EP0495150A1 - Façade construction - Google Patents

Abstract

In order to achieve, in a façade construction with frameless insulating glazings (14) fastened via supporting adhesive bonds (12) on façade profiles (10), an optimised heat insulation in the glass join, observing existing regulations with regard to the ventilation of glass rears, and an optimum vapour pressure equalisation and drainage in the region of the glass join, additional profiles (62) forming or having cavities are arranged in a bridging manner in the intermediate space between opposite seals of the insulating glazings (14). The additional profiles (62) at the same time keep the intermediate space free from any filling material, at least one end of the additional profiles (62) being open for drainage and/or vapour pressure equalisation. <IMAGE>

Description

The invention relates to a facade construction with frameless insulating glazing (structural glazing) attached to facade profiles via load-bearing bonds, as described in claim 1.

From DE-OS 35 40 385 a facade construction is known in which insulating glass panes are attached to the facade profiles by means of load-bearing gluing. An auxiliary profile projects into the space formed between two edges of the insulating glass panes, which has grooves for receiving a seal. A folding seal is inserted into this groove, which bridges part of the space between the edges of the insulating glass panes. The remaining free spaces lying between the auxiliary profile and the respective glass pane edges are sealed in that a silicone compound and a backfill material arranged behind it are provided on the weather side of these intermediate spaces. The entire space between the glass pane edges is thus sealed in the manner of a weather seal.
In this known construction it is disadvantageous that, despite the silicone seal, moisture penetrates into this area and can accumulate in particular in the backfill material. The edge of the glass pane can then be constantly surrounded by a moisture-containing area, which moisture cannot be removed due to the lack of ventilation. As a result, there is a risk that due to differences in vapor pressure, moisture will seal into the space due to the sealing of the insulating glass pane gets between the individual insulating glass panes, which is not desirable.

One way to prevent the formation of vapor pressure differences and permanent accumulation of moisture or water in the area of the glass pane edges of insulating glass panes is to omit the weather seal, i.e. leave the space between the edges of the insulating glass pane.

However, this measure creates the disadvantage of poor thermal insulation in the area of the glass rebate and at least occasionally heavy stress on the glass back due to rain. There is also an increased tendency to become dirty in the area of the open glass rebate.

It is an object of the invention to propose a facade construction with frameless insulating glazing fastened to facade profiles, in which, in conjunction with optimal thermal insulation in the glazing rebate and compliance with existing regulations regarding the ventilation of glass backs, both optimal vapor pressure compensation and drainage and optimal shielding against Water can penetrate into the double glazing.

The solution to this problem results from the features in claim 1.

The solution according to the invention advantageously leads to an essentially watertight intermediate space or glass rebate space, in which the insulating glass backs or insulating glass pane edges remain optimally ventilated.

The open end of the auxiliary profiles used between the insulating glazing ensures, on the one hand, that the glazing rebate area is adequately drained, since it cannot be prevented even with optimal sealing measures can moisture penetrate into the rebate space or the interior of the auxiliary profiles. In addition, the open end of the auxiliary profiles also ensures the necessary vapor pressure compensation.

Advantageously, a bent, in particular bent down, drain can be arranged at the open end of the auxiliary profiles, this drain preferably being a tube-like or tube-like drain. As a result, the moisture that may accumulate in the auxiliary profiles can be drained off from the auxiliary profiles in a predetermined manner without, for example, contaminating the outside of the facade construction. The downward curved drain also prevents back pressure inside the auxiliary profiles due to wind pressure, so that the auxiliary profiles are always drained.

Advantageously, additional openings for drainage and vapor pressure compensation can be provided in the auxiliary profiles. Although the open end of the auxiliary profiles is generally sufficient for the necessary drainage and / or the necessary vapor pressure compensation, additional openings can promote the vapor pressure compensation in the auxiliary profiles. If these additional openings are also used for drainage purposes, transverse seals can be provided below the additional openings, which promote a drainage from the additional openings as a kind of partition in the auxiliary profiles. Such transverse seals will then expediently be arranged just below the additional openings.

