EP4375439A1 - Mounting system and method for mounting an add-on part on a wall provided with insulating material - Google Patents

Abstract

Mounting system (1) for thermally separated mounting of an attachment (10) on a wall (2) provided with insulating material (3), the mounting system comprising at least one anchor element (4) with an anchor section (5) for anchoring in the wall and an adjoining connecting section (6), the anchor element further comprising a thermally insulating thermal bridge separation module (7) for at least section-wise arrangement in the insulating material, wherein the thermal bridge separation module is connected to the connecting section and has a receptacle (11) for a preferably screw-in fastening means (8', 9) for screwing the attachment tight, the mounting system further comprising at least one thermally insulating support component (12) for arrangement between the wall and the attachment in order to enable direct or indirect support of a first end region (13) of the support component on the wall and direct or indirect support of the attachment on a second end region (14) of the support component opposite the first end region, wherein the respective support component surrounds the respective anchor element in sections.

Description

FIELD OF INVENTION

The present invention relates to a mounting system for the thermally separated mounting of an attachment to a wall provided with insulating material, in particular to a wall provided with a thermal insulation composite system.

Furthermore, the present invention relates to a method for mounting an attachment to a wall provided with insulating material, in particular to a wall provided with a thermal insulation composite system, using a mounting system according to the invention.

STATE OF THE ART

Thermal insulation on building walls makes a significant contribution to reducing heating energy. This involves covering a wall with insulating material, which can be, for example, insulation panels made of synthetic inorganic material, such as calcium silicate, or insulation panels made of synthetic organic material, such as expanded polystyrene foam. Such insulation panels can be part of a thermal insulation composite system used to insulate the exterior walls of buildings, see https://de.wikipedia.org/wiki/Wärmedämmverbundsystem.

The term "wall" here and in the following refers only to those components or component sections that have a stable structure, in particular sufficient stability for the anchoring of anchor elements, and for this purpose can be constructed, for example, from concrete, aerated concrete or masonry (e.g. from perforated or solid brick).

Problems arise when particularly heavy attachments, such as brackets for awnings, air conditioning units, heat pumps or satellite systems, have to be mounted on a wall covered with insulating material.

Firstly, the fastening must be carried out in such a way that no thermal bridge is formed from the outside through the insulation material to the wall. In principle, solutions with anchor elements that include thermally insulating thermal bridge separation modules are known from the state of the art. However, these solutions are relatively expensive and the thermal bridge separation modules have rather unfavourable geometries that widen outwards, which can lead to such large recesses in the insulation material on the outside that they can no longer be covered by the attachment, which is to be seen as aesthetically disadvantageous at the very least.

On the other hand, the insulation material does not have a high level of mechanical stability and can give way under the pressure of the attachment, which - in addition to the poor appearance - can in turn have a detrimental effect on the stability of the attachment.

TASK OF THE INVENTION

It is therefore the object of the present invention to provide a mounting system and a method for mounting an attachment to a wall provided with insulating material. which avoid the disadvantages mentioned. In particular, a thermally insulated and mechanically stable fastening of the attachment to the wall provided with insulating material should be achieved.

DESCRIPTION OF THE INVENTION

To achieve the stated object, in a mounting system for the thermally separated mounting of an attachment to a wall provided with insulating material, in particular to a wall provided with a thermal insulation composite system, it is provided according to the invention that the mounting system comprises at least one anchor element with an anchor section for anchoring in the wall and an adjoining connecting section, the anchor element further comprising a thermally insulating thermal bridge separation module for at least section-wise arrangement in the insulating material, wherein the thermal bridge separation module is connected to the connecting section and has a receptacle for a, preferably screw-in, fastening means for screwing the attachment, the mounting system further comprising at least one thermally insulating support component for arrangement between the wall and the attachment in order to enable direct or indirect support of a first end region of the support component on the wall and direct or indirect support of the attachment on a second end region of the support component opposite the first end region, wherein the respective support component surrounds the respective anchor element in sections.

The anchor section of the respective anchor element can be formed, for example, by at least one section of an anchor rod, a screw or a threaded rod. If necessary, a dowel can be inserted into the wall so that the respective anchor section can be screwed into it.

