AT405313B - Façade structure - Google Patents

Abstract

A façade structure made of panel-like façade elements 3 fastened on a load-bearing structure wall 2 has rails 7 which are arranged on the structure wall 2 and on which the façade elements 3 are fastened in each case by means of fastening elements 1, it being the case that the fastening elements 1 are provided at least in each case at the top and bottom ends of the façade elements 3, and it being the case that each fastening element 1 is formed by a load-bearing part 4, which projects approximately horizontally from the structure wall 2 and supports the façade element 3, a retaining part 5, which projects upwards from the load-bearing part 4, and a fixing part 8, which is bent upwards again beyond an upwardly projecting strip 6 of a rail 7, and the retaining part 5 and fixing part 8 are designed resiliently in relation to one another, and exert a clamping force on the rail strip 6, and at least one panel-retaining means 9 is provided on the load-bearing part 4, which projects from the structure wall 2. In order to anchor each façade element 3 on the structure wall 2 individually and independently of adjacent façade elements, it being possible to realise 100%-secure anchorage in straightforward and rapid installation, toothing 11, 12, 13, 14 is provided between the rail 7 and the fastening element 1, 1', 1". <IMAGE>

Description

AT 405 313 B

The invention relates to a facade construction made of plate-shaped facade elements fastened to a load-bearing building wall, the facade elements each being fastened to rails arranged on the building wall by means of fastening elements and the fastening elements being provided at least in each case on the upper and lower ends of the facade elements, each fastening element element is formed by a supporting part that projects approximately horizontally from the building wall, supports the facade element, a holding part protruding upward from the supporting part, and a fixing part bent downward again via an upwardly projecting rail strip of a rail, the holding part and fixing part being exerted on the rail strip by applying a clamping force are designed to be resilient against one another and furthermore at least one plate holder is provided on the support part projecting from the building wall, and a fastening element for use in a facade construction d of this kind.

The use of curtain-type, and in particular also thermally insulated facade constructions is becoming increasingly important because the majority of the buildings erected so far no longer meet the requirements of modern thermal insulation. Facade constructions should contribute to energy saving and C02 minimization. The variety of facade cladding products on the market ranges from thin fiber cement panels to thin ceramic panels to small brick panels and heavier natural stone panels.

Every facade element must be statically verifiable against the effects of wind pressure and wind suction as well as shocks and its position must be secured against rattling, lifting, sliding, tilting, falling, tipping and lowering etc. However, rigid connections should be avoided at the same time, because shape changes occurring on the facade, e.g. due to the effects of heat (sun), cold (ice) and moisture (rain), must be absorbed without damage.

Building regulations require that in the case of inaccessible, load-bearing and load-fixing connecting elements, permanent connections must be made. It is known (DIN 18516) to realize connecting elements which meet these requirements for exterior wall claddings which are formed by facade elements 25 by means of mortared anchors or by screw connections which are anchored to the building wall. Fasteners anchored to the building wall require boreholes to be placed very precisely on the building wall or a superstructure.

Screw connections represent a very secure connection to the building wall - they only need to be additionally secured against loosening, for example by welding or destroying the 30 thread end - but, in addition to the high material and manufacturing costs, require a high amount of work for assembly. Screwing tools such as wrenches etc. are to be used for the installation, which means that specialists are required both for drilling the holes for the screw connection and for actually installing the facade elements. It is critical if you forget to secure the screw connection during assembly, because once the facade element has been installed, it is usually no longer possible to check it later.

Facade constructions are known, for example, from AT-B - 367.495 and AT-B - 350.237. In these known facade constructions, the facade elements, which serve as plaster bases according to these documents, are joined together with ground bearing and butting surfaces and, according to AT-B -350.237, are attached to ropes or rods by means of clips and, via these, to rails, or according to 40 AT-B - 367.495 held on rails by means of hook-shaped fastening elements.

The facade elements are supported with their ground abutting surfaces so that the weight of the facade elements is absorbed by the lowest facade element. After assembling the facade elements, the facade itself is provided with a layer of plaster or mortar. The fasteners only serve to prevent the facade elements from tipping over from the building wall. 45 A facade construction of the type described in the opening paragraph is known from DE 32 37 294 A1. In this construction, the fastening element can be fastened to the rail by means of a snap connection, but there is no security against lateral sliding and twisting. This can cause the facade elements to loosen and fall.

