to one of claims 1 to 4, characterized in that the coupling element (1) contains a second shelf (11) for engagement between two roofing elements, the second shelf (11) having a smaller distance from the axis of movement, than the first shelf (2), and wherein the first shelf (2) with the second shelf (11) and the second part (5) of the yoke is connected to the cross member (12) and forms with it, essentially, the shape of a bracket, and on the cross member (12) is made a nozzle element (13) for a tool nozzle, which is preferably partially covered by a cross-member (12) and a second lkoy (11). 6. The locking module according to one of claims 1 to 5, characterized in that the fastener (3) has a rod-shaped, at least partially reversibly deformable fitting piece (21) for insertion into a blind hole on the roofing element, which has a lower section for introducing into the blind hole and the upper section, and the fitting part (21) has a hole (22) for inserting a tool to remove the fastening from the roofing element. 7. The locking module according to claim 6, characterized in that the fitting part (21) in the upper section has rib-shaped protrusions (23) on the contour. 8. The locking module according to one of claims 1 to 6, characterized in that the mount (3) has a linear guide (17), in which the coupling element (1) is mounted for movement and rotation, and in which the part located on the axis of movement the second part (5) of the yoke, and the linear guide (17) has two ends, and a chamfer (18) is made on the end that faces from the top (6). 9. The locking module according to one of claims 1 to 5, characterized in that the fastening is made in the form of a bracket (24, 31, 33, 35, 36, 37) with at least two opposite each other shoulders (25) of the bracket and spring connecting them in each case at one end with a middle part (26), which at least partially covers the second part (5) of the yoke and on which brackets are made on the brackets (25) for connecting to the roofing element. 10. The locking module according to claim 9, characterized in that the fastening means for connecting to the roof element comprise at least one fastening foot (27), which is preferably made on the free end of at least one shoulder (25) of the bracket and is spaced apart from him in the opposite direction at an acute angle, preferably at an angle of less than 45 °. 11. The locking module according to claim 10, characterized in that at least one fastening tab (27) is made of at least one row of protrusions, preferably in the form of teeth (32) or hooks for engagement with a force closure with the roof element. 12. The locking module according to claim 11, characterized in that at least one fastening tab (27) has two rows of protrusions located one above the other and / or that at least one bracket (25) has two or more fastening tabs one above the other (27). 13. The locking module according to one of claims 9 to 12, characterized in that the bracket (24, 31, 33, 35, 36, 37) is made of metal. 14. A system consisting of a roofing element (28) and a locking module designed to lock the roofing element (28) on the roof or facade structure from the wind suction and made according to one of claims 9-12, and on the roofing element (28) groove-shaped recesses or beam-shaped protrusions (29) in each case with depth or height defining side walls (30) as engaging means for fastening the locking module, wherein fastening means on at least one of the side walls (30) are provided yaschimi engage with it. 15. The system according to 14, in which the recesses or protrusions (29) have a trapezoidal transverse - 10 032321 stitching with the side walls (30) as the inclined sides of the trapezoid, more preferably the angle that the inclined sides of the trapezoid enclose with the perpendicular to the parallel sides of the trapezoid is less than the angle that the fastening tabs (27) enclose with the sides of the opening. 8 2 13 5 7