EP0518222A1 - Framework consisting of mullion and transom profiles for a wall or roof construction made up of panel elements - Google Patents

Abstract

Framework (1) consisting of mullion and transom profiles for a wall or roof construction with framework interspaces (25) made up of panel elements (24). The mullion profiles (3) consist of a plurality of part profiles (7) and have bevelled profile joints (8) so that two adjacent part profiles (7) abut in the manner of legs of an angle beta different from 180 DEG . In the longitudinal direction (2), the mullion profiles (3) have a polygonal shape. At least one drainage channel (18) is introduced into the mullion profiles (3). The drainage channel (18) is lined by a water guide profile (31) which bridges the profile joints (8) and which is effective over the entire mullion profile length as a water guide channel. Sealing strips (22, 23) on the mullion profile, which are independent of the water guide profile (31), serve to fasten and seal the panel elements (24). <IMAGE>

Description

The invention relates to a mullion and transom profile frame for a wall or roof construction with the features mentioned in the preamble of claim 1. The post profiles of the profile scaffold bear the transom profiles that run transversely or diagonally to them, the post profiles being referred to as rafters in roof constructions. If post and transom profiles are mentioned in the following, the statements apply equally to rafters and transom profiles of roof structures.

Out
EP-A-399 778
is a post and transom profile frame for a wall construction known with a sealing strip, which seals surface elements against post profiles as well as sealing against a drainage channel in the post profile. The disadvantage here is the complex production of the sealing strip. A further disadvantage is that the sealing strip must be cut out separately in the joint area, in particular of transom profiles that are clipped into the post profiles, that is to say an individual seal must be created in each case. Such individual seals require very careful and individual assembly and involve the risk of leaks due to thermal expansion of the mullion and transom structure over the operating time of the wall construction.

Out
EP-A-414 105
a device for drainage on sloping and roof glazing is known. This known device has two different sealing elements, each of which can be snapped onto a post and a transom profile. These sealing elements seal the surface elements from the profiles and are also effective as water guiding elements on the mullion profile and the Reigel profile. The sealing element that can be snapped onto the post profile has a main drainage channel divided into two by a screw channel for drainage of the mullion profile and for partial drainage of the transom profile. It is also equipped with two other hollow chambers. Drainage channels from the sealing elements of the transom profiles open into these hollow chambers. In the joint areas of the mullion and transom profiles, the gutters penetrate the side walls of the hollow chambers. In the joint areas, the molded sealing lips must also be removed on the sealing element of the mullion profile in order to be able to mount the transom profiles. For this purpose, the hollow chamber side walls and the sealing lips have predetermined breaking points to make assembly easier.

A disadvantage here is the fact that parts of the sealing element must be removed in the joint areas. Another disadvantage is the complex design of the sealing element with two main drainage channels on the one hand and two secondary drainage channels designed as a hollow chamber on the other. The complex and asymmetrical design of the sealing elements for the transom profiles also increases the cost of the device. The assembly of the structurally complex sealing elements is complicated in the joint areas and the 2-stage drainage of the locking profiles is so complicated in structure that it is a source of error when assembling the device. In addition, errors can occur during the complicated assembly of the device, which can severely restrict the functionality of the drainage system.

The invention has for its object to simplify and improve the drainage system within a mullion and transom profile frame for a generic wall or roof construction with the simultaneous possibility of being able to realize any joint area angle and profile joint angle. This object is achieved by the combination of features of claim 1.

A water guide profile is introduced into the drainage channel of the post profile composed of several partial profiles. This water guide profile can be composed of several partial profile pieces. The butt joints between two adjoining, adjacent partial profiles are each bridged by a partial profile piece, so that none Water can penetrate into the butt joints. The water guide profile is thus effective as a water channel over the entire length of the post profile.

It is advantageous that a post profile with any number of different kinks can be produced from the partial profiles. The water guide profile according to the invention can be used independently of the kinks selected in the post profile. It is also advantageous that the post profile can be constructed modularly from identical partial profiles, the kinks being realized in that the profile joints of the partial profiles are chamfered.

Compared to the devices known from the prior art, the post profiles according to the invention have separate water guide profiles and sealing strips. The water routing profile is used only to drain the post profile. The sealing strips, which are separate from the water guide profile, are attached directly to the post profile and are used to fix the surface elements that fill out the post and transom profile frame. An essential idea of the invention is this combination of the water guide profile for the drainage channel with the separate sealing strips for fixing the surface elements on the post profiles. The advantage here is that only the sealing strip has to be cut in the joint areas between mullion and transom profiles. In contrast, the water routing profile remains completely unaffected by the transom assembly on the post profiles and thus extends throughout the entire length of the post profile.