The connecting section can also be formed by a section of an anchor rod, a screw or a threaded rod. A section adjoining this section can form the respective anchor section, i.e. the anchor rod, the screw or the threaded rod in this case comprises both the anchor section and the connecting section or forms them.

As mentioned, thermal bridge separation modules are known from the state of the art and are typically made from a plastic that is a poor conductor of heat. The thermal bridge separation module in particular provides thermal separation or insulation of the connecting section from the fastening means for screwing the attachment part. The thermal bridge separation module can be connected to the connecting section by screwing and/or gluing, for example.

Depending on the dimensions of the thermal bridge separation module and the insulation material, the thermal bridge separation module can be arranged entirely in the insulation material or can protrude outwards from it to a certain extent.

The holder for the fastening device for screwing the attachment can be designed differently depending on the fastening device. For example, the holder can have an internal thread into which the fastening device can be screwed, whereby the fastening device in this case can be, for example, a screw or a threaded rod plus a nut. In the case of the screw, the attachment is screwed tight with this. In the case of the threaded rod, the attachment is screwed tight with the nut.

However, it is also conceivable that a threaded rod plus nut is provided as a fastening means, but the holder does not have an internal thread and the threaded rod is glued into the holder using adhesive.

Of course, bonding is also possible if there is an internal thread in the holder.

For mechanical stabilization, at least one thermally insulating support component is provided, which is arranged between the wall and the attachment. Since the attachment is supported directly or indirectly on the second end region of the support component and the support component is supported directly or indirectly on the wall with its first end region, the support component acts as an abutment for the attachment.

With direct support, there is direct contact between the first/second end area and the wall/attachment. Preferably, the support component is contacted directly by the attachment during its assembly.

In the case of indirect support, one or more elements can be arranged between the first/second end area and the wall/attached part. For example, a washer or other spacer can be arranged between the attached part and the supporting component. In practice, the interposition of a "contamination", such as part of an interior plaster layer, an adhesive or a piece of insulation material, between the first/second end area and the wall/attached part cannot typically be excluded.

For thermal insulation of the support component, the latter can be made, at least in sections, from a thermally poorly conductive, pressure-resistant material, in particular from a thermally poorly conductive, pressure-resistant plastic.

In particular, the support component for thermal insulation can be designed, preferably by suitable material selection and/or material arrangement, such that it has a thermal conductivity from the first end region to the second end region (also called thermal conductivity or thermal conductivity coefficient) of not more than 0.35 W / (m K), preferably not more than 0.1 W / (m K).

By having the support component surround the respective anchor element in sections, it is ensured that no separate recess has to be created in the insulation material for the support component, but only a recess into which the respective anchor element is inserted with the support component surrounding it. Overall, the area of recesses potentially visible from the outside can therefore be kept very small.

In addition, the geometry of the necessary recess is essentially determined by the external shape of the support component, which can be designed independently of the external shape of the thermal bridge separation module. The "external shape" of the respective component is to be understood as the externally recognizable shape of the respective component considered in isolation. In particular, the external shape of the support component can be cylindrical, which enables the recess to be easily produced by drilling. Here and in the following, cylinder is essentially to be understood as a rotary cylinder, unless otherwise stated.

The support component only surrounds the anchor element in sections, since the support component does not surround the anchor section which is intended for anchoring in the wall. However, the support component can surround the connecting section and/or the thermal bridge separation module of the anchor element not only in sections, but also completely.

To ensure sufficient thermal insulation and mechanical stability of the support component, a preferred embodiment of the mounting system according to the invention provides that at least the first end region and/or the second end region of the support component, preferably the entire support component, is made of a, in particular glass-fiber or carbon fiber reinforced plastic.

Thermosets or thermosets in particular can be used as plastics with the desired thermal and mechanical properties.

In principle, the respective support component can also be manufactured in one piece.

With regard to optimal mechanical stability and/or manufacturing costs, a preferred embodiment of the assembly system according to the invention provides that only the first end region and/or the second end region of the support component are made of a plastic, in particular glass fiber or carbon fiber reinforced plastic.