The invention has for its object to provide a facade construction of the type described above, which is not plastered, in which the facade elements do not have to lie directly against each other, but in which each facade element for itself - and independently of neighboring facade elements - on the building wall is anchored and weight forces are not transferred from one facade element to the other, but can be absorbed by the building wall in an even distribution. It is essential that the facade elements are 100% securely anchored and that even high wind forces cannot cause a facade element to loosen, so that the above-mentioned building regulations are met.

It is a special object of the invention to be able to carry out an assembly of the facade elements by 'unskilled assistants, etc. without control of the same, i.e. the assembly should be 2

AT 405 313 B be simple, that even auxiliary workers can not do anything that could later have a detrimental effect when the building is used, in particular after installation the highest security against falling, rattling, etc. of the facade elements is given - and. between even without checking the individual attachment points.

This object is achieved in that a toothing is provided between the rail and the fastening element.

The supporting part projecting approximately horizontally from the wall of the building has a supporting function for the facade element arranged above, which sits on the supporting part with its full weight, and thus absorbs its weight. The facade element provided below the supporting part is supported by the supporting part, i.e. the plate holder arranged on it, against falling out of the facade, i.e. Secured from the facade.

The fastening element provided according to the invention for the facade construction is distinguished by a particularly simple assembly. It only needs to be struck with a hammer blow on the rail strip, to which it is fixed by the spring force prevailing between the holding part and the fixing part. After inserting or placing a facade element on the supporting part (the plate holder engaging in a corresponding recess in the facade element), a loosening of the fastening element upwards is excluded; the fastening element is loaded downwards by the facade element sitting on the supporting part and thus sits snugly on the rail strip.

The fixing part, which is bent downward around the rail strip, is preferably provided with at least one snap spring which engages behind a rail projection. As a result, the fastening element on the rail is positively secured against being pulled back after the snap spring has snapped in behind the rail projection. In the event of incorrect mounting of a fastening element on the rail, the fastening element must be destroyed if it is to be removed, for example by bending or unscrewing a part of the fastening element. Even this process can easily be carried out by unskilled assistants.

In order to also secure the fastening element on the rail strip against lateral displacement in order to maintain the uniformity of the butt joints, at least one projecting tooth or tooth space is advantageously provided on the fixing part bent downwards over the rail strip, which tooth or tooth has a tooth gap or a projecting tooth, which is provided on the rail interacts.

Here, at least one toothed strip is advantageously provided on the fixing part bent downward over the rail strip, which engages in a counter-toothed strip provided on the rail, and further expediently the fixing part bent downward over the rail strip is provided with a toothed strip at its lower end, parallel to the longitudinal extension of the rail Mistake.

A preferred embodiment is characterized in that the snap spring is directed upwards and is provided with a toothed strip at the upper end and that the opposing toothed strip is arranged on the rail projection.

The fastening element can be produced in a particularly simple manner if the snap spring is formed by punching from the fixing part which is reported downwards around the rail bar and springs against the upwardly projecting rail bar, the snap spring advantageously being formed in a window-like manner from the supporting part bent downward around the rail bar by punching . For particularly heavy and / or large facade elements, a support part is advantageously formed on the support part, which comes to rest on a wall side of the rail facing away from the building wall, the rail expediently having a support lug supporting the support part or having a support gripping around the support part open groove is provided.

A further preferred embodiment is characterized in that the supporting part protruding from the building wall is double-walled by folding, expediently one end of the folded part of the supporting part is in turn bent downwards to form a supporting part, and so on. approximately in alignment with the upward holding part, and comes to rest on a wall side of the rail.

The supporting part is preferably provided with a vertically oriented holding mandrel, which engages both in an upward and downward direction in a corresponding recess in a facade element, optionally with the interposition of an elastic perforated sleeve. For particularly high facade elements, further fastening elements can be provided between the lower and upper fastening elements, which hold the facade elements on the lower edges and upper edges, so that the facade elements are supported against swinging, etc. A fastening element which is suitable for this is characterized in that the supporting part is provided with a horizontally oriented holding mandrel which extends on both sides of the fastening element and in FIG

AT 405 313 B engages in each case a corresponding recess in a facade element, optionally with the interposition of an elastic perforated sleeve.

