EP3798383B1 - Fixing device and method for producing a facade - Google Patents

Description

The invention relates to a holding device for plate- or profile-shaped building elements for producing a facade, in particular a ventilated facade, according to the preamble of claim 1.

Furthermore, the invention relates to a method for producing a facade, in particular a ventilated facade, using such a holding device.

State of the art

With the help of a holding device of the type mentioned above, plate or profile-shaped building elements can be attached to a building surface, in particular to a wall. The plate or profile-shaped building element can be, for example, a plate-shaped facade element or a support profile for holding a plate-shaped facade element. The wall that forms the building surface can be solid or designed as a stud wall.

If the holding device is used to attach facade elements, the wall is an external wall, which is usually insulated.

In the case of a solid wall, the insulation layer is usually attached to the outside. Since the holding device cannot be attached to the insulation layer for static reasons, the holding device must be guided through the insulation layer to the building's substructure. This means that the holding device must have a certain projection in order to bridge the gap created by the insulation layer between the building's substructure and the panel-shaped facade elements or the support profiles for holding the panel-shaped facade elements. If the facade is also a ventilated construction, there is an additional air layer to be bridged in addition to the insulation layer.

In a wall constructed as a stud wall, at least part of the insulation can be arranged in the compartments between the studs. The compartments are usually closed by wall panels that are placed over the studs. Since the studs form the load-bearing wall structure, the holding device must be attached to the studs through the wall panels. The projection of the holding device therefore corresponds to at least the total thickness of the wall panels. If an additional insulation layer is arranged in front of the studs, the projection increases by the thickness of the insulation layer. In the case of a ventilated facade, the thickness of the air layer is added.

Depending on the application, the projection of the holding device can therefore vary. Furthermore, construction and/or assembly tolerances can require at least a small length adjustment. Holding devices are therefore already known from the state of the art that can be combined with spacers of different lengths and/or adjusted depending on the application in order to enable adaptation or adjustment. As a rule, however, adjustment is not only necessary in relation to the distance of the facade elements from the building substrate, but also in relation to the Height of the facade elements is desired. The complexity of the holding devices increases accordingly.

From the EP 0 718 451 A1 A holding device for fastening thermal insulation panels to a building substrate is known, which comprises a threaded bolt, which has a mounting plate at one end for fastening to the substrate and a holding plate at the other end for fixing the thermal insulation panel. Two collar elements extending in a circular arc extend on the top of the holding plate, which can be brought into engagement with the bearing shoulders of a support profile by rotating the holding plate around the threaded bolt.

The present invention is based on the object of specifying a holding device for plate or profile-shaped building elements for producing a facade, which is simple in construction and can therefore be produced inexpensively. Furthermore, the holding device should be easy to assemble and enable adjustment to compensate for construction and/or assembly tolerances in at least one spatial direction, in particular in a direction perpendicular to and/or parallel to the building subsurface.

To achieve the object, the holding device is specified with the features of claim 1. Advantageous further developments of the invention can be found in the subclaims. Furthermore, a method for producing a facade using such a device is proposed.

disclosure of the invention

The holding device for plate or profile-shaped building elements proposed for the production of a facade comprises a holding plate and a threaded bolt, by means of the retaining plate can be fastened to a construction-side substrate at a distance. The retaining plate has an opening, preferably a through-opening, with an internal thread for receiving the threaded bolt and at least one circular-arc-shaped elongated hole and/or at least one circular-arc-shaped row of holes, wherein the elongated hole and/or the row of holes is/are arranged concentrically or eccentrically in relation to the opening.

During assembly or when manufacturing a facade, the retaining plate of the proposed retaining device is screwed onto the threaded bolt, preferably after the threaded bolt has been fastened to the on-site substrate or the wall. after anchoring the threaded bolt in the building's subsurface. The screw connection enables the holding device to be rotated relative to the threaded bolt and thus relative to the building's subsurface, whereby the distance of the holding plate to the building's subsurface changes at the same time. In this way, the distance of the holding plate to the building's subsurface can be adjusted and construction and/or assembly tolerances can be compensated for in a direction perpendicular to the building's subsurface. The distance can also be adjusted continuously.