In particular, between the first and second end regions, the respective support component can be made, for example, from materials that satisfy particularly high mechanical stability requirements and/or are cost-effective. Accordingly, in a particularly preferred embodiment of the assembly system according to the invention, it is provided that the respective support component is made from an aluminum alloy or a stainless steel or from a carbon fiber reinforced plastic in a middle section between the first end region and the second end region.

In a particularly preferred embodiment of the assembly system according to the invention, it is provided that the first end region or the second end region of the support component is made of the same material as the central section, and preferably in one piece with it. This variant is advantageous in terms of production technology and in terms of costs.

If the middle section itself is not thermally insulating or even has good thermal conductivity, the desired thermal insulation of the support component can still be ensured by making one of the two end regions from a thermally insulating material.

In a preferred embodiment of the assembly system according to the invention, it is provided that the respective thermal bridge separation module is arranged completely within the respective support component. A high level of mechanical stability can thereby be ensured, even if the thermal bridge separation module itself does not have a particularly high level of mechanical stability. In addition, the support component protects the thermal bridge separation module against external influences from lateral directions.

In a particularly preferred embodiment of the mounting system according to the invention, it is provided that the support component has a length along a longitudinal axis and projects beyond the thermal bridge separation module in the direction of its first end region and/or in the direction of its second end region. This promotes direct support of the support component on the wall and/or the attachment on the support component and enables particularly good protection of the thermal bridge separation module.

In order to optimize the protection of the thermal bridge separation module, a particularly preferred embodiment of the mounting system according to the invention provides that the support component projects beyond the thermal bridge separation module along the longitudinal axis and in the direction of its first end region and/or in the direction of its second end region by at least 5%, preferably at least 10%, of its length.

In a particularly preferred embodiment of the mounting system according to the invention, it is provided that in the respective area in which the support component is arranged along the A thermally insulating cavity filling, in particular made of foam rubber, is arranged in the longitudinal axis of the thermal bridge separation module. This contributes to the thermal insulation of the entire arrangement of anchor element and the support component surrounding it in a cost-effective and technically simple manner, with foam rubber proving to be particularly cost-effective.

In a preferred embodiment of the assembly system according to the invention, the respective thermal bridge separation module has a cylindrical shape when viewed from the outside. This facilitates a small size of the respective recess for the anchor element in the insulation material.

As mentioned, the support component can also have a cylindrical shape when viewed from the outside, whereby the cylindrical shape of the thermal bridge separation module has a favorable effect with regard to the production of the support component.

In order to enable the respective support component to surround the respective anchor element in sections in a simple manufacturing process, a preferred embodiment of the assembly system according to the invention provides that the respective support component is designed to be essentially tubular or sleeve-shaped, preferably completely, at least in a central section between its first end region and its second end region. Accordingly, during the manufacture of the assembly system according to the invention, the sleeve-shaped section of the respective support component can be pushed over the respective anchor element.

"Essentially tubular or sleeve-shaped" is to be understood as meaning that the support component may also have lateral holes and/or recesses and/or slots, which in extreme cases may result in a net-like appearance.

In the event that the support component is completely tubular or sleeve-shaped, the tubular or sleeve shape is present over the entire length of the support component measured along the longitudinal axis.

In a preferred embodiment of the assembly system according to the invention, the thermal bridge separation module is made of a plastic, in particular one reinforced with glass fiber or carbon fiber. This improves the mechanical stability of the respective thermal bridge separation module and thus of the respective anchor element.

In general, the mounting system according to the invention naturally allows for several anchor elements and the supporting components surrounding them.

Analogous to what has been said above, the invention provides an arrangement comprising an inventive mounting system, a wall provided with insulating material and an attachment which is mounted on the wall with the mounting system, wherein the first end region of the respective support component is supported directly or indirectly on the wall and wherein the attachment component is supported directly or indirectly on the second end region of the respective support component. Accordingly, the attachment component is mounted on the wall in a thermally separated manner, wherein the support component imparts a counterpressure when the screw connection of the attachment component is tightened.