A further advantageous embodiment is characterized in that the fastening element on the supporting part protruding from the building wall has an upwardly curved plate holder and the attached facade element at the bottom and is additionally provided with a further plate holder for a facade element arranged below the attached facade element, which is attached to an in Cross-section of the U-shaped part is provided, the U-shaped part being fastened to the support part in a form-fitting manner, the part for the lower facade element advantageously being fastened to the support part with a spacer which defines a distance from the support part. A fastener of this type is also suitable for particularly large and / or heavy facade elements.

In order to avoid rattling of the facade elements, spring elements are advantageously provided between the facade element and the holding part and supporting part resting on the rail, an embodiment which is easy to manufacture being characterized in that the spring elements are fastened to the supporting part projecting from the building wall, preferably by means of a rivet .

The spring elements are preferably formed by corrugated spring plates.

However, the spring element can also be formed in one piece with the fastening element, etc. by punching a spring tab, preferably from the holding part and supporting part lying against the rail.

The support part is preferably provided at its front end facing away from the wall of the building with a downward and upward bent plug-in part forming the plate holders for engaging in a cavity of the facade elements.

The invention is explained in more detail below on the basis of several exemplary embodiments, with FIG. 1 illustrating a first embodiment of a fastening element for the facade construction according to the invention in oblique view. FIG. 2 shows a view in the direction of arrow II in FIG. 1 and FIG. 3 shows a side view in the direction of arrow III in FIG. 1. FIGS. 4 and 5 show how a fastening element is attached to a wall of a building attaching rail is attachable, etc. each in diagonal alignment. Fig. 6 shows a vertical section through a building wall with a facade construction according to the invention. FIG. 7 shows a further embodiment of a fastening element in a representation analogous to FIG. 1. 8 shows, analogously to FIGS. 4 and 5, the fastening element attached to a rail. Fig. 9 in a representation analogous to Fig. 6 shows a vertical section through a building wall. Another embodiment of a fastening element is also illustrated in an oblique view in FIG. 10. 11 shows a horizontal section through a building wall with a facade construction according to the invention.

Fig. 12 illustrates a further embodiment in oblique view, Fig. 13 is a view in the direction of arrow XIII of Fig. 12 and Fig. 14 is a view in the direction of arrow XIV of Fig. 13. Fig. 15 is again a vertical section through a building wall with a facade construction according to the invention again. 16 and 17 show an embodiment of a fastening element in an illustration analogous to FIGS. 2 and 3, FIG. 18 an embodiment analogous to FIG. 5.

According to the embodiment of the invention shown in FIGS. 1 to 6, a fastening element 1 has a supporting part 4 which projects approximately horizontally opposite a wall 2 on which facade elements 3 are mounted, a holding part 5 projecting upwards from the supporting part 4 and one over an upward part protruding rail bar 6 on a rail 7 arranged on the building wall 2 again downwardly bent fixing part 8.

At the end of the supporting part 4 facing away from the building wall 2, plate holders 9 are formed, etc. by an upward and a downward bent part, each forming a plate holder 9, of the fastening element 1 which is made in one piece from a sheet metal strip made of stainless steel (for example according to DIN 17440 material number 1.4571 or 1.4401). These upward and downward bent plate holders 9 each form a plug-in part for engagement into a cavity 10 of a facade element 3. The holding part 5 and the fixing part 8 of the fastening element 1 are designed to be resilient against one another, so that they fix the fastening element 1 on the rail 7 after the fastening element 1 has been placed on the rail strip 6. The fixing part 8 bent downward around the rail bar 6 is advantageously provided with at least one snap spring 12 which engages behind a rail projection 11. As a result, the fastening element 1 on the rail bar 6 is positively secured against pulling upwards.

A toothed strip 13 is provided on the fixing part 8 bent over the rail strip 6, etc. at the lower end of the fixing part 8, which, according to FIG. 5, engages in a counter-toothed strip 14 provided on the rail 7. The lower end of the fixing part 8 is bent slightly outwards for the purpose of easier attachment to the rail strip 6, whereby the snap spring 12 punched out window-like from the fixing part 8 is directed against the hat part 5 and after the attachment of the fastening part 4

AT 405 313 B element 1 engages behind the rail projection 11 on the rail bar 6. After mounting the fastening element 1 on the rail bar 6, the holding part 5 is supported on the front, away from the building wall 2, vertically oriented wall side 15 of the rail 7.