The sealing strips designed as line or surface seals are cut out in the area of the latching points of the transom profiles. The sealing strips are consequently arranged between two adjacent joint areas of mullion and transom profiles. Due to their simple geometry, the sealing strips can be cut easily and precisely and can also be replaced regardless of the water routing profile. Elaborate predetermined breaking points need not be provided on the sealing strips for this.

However, the effectiveness of the cascade-like water drainage system is not impaired by cutting out the sealing strips. According to the invention, the sealing level and the water management level on the post profile are completely separate from one another. While the water flow runs inside the post profile, the seal is made against the front the post profiles set surface elements by means of the sealing strips outside the post profile.

In its one-piece embodiment according to claim 2, the water guide profile can therefore be introduced by the meter from the piece into the drainage channels of the fully assembled post profiles, so it does not need to be pre-cut. This leads to good assemblability and a high degree of material utilization in the inventive water management profile. In principle, any profile lengths can also be bridged with the water guide profile according to the invention. In addition, the water guide profile material can be easily assembled on rolls. The rolls can easily be transported to the construction site and processed there directly as piece goods. Accordingly, the water guide profile can extend over the entire length of the post profile. The water guide profile can be easily pulled into the drainage channel of the post profile in one piece. There are also no butt joints in the drainage channel, which greatly improves the sealing effect of the water guide profile.

The complete lining of the post profile drainage channel by the water guide profile according to claim 3 also favors the sealing effect of the water guide profile with respect to the drainage channel.

The development of the scaffolding according to the invention according to claims 5 to 8 enables the creation of a cascade-like water guide system in the mullion and transom profile construction. The installation of the sealing strips on the groove webs is particularly simple. The double function of the side limbs which laterally delimit the base profile body is advantageous as the side walls of the drainage channel on the one hand and as a fastening surface for the sealing strips forming the sealing plane on the other hand. Drainage channels are also in the transom profiles. The water in these transom profile channels always flows into the drainage channel of the nearest post profile. Due to the different height levels of the drainage channel of the transom profile on one side and the drainage channel of the post profile on the other side, the water falls to a certain extent from the drainage channel of the transom profile into the drainage channel of the Post profile. The drainage channels of the mullion profiles are effectively the main drainage channels, while the drainage channels of the transom profiles are effectively the secondary drainage channels. In particular, the construction according to the invention prevents both the penetration of water into the joint area between the post profiles and the transom profiles and the penetration of the water into the butt joints between the partial profiles forming the post profiles. The drainage level of the transom profiles is therefore above or outside the drainage level of the post profiles. The additional attachment of the support seal to the transom profiles in turn serves to improve the sealing effect of the overall construction.

The division in two of the water guide profile proposed in claims 9 and 10 is particularly simple and saves material and costs.

The one-piece, preferred embodiment of the water guide profile according to the invention according to claims 12 and 13 is very easy to assemble because the water guide profile designed according to the internal geometry of the drainage channel centers itself on the screw channel protruding from the drainage channel in the manner of a central web. The fastening screws to be inserted into the screw channel can easily penetrate the water guide profile due to its rubber-like material. It is advantageous here that holes for fastening screws are only formed in the water guide profile where these are also needed, and thus the sealing effect of the water guide profile is not impaired by unnecessary, unused holes. Due to its high inherent elasticity, the water routing profile adapts to any internal geometry of the drainage channel in the post profile. Due to the one-piece design and the high degree of inherent elasticity, this adjustment takes place almost automatically and is fully retained over the entire operating time of the scaffold.

Claims 13 and 14 relate to advantageous measures for fixing the surface elements on the mullion and transom profile frame.

According to claim 15, it is particularly advantageous to use the inventive framework to create so-called polygon roofs, because all the advantages of the invention are used particularly well.