• Verankerung des jeweiligen Ankerabschnitts des zumindest einen Ankerelements in der Wand und zumindest abschnittsweise Anordnung des jeweiligen Verbindungsabschnitts, des jeweiligen Wärmebrückentrennmoduls sowie des jeweiligen Stützbauteils im Dämmmaterial, wobei die Anordnung des jeweiligen Stützbauteils so ist, dass der erste Endbereich des jeweiligen Stützbauteils zur Wand weist und der zweite Endbereich von der Wand weg weist;
• Befestigung des Anbauteils durch Verschraubung mit dem jeweiligen Wärmebrückentrennmodul mittels eines Befestigungsmittels derart, dass sich der erste Endbereich des jeweiligen Stützbauteils direkt oder indirekt an der Wand abstützt und dass sich das Anbauteil direkt oder indirekt am zweiten Endbereich des jeweiligen Stützbauteils abstützt.

Analogous to the above, the invention further provides a method for mounting an attachment on a wall provided with insulating material, in particular on a wall provided with a thermal insulation composite system, using a mounting system according to the invention, the method comprising the following steps:

• Anchoring the respective anchor section of the at least one anchor element in the wall and at least in sections Arrangement of the respective connecting section, the respective thermal bridge separation module and the respective support component in the insulation material, wherein the arrangement of the respective support component is such that the first end region of the respective support component points towards the wall and the second end region points away from the wall;
• Fastening the attachment by screwing to the respective thermal bridge separation module by means of a fastening means in such a way that the first end region of the respective support component is supported directly or indirectly on the wall and that the attachment is supported directly or indirectly on the second end region of the respective support component.

This means that it is conceivable that a part of the respective anchor element and/or the support component protrudes outwards from the insulation material.

"Fastening the attachment by screwing it to the respective thermal bridge separation module using a fastening device" means that the attachment is screwed in place when it is installed. As already explained in detail above, the fastening device itself does not necessarily have to be screwed to the thermal bridge separation module or its holder, but rather a threaded rod could be arranged in the holder and glued to the thermal bridge separation module. The attachment is then screwed in place using a nut that is screwed onto the threaded rod.

In order to be able to mount particularly heavy attachments or to absorb high loads, a preferred embodiment of the method according to the invention provides for several anchor elements and supporting components surrounding them in sections, wherein at least two anchor elements and supporting components surrounding them in sections Supporting components are arranged one behind the other in the direction of gravity.

This means that an anchor element and an associated support component together form a unit, and at least two such units are arranged one behind the other in the direction of gravity in order to be able to support or support particularly high weights.

SHORT DESCRIPTION OF THE CHARACTERS

The invention will now be explained in more detail using exemplary embodiments. The drawings are examples and are intended to illustrate the inventive concept, but are in no way intended to restrict it or even represent it exhaustively.

Fig. 1

eine Frontansicht einer ersten Ausführungsform eines erfindungsgemäßen Montagesystems, wobei ein Gewindestab in einer Aufnahme eines Wärmebrückentrennmoduls des Montagesystems angeordnet ist

Fig. 2

eine schematische Schnittdarstellung gemäß der Schnittlinie II-II aus Fig. 1, wobei die Pfeile die Blickrichtung andeuten, wobei zusätzlich eine mit Dämmmaterial versehene Wand und ein mittels einer Mutter verschraubtes Anbauteil angedeutet sind

Fig. 3

eine Frontansicht einer zweiten Ausführungsform des erfindungsgemäßen Montagesystems, wobei ein Gewindestab in der Aufnahme des Wärmebrückentrennmoduls des Montagesystems angeordnet ist

Fig. 4

eine schematische Schnittdarstellung gemäß der Schnittlinie IV-IV aus Fig. 3, wobei die Pfeile die Blickrichtung andeuten, wobei zusätzlich eine mit Dämmmaterial versehene Wand und ein mittels einer Mutter verschraubtes Anbauteil angedeutet sind

Fig. 5

eine schematische Frontansicht einer mit Dämmmaterial versehenen Wand, an der ein Anbauteil mit einer dritten Ausführungsform des erfindungsgemäßen Montagesystems montiert ist

Fig. 6

eine schematische Schnittdarstellung gemäß der Schnittlinie VI-VI aus Fig. 5, wobei die Pfeile die Blickrichtung andeuten

Fig. 7

eine Frontansicht der dritten Ausführungsform des erfindungsgemäßen Montagesystems, wobei ein Gewindestab in der Aufnahme des Wärmebrückentrennmoduls des Montagesystems angeordnet ist