With regard to the additional openings, it is also advantageous if these processes, in particular in the form of curved plastic tubes with openings directed downwards, are attached or used. Such processes then again fulfill the purpose of a directed outflow of moisture from the auxiliary profiles and serve to prevent a dynamic pressure in the auxiliary profiles.

The auxiliary profiles are expediently designed to be resilient or flexible perpendicular to their profile axis, so that the auxiliary profiles can adapt to a displacement of the adjacent insulating glazing units without the auxiliary profiles moving away from their contact in the edges of the insulating glazing units and thus creating openings in which, for example Moisture can penetrate.

A weather seal arranged on the outside of the auxiliary profiles can be used for additional protection, in particular against the ingress of moisture and dirt, and for additional thermal insulation. Such a weather seal may also be desirable from an aesthetic point of view.

When using weather seals, it is advantageous if an interruption of adhesion, for example in the form of a polyethylene film, is provided between the auxiliary profiles and the respective weather seal. Such an interruption of detention prevents movements of the weather seal from being transferred to the auxiliary profiles and possibly moving the auxiliary profiles away from their predetermined position.

To produce an interruption of adhesion between the weather seal and the auxiliary profiles, it is also expedient to produce the auxiliary profiles from a plastic which does not adhere to silicone, which is generally used for weather seals. A polyethylene material is particularly suitable as the plastic material for the auxiliary profiles.

A preferred embodiment of the auxiliary profiles is that the auxiliary profiles are designed as a fir tree base. Such an auxiliary profile can be introduced in a simple manner and with a firm fit in the space between the insulating glazing.

Advantageously, the free ends of the flanges of the fir tree base are arranged adjacent to the edges of the panes of the insulating glazing and / or the supporting back of the insulating glazing, the web connecting the flanges being spaced apart from the edges of the panes or the supporting back. This arrangement of the auxiliary profile designed as a fir tree base creates a cavity in the areas of the supporting back of the insulating glazing, which is largely free of moisture due to the open end of the auxiliary profiles and also represents adequate ventilation. The flanges together with the cavities and a weather seal ensure adequate thermal insulation in the area of the glass rebate.

In another, preferred embodiment, the auxiliary profiles can also be formed in a tube-like form with a particularly thin wall. Such a hose is easy to insert into the space between the insulating glass and, together with a weather seal, seals this space securely against the ingress of moisture.

The hose wall preferably lies at least on the supporting back of the insulating glazing and thus ensures the desired tightness and thermal insulation in the glass rebate.

In order to prevent moisture from accumulating permanently between the supporting back of the insulating glazing and the hose wall, the hose-like auxiliary profiles point into the supporting back of the Insulating glazing facing hose wall areas in particular regularly arranged recesses. Moisture that nevertheless penetrates into this space between the supporting back and the hose wall can run off or evaporate through the recesses. The risk of moisture penetrating between the panes of the insulating glazing is also prevented in the event that moisture accumulating from the area mentioned diffuses between the panes of the insulating glazing due to vapor pressure differences.

In a further advantageous embodiment, the auxiliary profiles can have a zigzag-shaped cross section or a meandering shape in the form of a tape, auxiliary profiles designed in this way being glued to the rear sides or the end faces of the edge regions of the outer panes. Auxiliary profiles of this type keep the entire space between the insulating glazing clear and, with sufficient thermal insulation, ensure optimal ventilation and an undisturbed drainage of moisture that forms in this room.

The cross section of the auxiliary profiles can also be U-shaped, have U-legs that rest on the supporting back of the insulating glazing, which are formed with recesses at regular intervals and have a zig-zag or meandering U-shaped web.

Auxiliary profiles in the form of two mutually mirror-inverted U-profiles as box profiles, which rest with their leg surfaces on the supporting back of the insulating glazing, are preferably used.

The box profiles can advantageously each be surrounded by two profile strips which are U-shaped in cross section and which are mutually displaceable in the region of their mutually facing U-legs transversely to their longitudinal axis and have interruptions in their U-webs.

These other types of training of the auxiliary profiles each meet the requirements for optimal drainage and optimal vapor pressure compensation. All profiles can be manufactured inexpensively and are available by the meter and are easy to install.

