EP1078135A1

EP1078135A1 - Frontage system for siding a building

Info

Publication number: EP1078135A1
Application number: EP99930989A
Authority: EP
Inventors: Jörn-Peter Knutzen
Original assignee: RP Technik GmbH Profilsysteme
Current assignee: RP Technik GmbH Profilsysteme
Priority date: 1998-05-11
Filing date: 1999-04-26
Publication date: 2001-02-28
Anticipated expiration: 2019-04-26
Also published as: WO1999058781A1; ATE215649T1; EP1078135B1; DE59901123D1; DE19822103A1

Abstract

The invention relates to a frontage system for siding a building, comprising a support (1) made of metal having a filling element support, wherein filling elements (2, 2'), more particularly, laminated glass panel elements, are placed, said elements being fixed by means of outer locking strips (3) that are releasably connected to the support (1), wherein inner sealing elements (4) and outer sealing elements (5) are also provided. The invention aims at ensuring flexible, simple and functional assembly of said system on any metal support (1). To this end, a separate profile rail (7) is provided on the metal support (1) that is placed thereon for fixing the locking strips (3), the profiles of which have a helical groove section (8) directly interacting with fastening screws (6) and at least one additional locking section (9, 9') located next to the helical groove section (8) and fixing the inner sealing elements (4).

Description

Facade system for cladding a building

description

The invention relates to a facade system for the cladding of a building according to the preamble of claim 1.

Such a facade system is known from DE 196 06 906. It essentially consists of a substructure made of posts and transversely arranged transoms. Both elements are made from a hollow profile. The filling elements - here laminated glass panes - are arranged in the metal frame formed by mullions and transoms. The conclusion towards the outside is formed by retaining strips which are connected to the metal frame with corresponding fastening screws. To seal the system are in the longitudinal grooves of the post, the

Bolts and the retaining strips are molded on the inside and outside accordingly. During assembly, the self-drilling fastening screw is inserted as far as possible into a guide and pressure spacer system. After attaching an electric screwdriver, the fastening screw is turned so that it is with a specially trained

The drill bit is screwed into the nose-shaped profile of the post or the transom. This facade system allows simple and therefore quick assembly of the filling elements on the substructure; However, for reasons of strength, it is only suitable for profiles in which penetration of the fastening screw is possible.

To avoid this disadvantage, DE 38 23 939 discloses a fastening solution for filling elements on the substructure, in which separate threaded bolts are used. Filling elements are fastened to a hollow profile shown in FIG. 1 via a holding strip. There are threaded bolts on the mullions and transoms shot or welded onto which metal bolts are screwed. The metal bolts have a screw-on area, a conical intermediate area and an area for screwing in fastening screws for the retaining strip.

Because of the use of separate welded or piled

Threaded bolts for fastening the filler elements can be used as a hollow profile for conveying fluids. There are no problems with leaks. Furthermore, the substructure is not specifically tailored to a specific facade system. It is therefore inexpensive to manufacture. The flat mounting surface on the outside of the frame also allows the structure to be veneered flexibly. A major disadvantage of this facade system, however, is its complex assembly. As practice has shown, the protruding threaded bolts cannot be attached to the metal frame in true-to-size alignment under construction site conditions. The operator of the fastening device - for example a welding device - can only fix the threaded bolts on the substructure in orthogonal alignment at equidistant intervals with considerable effort. In a workshop assembly the threaded bolt solution the problem arises that the ^"fixed projecting threaded bolt easily bend or in particular during transport to the construction site as a result of transverse impact load can break away.

Another facade system emerges from a brochure from the company Hermann Forster AG (forster thermfix vario, 02.94). It consists essentially of a hollow profile as a substructure, which with a clamping groove as a fastening groove for

Filling elements is provided. The clamping groove is used to accommodate clamping elements, the clamping foot of which spreads when a spreader sleeve is inserted and thus passes under the beveled flanks of the clamping groove, so that a clamping attachment is produced. With the clamp fastening, a holding element for receiving fastening screws for the filling elements is attached. It is with this

Facade system therefore requires a variety of elements, the use of which increases the assembly effort.

DE 295 00 286 discloses a facade system which also uses a hollow profile as a substructure, which also has a fastening groove is provided. In contrast to the facade system described above, however, the fastening groove serves as a screw groove section with a groove neck area narrowed with respect to the groove base, in which a fastening screw engages directly on the groove neck area. The two facade systems described above are based on the use of specially profiled hollow profiles, which are quite complex to manufacture compared to standard profiles.

The invention has for its object to provide a facade system that can be flexibly mounted on any substructure made of metal easily and at the same time functional.

The object is achieved on the basis of a facade system according to the preamble of patent claim 1 in conjunction with its characterizing features. Advantageous developments of the invention are specified in the subclaims.

The invention includes the technical teaching that a separate professional rail attached to a substructure is provided for fastening the retaining strips. The profile of the profile rail has a screw groove section which interacts directly with fastening screws and at least one further holding section located next to the screw groove section and fixing an inner sealing element.

The solution according to the invention has the advantage that the facade system can be used by using a separate profile rail on any substructure made of metal, which has a neutral - ie not specially profiled - contact surface. The profile rail can be used universally and can be attached, for example, to a metal substructure consisting of T-beams, rectangular profiles or round profiles. The facade system is therefore largely independent of the substructure and can be designed flexibly. Since the profile rail specifies both the screw-in points for the fastening screws and the fixing points for the inner sealing elements in the sense of functional integration, assembly errors due to non-compliance with. Assembly dimensions on the construction site excluded. Because the fastening screws directly, i.e. without the use of additional means with the screw groove section - 4 -

cooperate, otherwise customary parts in the form of nut or clamping elements are saved. In addition, the distance between the fastening screws can be freely selected - depending on the load. A further advantage is that the use of the already known guide and pressure spacer system ensures that the fastening screws are attached in a perpendicular and aligned manner.