Fig. 8

eine schematische Schnittdarstellung gemäß der Schnittlinie VIII-VIII aus Fig. 7, wobei die Pfeile die Blickrichtung andeuten

It shows:

Fig.1

a front view of a first embodiment of a mounting system according to the invention, wherein a threaded rod is arranged in a receptacle of a thermal bridge separation module of the mounting system

Fig.2

a schematic sectional view along section line II-II of Fig.1 , where the arrows indicate the direction of view, with a wall covered with insulating material and an attachment screwed on with a nut also being indicated

Fig.3

a front view of a second embodiment of the mounting system according to the invention, wherein a threaded rod is arranged in the receptacle of the thermal bridge separation module of the mounting system

Fig.4

a schematic sectional view according to section line IV-IV of Fig.3 , where the arrows indicate the direction of view, with a wall covered with insulating material and an attachment screwed on with a nut also being indicated

Fig.5

a schematic front view of a wall provided with insulation material, on which an attachment is mounted with a third embodiment of the mounting system according to the invention

Fig.6

a schematic sectional view along section line VI-VI from Fig.5 , where the arrows indicate the direction of view

Fig.7

a front view of the third embodiment of the mounting system according to the invention, wherein a threaded rod is arranged in the receptacle of the thermal bridge separation module of the mounting system

Fig.8

a schematic sectional view along the line VIII-VIII of Fig.7 , where the arrows indicate the direction of view

WAYS OF IMPLEMENTING THE INVENTION

A front view of a first embodiment of a mounting system 1 according to the invention for the thermally separated mounting of an attachment 10 on a wall 2 provided with insulating material 3 is shown in Fig.1 , wherein a threaded rod 8' is arranged in a receptacle 11 of a thermally insulating thermal bridge separation module 7 of the mounting system 1. The threaded rod 8' forms together with a nut 9 a fastening means for screwing the Attachment part 10. Attachment part 10 can, for example, be a bracket for an awning.

Fig.2 shows a schematic sectional view along section line II-II of Fig.1 , where the arrows indicate the viewing direction and where the wall 2 provided with insulation material 3 (see the dotted lines in Fig.2 ) and the attachment part 10 screwed on by means of the nut 9 (see the dashed lines in Fig.2 ) are indicated. The mounting system 1 comprises at least one anchor element 4 with an anchor section 5, which is intended for anchoring in the wall 2 or in Fig.2 is anchored in the wall 2. In the first embodiment shown, the anchor section 5 is formed by a section of a threaded rod 8, wherein the threaded rod 8 also forms a connecting section 6 of the anchor element 4 adjoining the anchor section 5.

The thermal bridge separation module 7 is connected to the connecting section 6, whereby the threaded rod 8 is screwed into the thermal bridge separation module 7. The thermal bridge separation module 7 is intended for at least partial arrangement in the insulation material 3 or the thermal bridge separation module 7 and the connecting section 6 are in Fig.2 arranged in the insulation material 3.

The thermal bridge separation module 7 has, as mentioned, the receptacle 11 for the threaded rod 8', which in the first embodiment shown is screwed into the receptacle 11. The receptacle 11 has an internal thread (not shown) for this purpose.

The mounting system 1 further comprises at least one thermally insulating support component 12 for arrangement between the wall 2 and the attachment 10 in order to directly or indirectly support a first end region 13 of the support component 12 on the wall 2 and to directly or indirectly support the attachment part 10 at a second end region 14 of the support component 12 opposite the first end region 13. In Fig.2 the first end region 13 rests directly on the wall 2, and the attachment 10 rests directly on the second end region 14 of the support component 12.

The respective support component 12 surrounds the respective anchor element 4 in sections, wherein in the illustrated first embodiment the thermal bridge separation module 7 is arranged completely within the support component 12.