Depending on the specific design of the retaining plate, an alignment in a direction parallel to the building subsurface can also be achieved simply by turning the retaining plate. This is the case if the at least one circular-arc-shaped elongated hole and/or the at least one circular-arc-shaped row of holes is/are arranged eccentrically in relation to the opening in the retaining plate in which the threaded bolt is received. In this case, when the retaining plate is rotated relative to the threaded bolt, the height of the at least one elongated hole and/or the at least one row of holes also changes. Since the at least one elongated hole and/or the at least one row of holes serves to accommodate a fastening device, for example a screw or a rivet, for fastening the plate- or profile-shaped component, the height of the plate- or profile-shaped component can also be changed in this way. This also makes it possible to compensate for construction and/or assembly tolerances in a direction parallel to the building subsurface.

The plate or profile-shaped component to be fastened can already be equipped with at least one hole for receiving a fastening device. In this case, the at least one hole in the plate or profile-shaped component determines the position of the fastening device. In order to be able to use the at least one slotted hole and/or the at least one row of holes in the retaining plate in as many positions as possible on the retaining plate to overlap with the at least one hole in the plate- or profile-shaped component, the elongated hole and/or the row of holes is/are designed in the shape of a circular arc. This means that the elongated hole and/or the row of holes is/are guided along a circular line over a certain angular range. This ensures that even after adjustment by turning the holding plate relative to the threaded bolt, there is still a common overlap area for inserting the fastening device. Since adjustment of the holding plate should normally only require a slight rotation of the holding plate relative to the threaded bolt, the at least one circular arc-shaped elongated hole and/or the at least one circular arc-shaped row of holes can extend over a restricted angular range of less than 180°, preferably less than 120°, and furthermore preferably less than 90°. This applies in particular if the holding plate has a plurality of circular-arc-shaped elongated holes and/or a plurality of circular-arc-shaped rows of holes which run along a common and/or along a plurality of circular lines which are preferably arranged concentrically to one another.

The holding device for plate or profile-shaped building elements proposed for the production of a facade is therefore particularly suitable for the production of a ventilated facade, as the threaded bolt can be used to bridge larger distances to the building's substructure. In addition, the holding plate screwed onto the threaded bolt enables subsequent adjustment of the distance by turning the holding plate relative to the threaded bolt. With at least one eccentrically arranged slot and/or at least one eccentrically arranged row of holes in the holding plate, height adjustment is also possible.

The advantages of the holding device according to the invention are not only limited to outdoor use, but also become apparent when used indoors. This means that the holding device can be used in the same way to produce a "facade" or wall cladding indoors.

The holding plate is preferably made of metal, for example steel or stainless steel. The holding plate is therefore very strong.

According to a preferred embodiment of the invention, the holding plate has several circular-arc-shaped elongated holes and/or circular-arc-shaped rows of holes that are arranged concentrically to one another. This means that several circular-arc-shaped elongated holes and/or several circular-arc-shaped rows of holes run along several concentrically arranged circular lines. The possibilities of making them overlap with the at least one hole in the plate- or profile-shaped component increase not only with the number of circular-arc-shaped elongated holes or rows of holes, but also with the distribution of the elongated holes or rows of holes over several concentrically arranged circular lines. This applies in particular if the elongated holes and/or rows of holes are arranged eccentrically in relation to the opening in the holding plate that serves to receive the threaded bolt. In the case of eccentrically arranged circular-arc-shaped elongated holes and/or rows of holes, a common overlap area of an elongated hole or a row of holes with a hole in the plate- or profile-shaped component to be fastened can jump from a first, further outward circular line to a second, further inward circular line or vice versa by rotating the retaining plate relative to the threaded bolt.