Fig. 1

eine Draufsicht auf das Pfosten- und Riegelprofilgerüst mit rechtwinklig zueinander angeordneten Pfosten- und Riegelprofilen,

Fig. 2

eine Draufsicht auf das Pfosten- und Riegelprofilgerüst mit in unterschiedlichen Winkeln zueinander angeordneten Pfosten- und Riegelprofilen,

Fig. 3

die Seitenansicht eines zusammengesetzten Pfostenprofils gemäß Pfeil III in Fig. 1 mit einer konkaven Krümmungslinie,

Fig. 4

die Seitenansicht eines zusammengesetzten Pfostenprofils gemäß Pfeil III in Fig. 1 mit einer Polygon-Krümmungslinie mit mehrern Wendepunkten,

Fig. 5

die Seitenansicht eines zusammengesetzten Pfostenprofils gemäß Pfeil III in Fig. 1 mit einer konvexen Krümmungslinie,

Fig. 6

die geschnittene Darstellung des Pfostenprofils gemäß Linie VI-VI in Fig. 3,4,5.

Using the exemplary embodiments shown in the drawings, the invention is described with further features essential to the invention. Show it:

Fig. 1

a plan view of the mullion and transom profile frame with mullion and transom profiles arranged at right angles to one another,

Fig. 2

a plan view of the mullion and transom profile frame with mullion and transom profiles arranged at different angles to one another,

Fig. 3

the side view of a composite post profile according to arrow III in Fig. 1 with a concave line of curvature,

Fig. 4

the side view of a composite post profile according to arrow III in Fig. 1 with a polygon curvature with several turning points,

Fig. 5

the side view of a composite post profile according to arrow III in Fig. 1 with a convex line of curvature,

Fig. 6

the sectional view of the post profile according to line VI-VI in Fig. 3,4,5.

Fig. 1 shows the top view of the mullion and transom profile frame 1 with the mullion profiles 3 running in the longitudinal direction 2 and the transom profiles 5 running perpendicular to the mullion profiles 3 the post profiles 3 latched. The mullion and transom profile frame 1 shown in FIG. 1 can be both a top view of a roof structure, the mullion profiles 3 in a roof structure being referred to as rafter profiles, and also a side view of a wall structure consisting of vertically extending mullion profiles 3 and horizontal transom profiles 5.

2 also shows a mullion and transom profile frame 1, the mullion profiles 3 not running exactly in the longitudinal direction 2 and the transom profiles 5 not running exactly in the transverse direction 4. The mullion and transom profile frame according to the invention generally enables any conceivable course of the mullion profiles 3 and transom profiles 5 in the plane spanned by the longitudinal direction 2 and the transverse direction 4 (= plane of the drawing in FIG. 2). 2 it is also possible that the post profiles 3 and the transom profiles 5 do not always collide exactly at right angles in their joint areas 6. Rather, all impact range angles α between 0 and 180 ° are conceivable. The angle legs of the joint area angle α each form a post profile 3 and a transom profile 5, the joint area 6 connecting these two profiles 3, 5 forming the apex of the joint area angle α. In the mullion and transom profile scaffold in Fig. 1, the joint area angle between all mullion profiles 3 and transom profiles 5 is always 90 ° in the plane spanned by the longitudinal direction 2 and transverse direction 4 (= drawing plane Fig. 1).

3 shows the post profile 3 composed of several partial profiles 7. The partial profiles 7 lie against one another with their beveled profile joints 8. In the direction of curvature 9 running at right angles to the transverse direction 4 and to the longitudinal direction 2, the water guide profile 10 running continuously in the longitudinal direction 2 is indicated as indicated above the partial profiles 7. The illustration in FIG. 3 shows a roof structure, the water guide profile 10 forming the top of the roof, that is to say FIG. 3 is a concave curved post profile 3.

FIG. 4 also shows a post profile 3 shown made up of several partial profiles 7. According to the illustration in FIG. 4, the partial profiles 7 form a polygon with a multiply changing curvature. Two adjacent sub-profiles 7 each form the legs of the profile joint angle β, the apex of which lies in the profile joint 8. The profile abutment angle β extends in the plane spanned by the longitudinal direction 2 and the curvature direction 9. Fig. 4 also shows that two adjacent partial profiles 7 with inclined profile joints 8 can form a profile joint angle β 'of 180 °. The water guide profile 10 according to the invention is consequently also suitable for bridging profile joints 8 between two partial profiles 7 forming a profile joint angle β 'of 180 °.

Fig. 5 shows the post profile 3 of a convex roof structure. With this convex roof construction, the profile joint angles are always β <180 °. In contrast, the profile butt angle β according to FIG. 1 applies: β> 180 °. From the representations of FIGS. 3, 4 and 5 it is particularly clear that 1 polygon courses with any profile joint angles β can be realized as item profile 3 with the post and transom profile framework according to the invention.