• Verankerung des jeweiligen Ankerabschnitts 5 des zumindest einen Ankerelements 4 in der Wand 2 und zumindest abschnittsweise Anordnung des jeweiligen Verbindungsabschnitts 6, des jeweiligen Wärmebrückentrennmoduls 7 sowie des jeweiligen Stützbauteils 12 im Dämmmaterial 3, wobei die Anordnung des jeweiligen Stützbauteils 12 so ist, dass der erste Endbereich 13 des jeweiligen Stützbauteils 12 zur Wand 2 weist und der zweite Endbereich 14 von der Wand 2 weg weist;
• Befestigung des Anbauteils 10 durch Verschraubung mit dem jeweiligen Wärmebrückentrennmodul 7 jeweils mittels Gewindestab 8' und Mutter 9 derart, dass sich der erste Endbereich 13 des jeweiligen Stützbauteils 12 direkt an der Wand 2 abstützt und dass sich das Anbauteil 10 direkt am zweiten Endbereich 14 des jeweiligen Stützbauteils 12 abstützt.

For the production of Fig.2 In the arrangement indicated, comprising the mounting system 1, the wall 2 provided with the insulating material 3 and the attachment 10, which is mounted on the wall 2 with the mounting system 1, a method is carried out which comprises the following steps:

• Anchoring the respective anchor section 5 of the at least one anchor element 4 in the wall 2 and at least partially arranging the respective connecting section 6, the respective thermal bridge separation module 7 and the respective support component 12 in the insulation material 3, wherein the arrangement of the respective support component 12 is such that the first end region 13 of the respective support component 12 points towards the wall 2 and the second end region 14 points away from the wall 2;
• Fastening of the attachment part 10 by screwing to the respective thermal bridge separation module 7 by means of a threaded rod 8' and a nut 9 in such a way that the first end region 13 of the respective support component 12 is supported directly on the wall 2 and that the attachment part 10 is supported directly on the second end region 14 of the respective support component 12.

Viewed from the outside, the thermal bridge separation module 7, which in the first embodiment shown is made of a glass fiber or carbon fiber reinforced plastic, has a cylindrical shape. In the first embodiment shown, the support component 12 surrounding the thermal bridge separation module 7 not only has a cylindrical shape when viewed from the outside, but is also designed as a hollow cylinder and thus completely tubular or sleeve-shaped - and not just in a central section 17 between the end regions 13, 14. Accordingly, a recess in the insulation material 3 for the anchor element 4 together with the support component 12 surrounding it in sections can be easily produced by drilling.

The support component 12 has a length L along a longitudinal axis 15. Along the longitudinal axis 15 and both in the direction of the first end region 13 and in the direction of the second end region 14, the support component 12 projects beyond the thermal bridge separation module 7 by approximately 10% of its length L.

Accordingly, due to the hollow cylindrical shape of the support component 12, a space is created between the first end region 13 of the support component 12 and the connecting section 6 or the threaded rod 8, as well as a space between the second end region 14 of the support component 12 and the threaded rod 8'. In the first embodiment shown, a thermally insulating cavity filling 16 made of foam rubber is arranged in these spaces in order to ultimately further improve the thermal separation between the attachment part 10 and the wall 2.

In the first embodiment shown, the entire support component 12 is made in one piece from a glass fiber or carbon fiber reinforced plastic.

Fig.3 shows a front view of a second embodiment of the mounting system 1 according to the invention, wherein again a threaded rod 8' is arranged in the receptacle 11 of the thermal bridge separation module 7 of the mounting system 1. Basically, what was said above about the first embodiment applies to the second embodiment, unless otherwise stated, which is why repetitions are largely dispensed with.

In the view of the Fig.3 the thermal bridge separation module 7 is not visible as such, but apart from the threaded rod 8' only the second end region 14 of the support component 12 is visible, which is formed by a support component 18 made of pressure-resistant plastic, which in the second embodiment shown is a glass fiber or carbon fiber reinforced plastic. This choice of material ensures the pressure resistance on the one hand and the thermal insulation properties of the support component 12 on the other.

The support component 18 extends from the outside in the direction of the longitudinal axis 15 essentially as far as the threaded rod 8'. The central section 17 of the support component 12 adjoining the second end region 14 is indicated by a dashed circular line, which in the second embodiment shown is a hollow cylinder or a shaped tube made of an aluminum alloy. This material proves to be light, stable and cost-effective.