Preferably, an inner seal can also be arranged between the mutually facing end faces of the inner panes of the insulating glazing, which requires additional thermal insulation and also prevents moisture from getting onto the room side of the insulating glazing.

A backfill material can also be arranged between this inner seal and the facade profiles, which is also advantageous in terms of thermal insulation and the prevention of moisture penetration.

A facade construction designed in this way is advantageously used for a sloping roof and / or inclined or horizontal facade surfaces. In the case of facade surfaces or roofs designed in this way, the liquid that forms in the cavities of the auxiliary profiles is always guaranteed to run off due to the force of gravity.

Fig. 1 bis 5

einen Schnitt durch Isolierverglasungen mit zwei Scheiben, wobei verschiedene Ausführungsformen der Hilfsprofile zwischen den Rändern der Isolierverglasungen angeordnet sind;

Fig. 6 bis 10

Quer- bzw. Längsschnitte verschiedener bevorzugter Formen der Hilfsprofile und

Fig. 11

eine bevorzugte Form eines Hilfsprofiles in einer perspektivischen Ansicht.

In the following, the invention is explained in more detail by way of example and schematically using preferred exemplary embodiments. It shows:

1 to 5

a section through double glazing with two panes, different embodiments of the auxiliary profiles are arranged between the edges of the double glazing;

6 to 10

Cross or longitudinal sections of various preferred forms of the auxiliary profiles and

Fig. 11

a preferred form of an auxiliary profile in a perspective view.

1 to 5 show facade profiles 10, to which frameless insulating glazing 14 are fastened via load-bearing bonds 12, while spacers 13 maintain the distance between the insulating glazing and the facade profiles 10.

Each insulating glazing 14 consists of an outer pane 16 and an inner pane 18. Between the panes 16 and 18 there are spacers 26, which are offset inwards from the edge regions 22 of the panes 16 and 18. Seals are arranged in the space between the spacers 26 and the edge regions of the panes 16 and 18 lying outside of them, which form the supporting back 30 of the insulating glazing. These load-bearing backs 30 of the insulating glazing generally run flush with the edges of the inner panes 18, which is why the insulating glazing 14, the outer panes 16 of which are larger than the inner panes 18, has a free edge - as shown in FIGS. 1 and 2 - trains. Furthermore, inner seals 56 are arranged between the opposing end faces of the inner disks 18, while the space between the inner seals 56, the inner ones bearing bonds 12 and the adjacent facade profiles 10, a backfill material 58 is arranged.

Since the above description largely corresponds for the embodiments shown in FIGS. 1 to 5, identical parts are denoted by identical reference numerals in these figures.

1, an auxiliary profile 20 with a meandering or zigzag-shaped cross section is arranged between the mutually opposite edge regions 22 of the outer panes 16 of the insulating glazing 14. As in the following FIGS. 2 to 5, the auxiliary profile 20 bridges the distance between the mutually opposite edge regions 22 of the adjacent outer panes 16 and keeps the space 24 between the opposite supporting back 30 of the insulating glazing 14 free, i.e. there is no material in the room, nor is there any filling material The auxiliary profile 20 is fastened by gluing on the back of the edge regions 22 of the outer panes 16, the free cross-sectional ends of the auxiliary profile 20 preferably reaching as close as possible to the supporting back 30.

According to FIG. 2, an auxiliary profile 21 is arranged bridging between the edge areas 22 of the outer disks 16, which is essentially U-shaped in cross-section, with a U-shaped depression extending inwards in the direction of the room side in the cross-section center located. In this case, the auxiliary profile 21 is attached by gluing to the end faces of the edge regions 22 of the outer disks 16.

In the embodiment according to FIG. 3 there is additionally a weather seal 28 on the outside of the auxiliary profile 32 provided, the shape of the auxiliary profile 32 being explained in more detail with reference to FIG. 7. In the case of the arrangement of a weather seal 28, either the auxiliary profile 32 consists of a plastic, to which silicone does not adhere, or an interruption of adhesion is provided between the auxiliary profile 32 and the weather seal 28, for example by a polyethylene film inserted between the auxiliary profile 32 and the weather seal 28 29 can be formed.