Since the at least one elongated hole passes through the holding plate, this weakens the holding plate. The weakening increases with the size of the at least one elongated hole and with the number of elongated holes. The number of elongated holes is therefore preferably limited. For example, two, four, six or eight circular-arc-shaped elongated holes can be provided, of which preferably two each run along a common circular line. Alternatively, circular-arc-shaped rows of holes can be provided instead of the circular-arc-shaped elongated holes, since these weaken the holding plate less.

Preferably, the opening of the retaining plate used to receive the threaded bolt is surrounded by a plurality of elongated holes and/or rows of holes arranged on one circular line, on two circular lines, on three circular lines or on four circular lines around the opening. While the circular lines are preferably arranged concentrically to one another so that they have a common center, they can be arranged both concentrically and eccentrically in relation to the opening of the retaining plate.

In the case of a concentric arrangement, the retaining plate has at least two circular-arc-shaped elongated holes and/or rows of holes that are arranged at the same distance from the opening, with the distance remaining the same over the entire length of the elongated holes or rows of holes. It corresponds to the radius of the circular line on which the circular-arc-shaped elongated holes or rows of holes are arranged.

In the case of the eccentric arrangement, the retaining plate has at least two circular-arc-shaped elongated holes and/or rows of holes in a mirrored arrangement in a top view, with the mirror axis running through the middle of the opening. Here too, the distance between the elongated holes or rows of holes opposite one another at the opening and the opening is preferably the same if the distance is measured perpendicular to the mirror axis. In the case of the eccentric arrangement, however, the distance to the opening varies over the length of the elongated holes or rows of holes, since the radius of the circular line on which the elongated holes or rows of holes are arranged does not end at the center of the opening, but is offset by the amount of eccentricity on the mirror axis running through the middle of the opening.

According to a preferred embodiment of the holding device according to the invention, the holding plate has circular-arc-shaped elongated holes and/or rows of holes arranged in pairs on a common circular line, which are opposite each other at the opening of the holding plate in a mirrored arrangement. The number of The number of pairs of elongated holes and/or pairs of rows of holes can in particular be three, since in this case the holding plate is optimized with regard to adjustment options and stability requirements.

To increase the stability of the retaining plate, it can be made thick enough. Alternatively or additionally, at least one embossing can be provided, which leads to a plastic deformation of the retaining plate in some areas. For example, embossings can be made that lead to a rise in the retaining plate on the one hand and a depression in the retaining plate on the other. In this way, the dimensional rigidity of the retaining plate is increased. Preferably, at least two embossings are provided, which are opposite each other at the opening in the retaining plate intended to accommodate the threaded bolt and thus stabilize the retaining plate, particularly in the area of the opening, since the bending stress on the retaining plate is particularly high here.

Alternatively or additionally, it is also proposed that the opening in the retaining plate is formed by a sleeve that is firmly connected to the retaining plate or is formed by the retaining plate. The sleeve simplifies the production of the internal thread for receiving the threaded bolt, since a larger surface is available. The retaining plate, on the other hand, can have a comparatively low thickness, since the sleeve also provides further stiffening of the retaining plate. The sleeve can be open on both sides so that a through opening is formed, or it can be closed at one end so that the maximum screw-in depth of the threaded bolt is specified.

The threaded bolt preferably has a thread-free section, which preferably has an enlarged outer diameter compared to a threaded section for connection to the retaining plate, so that the threaded bolt forms a ring-shaped contact shoulder. The contact shoulder limits the screw-in depth and thus the adjustment path in the direction perpendicular to the construction substrate, so that a The minimum distance between the retaining plate and the building substrate is ensured. If the facade to be constructed is a ventilated facade, this can ensure that a minimum layer thickness of an air layer serving as rear ventilation is maintained. This is particularly advantageous if the opening in the sleeve for receiving the threaded bolt is designed as a through-hole, as in this case the screw-in depth is unlimited.

The threaded bolt of the proposed holding device can be attached directly or indirectly to the building's substructure or anchored in the building's substructure. The holding device can be extended with appropriate aids for indirect attachment or anchoring.