Fig.4 shows a schematic sectional view along the section line IV-IV of Fig.3 , where the arrows indicate the viewing direction and where the wall 2 provided with insulation material 3 (see the dotted lines in Fig.4 ) and the attachment part 10 screwed on by means of the nut 9 (see the dashed lines in Fig.4 ) are indicated. As can be seen from this illustration, the first end region 13 is also formed by a support component 18 made of pressure-resistant plastic, which in the second embodiment shown is a glass fiber or carbon fiber reinforced plastic. This choice of material in turn ensures the pressure resistance and on the other hand the thermal insulation properties of the support component 12 are ensured or further improved.

This means that in the second embodiment, only the first end region 13 and the second end region 14 of the support component 12 are made of a glass fiber or carbon fiber reinforced plastic, but not the middle section 17.

In the case of the second embodiment, the support component 12 with its end regions 13, 14 projects beyond the thermal bridge separation module 7 along the longitudinal axis 15. In this case, the support component 12 projects beyond the thermal bridge separation module 7 along the longitudinal axis 15 and both in the direction of the first end region 13 and in the direction of the second end region 14 by approximately 8% of its length L, or the end regions 13, 14 each have a length measured along the longitudinal axis 15 of approximately 8% of the total length L of the support component 12.

Fig.5 shows a schematic front view of a wall 2 provided with insulation material 3, on which an attachment 10 with a third embodiment of the mounting system 1 according to the invention is mounted. Basically, what was said above for the first embodiment applies to the third embodiment, unless otherwise stated, which is why repetitions are largely omitted. The attachment 10 is screwed with two nuts 9 to two threaded rods 8', which are arranged one below the other or one behind the other as seen in the direction of gravity 19. The threaded rods 8' are shown in the sectional view of the Fig.6 clearly and are shown in images 11 (in Fig.6 not specifically marked for reasons of space; cf. Fig.8 ) of thermal bridge separation modules 7 of two anchor elements 4. In accordance with the arrangement of the threaded rods 8', the two anchor elements 4 and the support components 12 surrounding them in sections are arranged one below the other or one behind the other as seen in the direction of gravity 9.

Fig.7 shows a front view of such an anchor element 4 together with the support component 4 and the screwed-in threaded rod 8' with a view of the second end 14 of the support component 12.

Fig.8 shows a sectional view along the section line VIII-VIII from Fig.7 , with the arrows indicating the direction of view. As can be seen from this illustration, the second end region 14 is made in one piece with the central section 17 of the support component 12 and, like the latter, is made of stainless steel, this material proving to be particularly stable.

In the third embodiment shown, only the first end region 13 of the support component 12 is made of a glass fiber or carbon fiber reinforced plastic by a support component 18, whereby pressure stability or strength and the desired thermal insulation properties of the support component 12 are ensured.

In the third embodiment, the respective thermal bridge separation module 7 is also arranged completely within the respective support component 12. The support component 12 projects beyond the thermal bridge separation module 7 only with its first end region 13 or only along the longitudinal axis 15 and in the direction of the first end region 13, namely with approximately 10% of the total length L of the support component 12. Along the longitudinal axis 15 and in the direction of the second end region 14, the thermal bridge separation module 7 ends flush with the second end region 14.

LIST OF REFERENCE SYMBOLS

1

Mounting system

2

Wall

3

Insulation material

4

Anchor element

5

Anchor section

6

Connecting section

7

Thermal bridge separation module

8, 8'

Threaded rod

9

Mother

10

Attachment

11

Recording

12

Support component

13

First end area of the support component

14

Second end area of the support component

15

Longitudinal axis

16

Cavity filling

17

Middle section

18

Support component made of pressure-resistant plastic

19

Gravity direction

L

Length of the support component

Claims (15)