As can be seen from FIG. 6, the rail 7, which is mounted horizontally on the building wall 2, is rigidly attached to a mounting rail 16 mounted vertically on the building wall 2. The mounting rail 16 is in turn attached to the building wall 2 by means of mounting brackets 17 (according to DIN 4113) screwed to the building wall 2 or mounting anchors. The relatively large height of the mounting rail 16 enables the installation of thermal insulation material 18 on the building wall 2 with the provision of rear ventilation, i.e. a cavity 19 between the facade elements 3 and the thermal insulation material 18th

The fastening element 1 causes the facade element 3 arranged below the fastening element 1 to be held against the building wall, i.e. it secures it against tipping over by the corresponding plug-in part 9 engaging in the cavity 10 of the facade element 3. The plug-in part 9 is formed on the support part 4 so that the facade element 3 is pressed against the rail 7 by a certain spring force which is exerted by the plug-in part 9 on the facade element 3. The plug parts 9 are bent slightly outwards at their ends for easier insertion of a facade element.

The fastening element 1 takes over - and this is essential - a supporting function for the upper, i.e. on the supporting part 4 of the fastening element 1 placed facade element 3, the upper facade element 3 maintaining a certain distance from the lower facade element. The weight of the facade elements 3 is thus introduced via the support part 4 directly via the rail 7 into the vertical support rail 16 and further into the building wall 2.

In Fig. 4, a rail 7 'made of stainless steel sheet is illustrated. The rail projection 11 is here by folding the upper longitudinal region, i.e. the rail bar 6 of the rail 7 'is formed. In this embodiment, the counter-toothed strip 14, which can be easily punched or otherwise produced before folding, is located directly on the rail projection 6. Therefore, the toothed strip 13 of the fastening element 1 is provided at the upper end of the snap spring 12. If both tooth strips 13, i.e. provided at the end of the snap spring 12 and at the end of the fixing part 8, the fastening element 1 can be used for different types of rails 7, 7 '.

According to the variant shown in FIGS. 5 and 6, the rail is a pressed aluminum profile rail, which is produced, for example, in anodized or blank quality. In this variant, the counter-toothed strip 14 is located on the top of the C-shaped open box profile of the rail 7.

Through the interaction of the snap spring 12 with the engaging rail projection 11 and the toothed strip 13 with the opposing toothed strip 14, a multiple fastening function is achieved, namely once by an absolute fixation of the fastening element 1 in the horizontal direction along the rail 7 and further by an essential, supporting function or Influencing the holding part 5. The tensile load of the holding part 5 is passed through the material cross section of the fastening element 1 to the snap spring 12, so that the support of the snap spring 12 is automatically and additionally intensified, ie the higher the load load increases, the stronger the engagement function of the snap spring 12 is also used. High force absorption is possible through the use of stainless steel.

Subsequent loosening of the fastening element 1 - likewise dismantling - is not possible without destroying the fastening element 1.

The holding part 5 and the fixing part 8 of the fastening element 1 together have the great advantage that a very quick and easy assembly (practically without special auxiliary tools - a rubber hammer is sufficient) is ensured with the least possible effort, both in terms of material consumption and working time. Auxiliary staff can therefore be used to assemble facade elements 3.

According to the embodiment shown in FIGS. 7 to 9, the support part 4 is double-walled by folding, the folded-back part 20 being provided with a vertically downward end part 21, which functions as a support part. This support part 21 is provided in alignment with the holding part 5 and, like this, also comes to rest on the wall side 15 of the rail 7 facing away from the building wall 2. The rail 7 is provided on this wall side 15 with an upwardly open groove 22, into which the support part 21 engages when the fastening element 1 is placed in the rail 7. A vertically oriented holding dome 23 is provided on the supporting part 4, which extends both upwards and downwards and engages in a corresponding recess 24 of a facade element 3, etc. preferably with the interposition of an elastic perforated sleeve inserted into the recess 24.