For example, the holding device can comprise a mounting plate for support on the on-site substrate. In this case, the mounting plate preferably has an opening, preferably a through-opening, with an internal thread for connection to a threaded section of the threaded bolt. When producing a facade, the mounting plate is first attached to the on-site substrate, for example using screws, and then the threaded bolt is screwed into the opening in the mounting plate. To ensure that the holding plate is not unscrewed from the mounting plate again when it is screwed onto the threaded bolt, the thread of the threaded section for connection to the mounting plate is preferably opposite to the thread of the threaded section that is used to connect the threaded bolt to the holding plate. This means that the two threaded sections, preferably at the end, on the threaded bolt are opposite.

In order to facilitate the fastening of the mounting plate to the on-site substructure, the mounting plate can have at least one further opening for receiving a screw in addition to the opening for receiving the threaded bolt. The at least one further opening is designed as a through-hole. It can circular or as an elongated hole. The opening for receiving the threaded bolt can be designed in a similar way to the opening in the holding plate. In particular, the opening in the mounting plate can be formed by a sleeve that is connected to the mounting plate or is formed by the mounting plate itself. The sleeve simplifies the production of the internal thread for receiving the threaded bolt because a larger area is available.

According to a preferred embodiment of the invention, at least one threaded section of the threaded bolt is a metric thread, for example an M8 thread. With an M8 thread, the adjustment path is 0.75 mm if the holding plate is rotated by an angular range of 180° relative to the threaded bolt. This has proven to be particularly advantageous.

However, the threaded bolt can also be attached or anchored to or in the building substrate without a mounting plate. For example, the threaded bolt can be anchored in the building substrate using an injection technique, in particular it can be glued into the building substrate.

Alternatively or additionally, the threaded bolt can be anchored in the building's substructure using a dowel. This can be a conventional dowel, for example a frame dowel. According to a further preferred embodiment of the invention, the proposed holding device therefore comprises a dowel for anchoring the threaded bolt in the building's substructure.

According to the invention, it is proposed that the holding device has a plate- or profile-shaped component, for example a support profile, with at least two holes, preferably elongated holes, which can be brought into at least partial overlap with the at least one circular-arc-shaped elongated hole and/or the at least one circular-arc-shaped row of holes in the holding plate. If the plate- or profile-shaped component is a support profile, a plate-shaped component, for example a facade panel, can be attached to it.

Preferably, the plate- or profile-shaped component of the holding device has a plurality of holes, preferably elongated holes, which form at least one row of holes running parallel to a longitudinal edge of the component. The large number of holes increases the fastening options. In order to enable secure fastening, two rows of holes are preferably provided along two parallel longitudinal edges of the component or support profile. If the component is a support profile, this can in particular be a hat profile that has a trapezoidal cross-section with two parallel flange areas for contact with the holding plate of the holding device. The rows of holes are then formed in the flange areas.

To solve the problem mentioned at the beginning, a method for producing a facade, preferably a ventilated facade, using a holding device according to the invention is also proposed. In the method, the threaded bolt is fastened to the building substructure or anchored in the building substructure. The holding plate is then screwed onto the threaded bolt, the distance of the holding plate from the building substructure being at least preset. A plate or profile-shaped component, for example a support profile, is then placed on the holding plate so that holes formed in the plate or profile-shaped component and the at least one circular-arc-shaped elongated hole and/or the at least one circular-arc-shaped row of holes in the holding plate have a common overlap area for receiving a fastening means, in particular a screw or a rivet. The plate or profile-shaped component can then be fixed in position on the holding plate with the aid of at least one fastening means. The fastening means can in particular be a self-tapping screw. In the case of a rivet as the fastening means, it can in particular be a blind rivet.