Mounting system (1) for the thermally separated mounting of an attachment (10) on a wall (2) provided with insulating material (3), in particular on a wall (2) provided with a thermal insulation composite system, the mounting system (1) comprising at least one anchor element (4) with an anchor section (5) for anchoring in the wall (2) and an adjoining connecting section (6), the anchor element (4) further comprising a thermally insulating thermal bridge separation module (7) for at least section-wise arrangement in the insulation material (3), wherein the thermal bridge separation module (7) is connected to the connecting section (6) and has a receptacle (11) for a preferably screw-in fastening means (8', 9) for screwing the attachment part (10) tight, the mounting system (1) further comprising at least one thermally insulating support component (12) for arrangement between the wall (2) and the attachment (10) in order to enable direct or indirect support of a first end region (13) of the support component (12) on the wall (2) and direct or indirect support of the attachment (10) on a second end region (14) of the support component (12) opposite the first end region (13), wherein the respective support component (12) surrounds the respective anchor element (4) in sections. Mounting system (1) according to claim 1, characterized in that at least the first end region (13) and/or the second end region (14) of the support component (12), preferably the entire support component (12), is/are made of a plastic, in particular glass fiber or carbon fiber reinforced. Mounting system (1) according to one of claims 1 to 2, characterized in that only the first end region (13) and/or the second end region (14) of the support component (12) are/is made of a plastic, in particular glass fiber or carbon fiber reinforced. Mounting system (1) according to one of claims 1 to 3, characterized in that the respective support component (12) is made of an aluminum alloy or a stainless steel or a carbon fiber reinforced plastic in a central section (17) between the first end region (13) and the second end region (14). Mounting system (1) according to claim 4, characterized in that the first end region (13) or the second end region (14) of the support component (12) is made of the same material as the central section (17), and preferably in one piece with it. Mounting system (1) according to one of claims 1 to 5, characterized in that the respective thermal bridge separation module (7) is arranged completely within the respective support component (12). Mounting system (1) according to claim 6, characterized in that the support component (12) has a length (L) along a longitudinal axis (15) and projects beyond the thermal bridge separation module (7) in the direction of its first end region (13) and/or in the direction of its second end region (14). Mounting system (1) according to claim 7, characterized in that the support component (12) along the longitudinal axis (15) and in the direction of its first end region (13) and/or in the direction of its second end region (14) Thermal bridge separation module (7) projects beyond at least 5%, preferably at least 10%, of its length (L). Mounting system (1) according to one of claims 7 to 8, characterized in that a thermally insulating cavity filling (16), in particular made of foam rubber, is arranged in the respective region in which the support component (12) projects beyond the thermal bridge separation module (7) along the longitudinal axis (15). Mounting system (1) according to one of claims 1 to 9, characterized in that the respective thermal bridge separation module (7) has a cylindrical shape when viewed from the outside. Mounting system (1) according to one of claims 1 to 10, characterized in that the respective support component is formed, preferably completely, substantially tubular or sleeve-shaped, at least in a central section (17) between its first end region (13) and its second end region (14). Mounting system (1) according to one of claims 1 to 11, characterized in that the thermal bridge separation module (7) is made of a plastic, in particular glass fiber or carbon fiber reinforced. Arrangement comprising a mounting system (1) according to one of claims 1 to 12, a wall (2) provided with insulating material (3) and an attachment (10) which is mounted on the wall (2) with the mounting system (1), wherein the first end region (13) of the respective support component (12) is supported directly or indirectly on the wall (2) and wherein the attachment (10) is supported directly or indirectly on the second end region (14) of the respective support component (12). Method for mounting an attachment (10) on a wall (2) provided with insulating material (3), in particular on a wall (2) provided with a thermal insulation composite system, with a mounting system (1) according to one of claims 1 to 12, the method comprising the following steps: - anchoring the respective anchor section (5) of the at least one anchor element (4) in the wall (2) and arranging at least in sections the respective connecting section (6), the respective thermal bridge separation module (7) and the respective support component (12) in the insulation material (3), wherein the arrangement of the respective support component (12) is such that the first end region (13) of the respective support component (12) points towards the wall (2) and the second end region (14) points away from the wall (2); - Fastening the attachment (10) by screwing it to the respective thermal bridge separation module (7) by means of a fastening means (8', 9) such that the first end region (13) of the respective support component (12) is supported directly or indirectly on the wall (2) and that the attachment (10) is supported directly or indirectly on the second end region (14) of the respective support component (12). Method according to claim 14, characterized in that a plurality of anchor elements (4) and support components (12) surrounding them in sections are provided, wherein at least two anchor elements (4) and support components (12) surrounding them in sections are arranged one behind the other as seen in the direction of gravity (19).

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