In order to be able to hold a facade element 3, which extends over a greater height, also at a height between its lower and upper ends, a fastening element 1 'designed according to FIGS. 10 and 11 is expediently provided. This is analogous to the fastening 5 shown in FIG

Claims (22)

AT 405 313 B element formed, with the difference that a holding mandrel 25 is even more in the horizontal direction, etc. The fastening element 1 protrudes on both sides. The holding mandrel 25 is fastened to the supporting part 4 by folding the sheet forming the supporting part 4 around the holding mandrel 25. As can be seen from FIG. 11, the holding mandrel 25, with one part projecting laterally from the supporting part 4, projects into a corresponding recess 26 of a facade element 3, an elastic perforated sleeve also preferably being interposed here. For better load transfer, the supporting part 4 is used, for which purpose slots 27 corresponding to the supporting part 4 are provided in the facade elements 3, so that the facade elements 3 are supported not only on the holding mandrels 25 alone, but to a large extent directly on the supporting part 4. The rail 7 shown in FIGS. 8 and 9 has a particularly stable double box profile in cross section; It is made of a pressed and heat-hardened aluminum alloy (AI Mg Si 0.5 - F22 according to DIN 18516) and is ideally suited for heavy, large facade elements 3. The variant of a fastening element 1 &quot; has a design of the lower plate holder 9 as a separate part 28, which is connected or welded to the supporting part 4 of the fastening element by means of a rivet 29. The lower part 28 is U-shaped in profile, with a vertically downwardly extending support part 21 in alignment with the holding part 5 of the fastening element 1 &quot; is arranged. Both the support part 21 and the holding part 5 are provided on the side facing away from the building wall 2, on which the facade element 3 rests, with spring elements 30, preferably with the rivet with which the U-shaped part 28 is fastened to the supporting part 4 , on the fastener 1 &quot; are attached. The spring elements 30 are formed by corrugated spring plates, the strength of the spring plates or their spring force depending on the facade elements 3 that are to be held or the wind pressure etc. However, the spring elements 30 can also be formed by punching out of the holding part 5 and from the supporting part 21 and then bending out the punched parts out of the plane of the holding part 5 and the supporting part 21 analogously to the snap spring 12. As can be seen from Fig. 15, the facade elements 3 are completely embraced by the plate holder 9, so that they are visible from the outside. The embodiment shown in FIGS. 16 and 17 shows a fastening element 1 similar to that as illustrated in FIGS. 1 to 3, with the difference that the sheet metal part of the fastening element 1 adjoining the supporting part 4 is split into three mutually parallel parts is, two parts form the plate holder 9 and the third, preferably middle part, is bent back as a supporting part 21 so far that it comes to rest on the wall side 15 of the rail 7 facing away from the building wall 2. A particularly good load transfer is given when the support part 21 is supported on a strip-shaped support lug 31 which extends along the rail 7 on its wall side 15 (cf. FIG. 18). All embodiments with support part 21 allow the absorption of large loads. They are therefore particularly suitable for particularly heavy facade elements. In addition to the quick assembly, the versatile use of a fastener system of the same basic configuration with regard to the main features of the plate holder 9 - support part 4 - holding part 5 and fixing part 8 is of enormous economic advantage for the facade builder Facade elements (3), the facade elements (3) each being fastened to rails (7, 7 ') arranged on the building wall (2) by means of fastening elements (1, 1', 1 ') and the fastening elements (1, 1', 1 '') are provided at least in each case on the upper and lower ends of the facade elements (3), each fastening element (1, 1 ', 1 &quot;) from a supporting part which projects approximately horizontally from the building wall (2) and supports the facade element (3) (4), a holding part (5) projecting upward from the supporting part (4) and one over an upwardly projecting rail strip (6) e in the rail (7) downward bent fixing part (8) is formed, the holding part (5) and fixing part (8) are designed to be resilient against one another by exerting a clamping force on the rail strip (6) and further on the wall of the building (2) projecting supporting part (4) at least one plate holder (9) is provided, characterized in that a toothing (11 to 14) is provided between the rail (7) and the fastening element (1, 1 ', 1 "). 2. Facade construction according to claim 1, characterized in that the fixing part (8) bent downwards around the rail strip (6) is provided with at least one snap-in spring (12) engaging behind a rail projection (11). 6 AT 405 313 B 3. Facade construction according to claim 1 or 2, characterized in that at least one projecting tooth or a tooth gap is provided on the fixing part (8) bent downwards over the rail strip (6), the tooth or teeth having a tooth gap or a projecting tooth or which is provided on the rail (7, 7 ') acts together. 