To precisely adjust the position of the plate or profile-shaped component in relation to the building substructure, the retaining plate is rotated relative to the threaded bolt, preferably before the final position of the plate or profile-shaped component is fixed to the retaining plate. This causes the retaining plate to move closer to or further away from the building substructure, so that the distance of the plate or profile-shaped component in relation to the building substructure is adjusted. Depending on the design of the retaining plate, the height can be adjusted at the same time. This is the case if a retaining plate is used that has at least one circular-arc-shaped slot and/or at least one circular-arc-shaped row of holes that is arranged eccentrically in relation to the opening for receiving the threaded bolt.

In the proposed method, the distance of the plate- or profile-shaped structural element to the on-site substrate and/or the height of the plate- or profile-shaped structural element is preferably adjusted by turning the retaining plate screwed onto the threaded bolt.

When carrying out the method according to the invention, the threaded bolt can be fastened to the on-site subsurface using a mounting plate. In this case, the mounting plate is preferably fastened to the on-site subsurface first. The threaded bolt is then screwed in. The mounting plate simplifies the installation of the threaded bolt. It also distributes the load, so that the load-bearing capacity of the holding device increases.

Alternatively, it is proposed that the threaded bolt be anchored in the on-site subsurface using an injection technique, in particular by being glued into the on-site subsurface. However, this requires that the on-site subsurface is a solid wall construction, otherwise the anchoring is inadequate.

As an alternative or in addition to the injection technique, the threaded bolt can be anchored in the on-site subsurface using a dowel. The dowel optimizes the anchoring in the on-site subsurface, so that the requirements for the subsurface can be reduced.

• Fig. 1 eine Draufsicht auf eine Halteplatte einer erfindungsgemäßen Haltevorrichtung,
• Fig. 2 eine Seitenansicht eines Gewindebolzens einer erfindungsgemäßen Haltevorrichtung,
• Fig. 3 eine Draufsicht auf und verschiedene Längsschnitte durch eine Montageplatte einer erfindungsgemäßen Haltevorrichtung,
• Fig. 4 einen schematischen Längsschnitt durch eine an einem bauseitigen Untergrund befestigte erfindungsgemäße Haltevorrichtung,
• Fig. 5 verschiedene Ansichten eines Halteprofils mit montiertem Tragprofil in unterschiedlichen Positionen zueinander,
• Fig. 6 eine Draufsicht auf eine weitere Halteplatte einer erfindungsgemäßen Haltevorrichtung,
• Fig. 7 einen schematischen Längsschnitt durch eine an einem bauseitigen Untergrund befestigte weitere erfindungsgemäße Haltevorrichtung und
• Fig. 8 eine Draufsicht auf und verschiedene Längsschnitte durch eine Abwandlung der Halteplatte der Fig.6.

Preferred embodiments of the invention are described in more detail below with reference to the accompanying drawings. The method according to the invention is also explained with reference to the drawings. They show:

• Fig. 1 a plan view of a holding plate of a holding device according to the invention,
• Fig. 2 a side view of a threaded bolt of a holding device according to the invention,
• Fig. 3 a plan view of and various longitudinal sections through a mounting plate of a holding device according to the invention,
• Fig. 4 a schematic longitudinal section through a holding device according to the invention attached to a construction substrate,
• Fig. 5 different views of a retaining profile with mounted support profile in different positions to each other,
• Fig. 6 a plan view of another holding plate of a holding device according to the invention,
• Fig. 7 a schematic longitudinal section through a further holding device according to the invention attached to a building substrate and
• Fig. 8 a top view and various longitudinal sections through a modification of the retaining plate of the Fig.6 .

Detailed description of the drawings

A holding device according to the invention for fastening a plate- or profile-shaped component 15 to a constructional base 3 comprises at least one holding plate 1 and a threaded bolt 2. A first preferred embodiment of a holding plate 1 is described below with reference to the Fig. 1 described.