Fig. 4 shows a variant in which the auxiliary profile 64 has a tube-like shape and is inserted into the space between the insulating glazing in such a way that the tube wall rests on the supporting back 30 of the insulating glazing 14, the inner seal 56 and the weather seal 28. The auxiliary profile 64 has recesses 66 arranged in the hose wall regions facing the supporting back 30 of the insulating glazing 14. The recesses 66, which are in particular regularly arranged, prevent accumulation and possible remaining of moisture between the hose wall, the weather seal 28, the inner seal 56, and in particular the supporting back 30. Moisture collecting in this area can either enter the interior through the recesses 66 of the profile 64 or evaporate through the recess 66. 10, the auxiliary profile 64 is subsequently described in more detail.

Finally, FIG. 5 shows the arrangement of an auxiliary profile 62, which is designed as a fir tree base. The free ends of the flanges 68 of the auxiliary profile 62 lie on the one hand on the edges of the inner panes 18 of the insulating glazing 14 and on the other hand in the area between the supporting back 30 and the outer panes 16 of the insulating glazing 14. The web 70 connecting the flanges 68 is, viewed in cross section, spaced from the supporting back 30 by approximately the same amount and thus arranged approximately in the cross-sectional center of the auxiliary profile 62. Two cavities are thus formed between the load-bearing back 30 of the insulating glazing 14 and the web 70, which keep the load-bearing back 30 free of any filling material and ensure the desired ventilation and / or drainage. During installation, the auxiliary profile 62 designed as a fir tree base is pressed in from the weather side with the flange 68 cut into the cross-section for clamping, pointing towards the room side. As a result, the cut-in flange 68 is arranged on the room side after installation and ensures that the auxiliary profile 62 is adequately secured in position by its contact with the edges of the panes 18.

6 to 10 show different embodiments of auxiliary profiles in cross section and in longitudinal section.

According to FIG. 6, the auxiliary profile 72 has a circular or arched cross-section and can be arranged, in particular glued, on the supporting back 30 or the edges of the panes 16 with its free edges.

7, the auxiliary profile 32 is U-shaped in cross section. The U-legs 34 of the auxiliary profile 32 are provided with preferably regularly spaced recesses 36 in the longitudinal direction of the profile, while the U-web 38 has a zigzag or meandering cross-section. In the installed state, the auxiliary profile 32 bears with its U-legs 34 against the opposing supporting back 30 of the insulating glazing. The recesses 36 in turn prevent a possible one Accumulation of moisture between the U-legs 34 and the supporting back 30.

FIG. 8 shows an auxiliary profile 40, which is designed as a box profile in the form of two mutually mirror-inverted U-profiles, as shown in FIG. 7. The auxiliary profile 40 rests with its leg surfaces 42 in the installed state on the opposing supporting back 30 of the insulating glazing 14. Recesses 36 are also formed in the leg surfaces 42, as is also the case with the auxiliary profile 32 according to FIG. 7.

According to the embodiment shown in FIG. 9, the auxiliary profile 40 is designed as a box profile and is surrounded by two profile strips 44, 46 with a U-shaped cross section. The distances between the U-legs 48 and 50 of the profile strips 44, 46 are selected to be of different sizes, so that the profile strips 44, 46 can move relative to one another transversely to their longitudinal axis. In addition, the profile strips 44, 46 in turn have interruptions 52 in their U-webs 44, preferably at regular intervals.

FIG. 10 finally shows the tubular auxiliary profile 64, which is shown in FIG. 4 in the installed state. The recesses 66 are preferably arranged in opposing regions of the hose wall, in particular at regular intervals, as can also be seen in FIG. 11, which shows the tubular auxiliary profile 44 in a perspective, schematic side view.