FIG. 6 shows the rectangular basic cross section of the basic profile body 11 of the partial profile 7 lying in the plane spanned by the transverse direction 4 and the curvature direction 9, with - as stated - several composite partial profiles 7 forming the post profile 3. In the post profile 3 4 transverse profiles 5 are latched. These locking profiles 5 have a different profile height 12 in the direction of curvature 9.

The basic profile body 11 has a room side 13 and a facade side 14 facing away from the room side 13 in the direction of curvature 9. The room side 13 and the facade side 14 delimit the basic profile body 11 in the curvature direction 9. In the curvature direction 9, the central web 15 extending in the longitudinal direction 2 protrudes from the post profile 3 from the facade side 14. The screw channel 16 is introduced into the central web 15 for receiving the fastening screw 17. In the transverse direction 4 next to the central web 15, the drainage channels 18 are arranged. The drainage channels 18 run in the longitudinal direction 2 of the post profile. In the transverse direction 4, the drainage channels 18 are delimited by the side legs 19 which protrude from the facade side 14 of the post profile 3 in the direction of curvature 9. The facade-side end faces of the side legs 19 are angled at right angles to one another in such a way that they form the transverse webs 4 groove webs 20. The drainage channels 18 are consequently each delimited by a groove web 20, a side leg 19 and a section of the facade side 14.

Facing away from the drainage channels 18, the locking profiles 5 with their latching areas 21 rest on the groove webs 20. The sealing strips 22 cut out in the latching areas 21 of the locking profiles 5 are shown in dashed lines in FIG. 6 on. On their sides facing away from the mullion profile in the direction of curvature 9, the locking profiles 5 carry the support seals 23 for sealing the surface elements 24 adjoining in the direction of curvature 9 against the locking profiles 5. The support seals 23 are sandwiched between the locking profiles 5 and the surface elements 24. The surface elements 24 are used on the mullion and transom profile frame 1 to fill in the spaces 25 between the mullion profiles 3 and the transom profiles 5. To hold the surface elements 24 against the support seal 23 in Curvature direction 9 facing away from the surface elements 24, the fastening profile 26 pre-screwed by means of the fastening screw 17. The fastening profile 26 presses, under the force of the fastening screw 17, the fastening seal 27 lying between the fastening profile 26 and the surface element 24 against the side of the surface elements 24 facing away from the support seal 23 in the direction of curvature 9.

To make it difficult to disassemble and optically cover the fastening screw 17 in the final assembly state, the cover profile 28 is snapped onto the rear side 29 of the fastening profile 26 facing away from the surface elements 24. For this purpose, the cover profile 28 is provided with two spring hooks 30. In the snap-on position, the two spring hooks 30 engage behind correspondingly designed rear grip parts on the fastening profile 26.

The drainage channels 18 are essentially lined by the one-piece water guide profile 31. The water guide profile 31 is shaped in a W-shape such that its profile side legs 32 abut the side legs 19 of the post profiles 3. The central area of the water guide profile 31 fits snugly against the central web 15 and covers the central web 15 in such a way that the facade side 14 of the post profile 3 is completely covered by the water guide profile 31 against the drainage channels 18. In addition, the water guide profile 31 also completely covers the central web 15 against the drainage channels 18. The water guiding profile 31 also nestles into the screw-in funnel 33 of the screw channel 16 and is pierced by the fastening screw 17 at the screw-in point.

The device works as follows:
The water running out of the drainage channels of the transom profiles 5, which run in the transverse direction 4 and are not shown in the drawings, falls into the drainage channels 18 of the mullion profiles 3 due to the force of gravity. The drainage channels 18 are completely lined by the water guide profile 31 bridging the profile joints 8. The water guide profile 31 seals the drainage channels 18 both against the central web 15 carrying the screw channel 16 and against the facade side 14 of the post profile and the side legs 1 of the Post profile from. On the water guide profile 31, the water runs in the longitudinal direction 2 to the water outlet, not shown in the drawings, and leaves the mullion and transom profile frame via the water outlet.