The Fig. 1 The holding plate 1 shown has a rectangular basic shape. An opening 4 in the form of a through-opening is formed in the holding plate 1. The opening 4 is arranged centrally between the two short side edges and off-center between the two long side edges of the holding plate 1. The opening 4 is formed by a sleeve-shaped section 19 of the holding plate 1, which is provided with an internal thread 5. A web-like embossing 20 is provided on both sides of the opening 4 to increase the dimensional rigidity of the holding plate 1. Three circular-arc-shaped elongated holes 6 are formed above and below the opening 4. The elongated holes 6 are arranged on circular lines that are concentric to one another, but whose common center is arranged eccentrically in relation to the opening 4 or its center. The top view of the Fig. 1 clearly shows that the elongated holes 6 are mirrored, with the mirror axis As running through the center of the opening 4. The holding plate 1 is in this case mirror-symmetrical about the mirror axis As.

The Fig. 2 A threaded bolt 2 is to be removed, which together with the retaining plate 1 of the Fig. 1 a holding device according to the invention. The threaded bolt 2 has a threaded section 8, 13 at each of its two ends, the thread being a metric thread, namely an M8 thread. The two threaded sections 8, 13 have opposing threads, that is, a left-hand thread and a right-hand thread. Between the threaded sections 8, 13, the threaded bolt 2 has a thread-free section 7 with an enlarged diameter D, whereby in this case the diameter D is 10 mm. Due to the enlarged diameter D, the threaded bolt 2 forms a contact shoulder 9, which defines a maximum screw-in depth.

The holding device according to the invention can comprise, in addition to a holding plate 1 and a threaded bolt 2, a mounting plate 10 by means of which the holding device can be fastened to the on-site substrate 3. Such a mounting plate 10 is the Fig. 3 The mounting plate 10 has an opening 11 in the form of a through-hole, which is delimited by a sleeve-shaped section 21. The sleeve-shaped section 21 has an internal thread 12 for receiving a threaded bolt 2, which is analogous to the threaded bolt 2 of the Fig. 2 The mounting plate 10 can be fastened to the on-site substrate 3 by means of fastening means 18', for example in the form of screws. To accommodate the screws, further openings 23 are provided in the mounting plate 10, which are designed as through-openings. In order to increase the dimensional stability of the mounting plate 10, web-like embossings 22 are provided on both sides of the opening 11.

A holding device according to the invention, which is attached to a building-side substrate 3 by means of a mounting plate 10, is shown in the Fig. 4 The sleeve-shaped section 21 with the internal thread 12 into which the threaded bolt 2 is screwed is clearly visible. Fasteners 18' are used above and below the threaded bolt 2 to fasten the mounting plate 10 to the on-site substrate 3. The fastening means 18' are screws in this case. At the other end, a retaining plate 1 is screwed onto the threaded bolt 2. A profile-shaped component 15 in the form of a support profile is fastened to this, with the fastening being carried out using fastening means 18. In this case, it can be These can be self-tapping screws or rivets, preferably blind rivets.

Before the final positional fixation of a profile or plate-shaped component 15 on a holding plate 1 of a holding device according to the invention, the holding plate 1 and thus the plate or profile-shaped component 15 can be adjusted with regard to the distance to the building substrate 3 and/or with regard to the height. To do this, simply, as shown by way of example in the Fig. 5 As shown in the illustration, the retaining plate 1 screwed onto the threaded bolt 2 is rotated. Due to the screw connection with the threaded bolt 2, the retaining plate 1 moves towards the on-site substructure 3 or away from it. At the same time, the height can be adjusted if - as in the example of the Fig. 5 the case - the circular-arc-shaped elongated holes 6 of the holding plate 1 are arranged eccentrically in relation to the opening 4 and thus on the threaded bolt 2. In each of the angular positions shown, the circular-arc-shaped elongated holes 6 can be used to overlap the elongated holes 6 with holes 16 of a profile-shaped component 15, so that a common overlap area 17 is created, in the area of which the fastening means 18 can be arranged.

In the Fig. 5 The profile-shaped component 15 has a trapezoidal cross-section with two flange sections in which the holes 16 are arranged in a row. The holes 16 are also designed as elongated holes. The profile-shaped component 15 can thus be fastened to the holding plate 1 once at the top and once at the bottom using the fastening means 18.