REFERENCE SIGN LIST

10th

Facade profile

12

load-bearing adhesive

13

Spacers

14

Double glazing

16

outer disc

18th

inner disc

20th

Auxiliary profile

21

Auxiliary profile

22

Edge area

24th

Space

26

Spacers

28

Weather sealing

29

Polyethylene film

30th

move

32

Auxiliary profile

34

U-leg

36

Recess

38

U-bridge

40

Auxiliary profile

42

Thigh surface

44, 46

Profile bar

48, 50

U-leg

52

Interruption

54

U-bridge

56

inner sealing

58

Backfill material

60, 62, 64

Auxiliary profile

66

Recess

68

flange

70

web

72

Auxiliary profile

Claims (14)

Facade construction with spacers (26) and seals, in particular in the form of supporting backs (30), with frameless insulating glazing (14) attached to facade profiles (10) via load-bearing bonds (12), with auxiliary profiles (20; 21 ; 32; 40; 60; 62; 64; 72) bridge the gap (24) between opposite seals of the insulating glazing (14) and keep it free of any filling material and at least one end of the auxiliary profiles (20; 21; 32; 40; 60; 62 ; 64; 72) is open for drainage and / or vapor pressure compensation. Facade construction according to Claim 2, in which the open end of the auxiliary profiles (20; 21; 32; 40; 60; 62; 64; 72) opens into a downward-curved drain, in particular a tube-like drain. Facade construction according to Claim 1 and / or 2, in which additional openings for drainage and / or for vapor pressure compensation are provided in the auxiliary profiles (20; 21; 32; 40; 60; 62; 64; 72), preferably with drains in the additional openings , in particular in the form of curved plastic tubes with openings directed downwards. Facade construction according to one or more of Claims 1 to 3, in which the auxiliary profiles (20; 21; 32; 40; 60; 62; 64; 72) are designed to be resilient or flexible perpendicular to their longitudinal axes. Facade construction according to one or more of claims 1 to 4, in which a weather seal (28) is arranged on the outside of the auxiliary profiles (20; 21; 32; 40; 60; 62; 64; 72), in particular between the auxiliary profiles (20 ; 21; 32; 40; 60; 62; 64; 72) and the associated weather seal (28) an interruption of adhesion, in particular in the form of a polyethylene film (29), is provided. Facade construction according to Claim 5, in which the auxiliary profiles (20; 21; 32; 40; 60; 62; 64; 72) consist of a plastic on which silicone does not adhere. Facade construction according to one or more of Claims 1 to 6, in which the auxiliary profiles (62) are designed as a fir tree base, in particular the free ends of the flanges (68) of the fir tree base on the edges of the panes (16, 18) of the insulating glazing (14) and / or bear against the supporting back (30) of the insulating glazing (14) and the web (70) connecting the flanges (68) is spaced from the edges of the panes (16, 18) or the supporting back (30). Facade construction according to one or more of Claims 1 to 6, in which the auxiliary profiles (64) are designed in a tube-like shape with, in particular, a thin wall, the tube wall in particular resting at least on the supporting back (30) of the insulating glazing (14). Facade construction according to Claim 8, in which the tube-like auxiliary profiles (64) have, in particular, regularly arranged recesses (66) in the tube wall regions facing the load-bearing back (30) of the insulating glazing (14). Facade construction according to one or more of Claims 1 to 6, in which the auxiliary profiles (20; 21) are designed as a zigzag-shaped or meandering band in cross section, which is glued to the rear sides or the end faces of the edge regions (22) of the outer panes (16) . Facade construction according to one or more of Claims 1 to 6, in which the auxiliary profiles (32) are U-shaped in cross-section and have U-legs (34) which rest against the supporting back (30) of the insulating glazing (14) and which are arranged at regular intervals Distances are formed with recesses (36) and have a zigzag or meandering U-shaped web (38). Facade construction according to one or more of claims 1 to 6, in which the auxiliary profiles (40) are designed in the form of two mutually mirror-inverted U-profiles as box profiles, which have their leg surfaces (42) on the supporting back (30) of the insulating glazing (14 ) issue. Facade construction according to Claim 11 and / or 12, in which the auxiliary profiles (32; 40) are each surrounded by two profile strips (44, 46) which are U-shaped in cross section and which extend transversely in the region of their mutually facing U-legs (48, 50) are mutually displaceable with respect to their longitudinal axis and have interruptions (52) in their U-webs (54). Facade construction according to one or more of Claims 1 to 13, in which an inner seal (56) is arranged between the mutually facing end faces of the inner panes (18) of the insulating glazing (14).

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