Reference symbol list

1

Post and
Transom profile frame

2nd

Longitudinal direction

3rd

Post profile

4th

Cross direction

5

Transom profile

6

Joint area

7

Partial profile

8th

Profile joint

9

Direction of curvature

10th

Water guiding profile

11

Profile body

12

Profile height

13

Room side

14

Facade side

15

Mittelsteg

16

Screw channel

17th

Mounting screw

18th

Drainage canal

19th

Side thighs

20th

Groove web

21

Latching area

22

Sealing strip

23

Overlay seal

24th

Surface element

25th

Space

26

Mounting profile

27th

Mounting seal

28

Cover profile

29

back

30th

Spring hook

31

Water guiding profile

32

Profile side leg

33

Screw-in funnel

α

Joint area angle

β

Profile joint angle

β '

Profile joint angle
= 180 °

Claims (15)

a) mullion and transom profile scaffold (1) for a wall or roof construction with the scaffold spaces (25) fanning out surface elements (24) and with a longitudinal profile (2), consisting of several sub-profiles (7) assembled post profile (3). b) Two adjacent partial profiles (7) each lie with their end faces against one another and each form a profile joint (8). c) The profile joints are c1) beveled so that two adjacent partial profiles (7) abut each other in the manner of legs of an angle (β) different from 180 ° to form a post profile (3) and / or which bends in the longitudinal direction (2) c2) straight, so that two adjacent partial profiles (7) abut each other in the manner of legs of a 180 ° angle (β ') to form a straight post profile (3) in the longitudinal direction (2). d) the partial profiles (7) have side legs (19) projecting on the facade side (= 14) and extending in the longitudinal direction (2) to form a drainage channel (18) extending over the entire length of the post profile,
characterized by the following features: d) A water guide profile (31), which is introduced into the drainage channel (18) and acts as a water channel over the entire length of the post profile e) from the water guide profile (31), separate sealing strips (22) on the facade side (= 14) that can be attached to the post profile for fixing the surface elements (24). Scaffold according to claim 1,
characterized,
that the water guide profile (31) extends in one piece in the longitudinal direction (2) over the entire length of the post profile (3) and bridges the butt joints created in the area of the profile joints (8). Scaffolding according to one of claims 1 or 2,
characterized,
that the water guide profile (31) completely lines the drainage channel (18). Scaffold according to one of claims 1 to 3
characterized, - That the partial profiles (7) have a rectangular profile body (11) with the facade side (14) and the facade side (14) facing away from the room side (13) as long sides and - That the side legs (19) protrude in the direction of curvature (9) from the facade side (14) of the base body (11) and limit the facade side (14) in the transverse direction (4) on the edge side. Scaffold according to claim 4
characterized,
that the side legs (19) are angular, the angled, parallel to the facade side (14) of the partial profiles (7) area of the side legs (19) forms a groove web (20) as a mounting surface for the sealing strips (22). Scaffold according to claim 5
characterized,
that the locking profiles (5) rest on the groove webs (20) in the final assembly state and the drainage channels of the locking profiles (5) lead into the drainage channels (18) of the mullion profiles (3). Scaffold according to claim 6,
characterized,
that the locking profiles (5) rest in the final assembly state with the interposition of a support seal (23) on the groove webs (20). Scaffold according to claim 6 or 7,
characterized,
that the transom profiles (5) can be latched into the post profiles (3). Scaffolding according to one or more of the preceding claims,
marked by
a screw channel (16) projecting from the facade side (14) of the mullion profile (3) towards the outside of the wall or roof construction in the manner of a central web (15) for receiving fastening screws (17). Scaffold according to claim 9,
characterized, - That of the central web (15) carried screw channel (16) divides the drainage channel (18) into two parallel drainage subchannels (18) and - That in each drainage subchannel (18) is in each case an extending over the entire post profile length water guide sub-profile (31). Scaffold with screw channel (16) on the post profile according to claim 9,
marked by
a W-shaped cross section of the drainage channel (18) and a corresponding W-shaped design of the water guide profile cross section. Scaffolding according to one or more of the preceding claims,
marked by
a water guide profile material such that the water guide profiles (31) are elastically deformable in all directions (= 2,4,9) to improve conformability to the inner structure of the drainage channels (18). Scaffold according to claim 12,
characterized,
that the surface elements (24) can be clamped between the sealing strips (22) and a mounting profile (26) which can be mounted in front of the facade side (14) of the post profile (3). Framework according to claim 13,
characterized,
that a fastening screw (17) can be screwed into the screw channel (16) for bracing the surface elements (24) between the sealing strips (22) and the fastening profile (26). Use of a mullion and transom profile frame (1) according to one or more of the preceding claims for a polygon roof, the mullion profiles (3) forming the rafters and glass surface elements (24) fanning out the profile spaces (25).

Images