A modification of a holding plate 1 for a holding device according to the invention is shown in Fig. 6 shown. Here, the holding plate 1 has a circular basic shape. This has a sufficient projection in any angular position of the holding plate 1 relative to a profile-shaped component 15, so that the holding plate 1 can be gripped more easily and rotated relative to the threaded bolt 2. The The outer diameter of the holding plate 1 is 140 mm. The Fig. 5 The profile-shaped component 15 shown, which is a hat profile, has, for example, a height of 110 mm.

Furthermore, the retaining plate 1 corresponds to the Fig. 6 the retaining plate 1 of the Fig. 1 , so that reference is made to the corresponding description.

The Fig. 7 1 shows a holding device according to the invention which is attached to a building substrate 3, in which the threaded bolt 2 is anchored in the building substrate 3 by means of a dowel 14. A mounting plate 10 can thus be omitted. Furthermore, an insulating layer 24 is formed on the building substrate, which is bridged by means of the threaded bolt 2. A holding plate 1 is screwed onto the threaded bolt 2, to which a profile-shaped component 15 is in turn attached by means of fastening means 18. The holding plate 1 can in particular be made according to the Fig. 1 or according to the Fig. 6 holding plate 1 shown.

The Fig. 8 is a modification of the retaining plate 1 of the Fig. 6 The retaining plate 1 has the same shape as the retaining plate 1 of the Fig. 6 a circular basic shape. Instead of the circular-arc-shaped elongated holes 6, the holding plate 1 is interspersed with circular-arc-shaped rows of holes 6'. The rows of holes 6' each consist of several circular-arc-shaped round holes, which, in contrast to the circular-arc-shaped elongated holes, weaken the holding plate 1 less. The circular lines K ₁ to K ₃ correspond to the circular lines along which the circular-arc-shaped elongated holes 6 of the holding plate 1 of the Fig. 6 This means that the circle lines K ₁ to K ₃ in the Fig. 8 the same diameter as the corresponding circle lines in the Fig. 6 The circular lines K ₁ to K ₃ make it clear that the rows of holes 6' as well as the slots 6 of the retaining plate 1 of the Fig. 6 are arranged eccentrically in relation to the central opening 4 of the holding plate 1. Thus, the height can be adjusted by turning the holding plate 1 relative to the threaded bolt 2.

Furthermore, the retaining plate 1 corresponds to the Fig. 8 the retaining plate 1 of the Fig. 6 , so that reference can be made to the corresponding description. In particular, the retaining plate 1 of the Fig. 8 the central opening 4 is limited by a sleeve-shaped section 19 (see longitudinal sections arranged at the side and below the top view). Furthermore, the holding plate 1 of the Fig. 8 20 embossings to increase the dimensional stability (see longitudinal sections).

list of reference symbols

1

retaining plate

2

threaded bolt

3

on-site subsurface

4

opening

5

internal thread

6

slot

6'

row of holes

7

thread-free section

8

threaded section

9

investment shoulder

10

mounting plate

11

opening

12

internal thread

13

threaded section

14

dowels

15

plate- or profile-shaped component

16

Hole

17

coverage area

18

fasteners

19

sleeve-shaped section

20

embossing

21

sleeve-shaped section

22

embossing

23

opening

24

insulation layer

Claims (15)