4. Facade construction according to claim 3, characterized in that at least one toothed strip (13) is provided on the fixing part (8) bent downwards over the rail strip (6) and engages in a counter toothed strip (14) provided on the rail (7). 5. Facade construction according to claim 4, characterized in that the fixing part (8) bent downwards over the rail strip (6) is provided with a toothed strip (13) at its lower end parallel to the longitudinal extension of the rail (7). 6. Facade construction according to one or more of claims 2 to 5, characterized in that the snap spring (12) is directed upwards and is provided at the upper end with a toothed strip (13) and that the opposing toothed strip (14) on the rail projection (11) is arranged (Fig. 4). 7. Facade construction according to one or more of claims 2 to 6, characterized in that the snap spring (12) from the around the rail bar (6) downward fixing part (8) is formed by punching and against the upwardly projecting rail bar (6) springs. 8. facade construction according to claim 7, characterized in that the snap spring (12) is window-like from the around the rail strip (6) bent down fixing part (8) is formed by stamping. 9. facade construction according to one or more of claims 1 to 8, characterized in that on the support part (4) a support part (21) is integrally formed on a wall side (15) facing away from the building wall (2) of the rail (7) comes to the plant (Fig. 7, 9, 16, 17). 10. Facade construction according to claim 9, characterized in that the rail (7) with a supporting part (21) supporting supporting lug (31) or with a supporting part (21) encompassing upwardly open groove (22) is provided (Fig. 8, 9; 18). 11. Facade construction according to one or more of claims 1 to 10, characterized in that the supporting part (4) projecting from the building wall (2) is double-walled by folding (Fig. 7 to 11). 12. Facade construction according to claim 11, characterized in that one end of the folded part of the supporting part (4) is in turn a support part (21) bent downwards, etc. approximately in alignment with the upward holding part (5) and comes to rest on a wall side (15) of the rail (7) (FIGS. 7 to 11). 13. Facade construction according to claim 11 or 12, characterized in that the supporting part (4) is provided with a vertically oriented holding mandrel (23) which is directed both upwards and downwards in a corresponding recess (24) of a facade element (3) engages, if necessary with the interposition of an elastic perforated sleeve (Fig. 7 to 9). 14. Facade construction according to claim 11 or 12, characterized in that the supporting part (4) is provided with a horizontally oriented retaining dome (25) which extends on both sides of the fastening element (1) and in each case a corresponding recess (26) of a facade element ( 3) engages, possibly with the interposition of an elastic perforated sleeve (Fig. 10,11). 15. Facade construction according to one or more of claims 1 to 14, characterized in that the fastening element (1 &quot;) on the support part (4) projecting from the wall of the building has an upwardly bent panel and the attached facade element (3) comprising bottom bracket (9) and is additionally provided with a further plate holder (9) for a facade element (3) arranged below the attached facade element (3), which is provided on a part (28) with a U-shaped cross section, the U-shaped part (28) on the support part (4) is positively attached (Fig. 12, 13, 14, 15). 7 AT 405 313 B 16. Facade construction according to claim 15, characterized in that the part (28) for the lower facade element (3) with a distance from the support part (4) determining spacer on the support part (4) is fixed (Fig. 12, 13, 14, 15). 17. Facade construction according to claim 15 or 16, characterized in that spring elements (30)) are provided between the facade element (3) and the support part (5) and support part (21) resting on the rail (7) (FIGS. 12, 13 , 14, 15). 18. Facade construction according to claim 17, characterized in that the spring elements (30) on the structural wall (2) projecting support part (4) are attached, preferably by means of a rivet (29) (Fig. 12, 13, 14, 15). 19. Facade construction according to claim 17 or 18, characterized in that the spring elements (30) are formed by corrugated spring plates (Fig. 12, 13, 14, 15). 20. Facade construction according to one or more of claims 16 to 18, characterized in that the spring elements (30) are integrally formed with the fastening element (1) or part (28), etc. by punching a spring tab, preferably from the holding part (5) and supporting part (21) resting on the rail. 21. Facade construction according to one or more of claims 1 to 8, characterized in that the support part (4) at its front end facing away from the building wall, with a downward and an upward bent, the plate holder (9) forming plug part for engagement in a cavity (10) of the facade elements (3) is provided. 22. Fastening element (1, 1 ', 1 ”) for use in a facade construction according to one or more of claims 1 to 21. Including 3 sheets of drawings 8