1. A fixing device for panel-like or profile-like structural elements (15) for production of a façade, preferably a suspended façade ventilated from behind, comprising a fixing plate (1) and a threaded bolt (2) by means of which the fixing plate (1) is fastenable at a distance to a structure-side substrate (3), wherein the fixing plate (1) has an opening (4), preferably a through-opening, with an internal thread (5) for receiving the threaded bolt (2) and at least one circular-arc-shaped slot (6) and/or at least one row of circular-arc-shaped holes (6'), and wherein the at least one slot (6) and/or the at least one row of holes (6') is arranged concentrically or eccentrically in relation to the opening (4),
   characterised in that the fixing device comprises a panel-like or profile-like structural element (15), for example a support profile, having at least two holes (16), preferably slots, which can be brought into at least partial overlap with the at least one circular-arc-shaped slot (6) and/or with the at least one row of circular-arc-shaped holes (6') of the fixing plate (1).
2. The fixing device according to claim 1,
   characterised in that the fixing plate (1) has a plurality of circular-arc-shaped slots (6) and/or rows of circular-arc-shaped holes (6'), which are arranged concentrically to one another.
3. The fixing device according to claim 1 or 2,
   characterised in that the fixing plate (1) has at least two circular-arc-shaped slots (6) and/or rows of circular-arc-shaped holes (6'), which are arranged at the same distance from the opening (4).
4. The fixing device according to any one of the preceding claims,
   characterised in that the fixing plate (1) in plan view has at least two circular-arc-shaped slots (6) and/or rows of circular-arc-shaped holes (6') in mirrored arrangement, wherein the mirror axis (As) runs centrally through the opening (4).
5. The fixing device according to any one of the preceding claims,
   characterised in that the threaded bolt (2) has a thread-free portion (7), which preferably has an enlarged outer diameter in relation to a threaded portion (8) for connection to the fixing plate (1), so that the threaded bolt (2) forms an annular contact shoulder (9).
6. The fixing device according to any one of the preceding claims,
   characterised in that the fixing device comprises a mounting plate (10) for support on the structure-side substrate (3) and the mounting plate (10) has an opening (11), preferably a through-opening, with an internal thread (12) for connection to a threaded portion (13) of the threaded bolt, wherein preferably the thread of the threaded portion (13) runs oppositely to the thread of the threaded portion (8) of the threaded bolt (2).
7. The fixing device according to claim 5 or 6,
   characterised in that at least one threaded portion (8, 13) is a metric thread, for example an M8 thread.
8. The fixing device according to any one of the preceding claims,
   characterised in that the fixing device comprises a dowel (14) for anchoring the threaded bolt (2) in the structure-side substrate (3).
9. The fixing device according to any one of the preceding claims,
   characterised in that the panel-like or profile-like structural element (15) has a plurality of holes (16), preferably slots, which form at least one row of holes running parallel to a longitudinal edge of the structural element (15).
10. A method for producing a façade, preferably a suspended façade ventilated from behind, using a fixing device according to any one of claims 1 to 9, in which method the threaded bolt (2) is fastened to the structure-side substrate (3) or anchored in the structure-side substrate (3), then the fixing plate (1) is screwed onto the threaded bolt (2), wherein the distance of the fixing plate (1) from the structure-side substrate (3) is at least pre-set, then the panel-like or profile-like structural element (15), for example a support profile, is placed against the fixing plate (1), so that holes (16) formed in the panel-like or profile-like structural element (15) and the at least one circular-arc-shaped slot (6) and/or the at least one row of circular-arc-shaped holes (6') of the fixing plate (1) have a common overlap region (17) for receiving a fastening means (18), in particular a screw or a rivet.
11. The method according to claim 10,
    characterised in that the panel-like or profile-like structural element (15) is fixed in position on the fixing plate (1) with the aid of at least one fastening means.
12. The method according to claim 10 or 11,
    characterised in that by rotating the fixing plate (1) screwed onto the threaded bolt (2), the distance of the panel-like or profile-like structural element (15) from the structure-side substrate (3) and/or the height position of the panel-like or profile-like structural element (15) is adjusted.
13. The method according to any one of claims 10 to 12, characterised in that the threaded bolt (2) is fastened to the structure-side substrate (3) with the aid of a mounting plate (10).
14. The method according to any one of claims 10 to 12, characterised in that the threaded bolt (2) is anchored in the structure-side substrate (3) with the aid of an injection technique, in particular is glued into the structure-side substrate (3).
15. The method according to any one of claims 10 to 12, characterised in that the threaded bolt (2) is anchored in the structure-side substrate (3) with the aid of a dowel (14).

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