In addition, an adequate seal is ensured in the area of the penetration of the inner sealing element.

The profile rail is preferably attached to a flat end face of the metal substructure running in the facade plane. The outward-facing surface of the metal substructure is used for this. It is also conceivable to attach the profile rail to the flank sides of a metal substructure.

One measure improving the invention is that the profile rail is curved on its base surface facing the metal substructure. Thus, contact is made with a flat substructure made of metal solely through a line-like support in the bilateral edge area of the bottom surface of the profile rail. This design avoids the accumulation of condensation water between the profile rail and the metal substructure and thus allows ventilation, which as a result prevents crevice corrosion in the fastening area between the metal substructure and the professional rail. At the same time, any corrosion protection agent that may be used is thereby made possible to spread in this area.

The profile rail preferably has two holding sections for the inner sealing element, which are formed by an acute-angled inclination of the two side edges of the profile rail. The use of the side edges of the profile rail for holding purposes for the inner sealing element - which could otherwise be pushed out of its desired position under load - is particularly effective. Due to the acute-angled inclination of the side edges, the inner sealing element is pressed underneath them and thus firmly and reliably fixed.

The screw groove section is advantageously designed in such a way that it has a groove neck area narrowed with respect to the groove base, in which the - 5 -

Fastening screw comes into engagement. This measure makes it easier to screw in the fastening screw and at the same time ensures that the screw connection is held securely.

Another measure improving the invention is that

Profile rail is made from a steel band and is profiled by forming. It can therefore be produced efficiently. The profile rail can be quickly and securely fastened to the metal substructure by welding, with elongated holes preferably being provided as welding points along the edge regions on both sides. The welding takes place on the

Edge of the profile rail facing flank side of each elongated hole. The weld seam layer is designed in such a way that a subsequent corrosion protection measure can be introduced. When such a welded connection is used, the inner sealing element can have a flexible contact area for bridging weld seam elevations, so that the weld seam has the position of the inner one

Sealing element is not hindered. The inner sealing element can furthermore have a rigidly designed flank area for the partial absorption of fastening forces.

The profile rail according to the invention can be largely independent of the

Use the substructure and can be installed together with a thermal insulation body for thermal insulation, which is then arranged between the metal substructure and the profile rail.

Further measures improving the invention are specified in the subclaims or are shown below together with the description of a preferred embodiment of the invention with reference to the figures. 1 shows a perspective illustration of a facade system in FIG

Exterior view,

Fig. 2 shows a partial section through a facade system in the assembled state

(without cover strip),

3 is a perspective view of a profile rail with a weld, 4 shows a top view of a profile rail according to FIG. 2,

Fig. 5 shows a partial section through a facade system with thermal

Insulation body in the assembled state (without cover strip),

Fig. 6 is a plan view of a rail with attached

Filler element carrier and

7 shows a side view of FIG. 6, however, with the inner sealing element installed and without filler element carrier.

A facade system according to FIG. 1 is mounted on a metal substructure 1 composed of vertical posts 1a and transversely extending bars 1b. The substructure 1 made of metal is assigned to the building. The facade system is used to attach filler elements 2, 2 'for cladding the

Building. In the exemplary embodiment, laminated glass pane elements are provided as filling elements 2, 2 '. The filling elements 2, 2 'are detachably connected to the substructure 1 via outer holding strips 3 and optionally with cover strips.

The partial section according to FIG. 2 shows the fastening system in detail. An inner sealing element 4 provided between the edge region of each filling element 2, 2 'and the substructure 1 is shown. Likewise, an outer sealing element 5 is located between the edge region of each filler element 2, 2 'and the holding bar 3

Cover strip was omitted here. The sealing elements 4 and 5 prevent the penetration of external climatic influences into the building and also have an insulating effect in the opposite direction. The releasable connection of the holding strips 3 to the substructure 1 is realized by means of a plurality of fastening screws 6 arranged equidistantly along the substructure 1. Each fastening screw 6 interacts with a profile rail 7 welded to the substructure 1. For this purpose, the profile rail 7 has a screw groove section 8. Furthermore, the profile rail 7 is equipped with two holding sections 9, 9 ′ which fix the inner sealing element 4. The inner sealing element 4 has a flexible contact area 10 for bridging weld seam elevations. For at least partially picking up caused by the fastening screws 6 Fixing forces, the inner sealing element 4 is equipped with a rigidly formed flank area 11. Thus, the inner sealing element 4 cannot be damaged by a shearing action of the angled holding sections 9, 9 '. To fix the clamping distance for the filling element 2, 2 'to be held, a guide and is coaxially penetrated by the fastening screw 6

Pressure spacer system 12 is provided. The sealing guide and pressure distance sleeve system 12 consists of a guide sleeve which is plugged onto the fastening screw 6 and which is inserted into a spacer sleeve and thus forms both a guide for the fastening screw 6 and a spacer for the filling element 2, 2 '. The guide and pressure spacer sleeve

System 12 comes into contact with the holding strip 3 on one end face and on the inner sealing element 4 on the other end face. This minimizes the penetration of corrosive media into the screw channel.

The specially designed profile rail is made from a steel strip according to FIG. 3 and profiled by reshaping. The profile rail 7 is concavely curved on its bottom surface 15 facing the substructure 1. As a result, there is contact with the substructure 1 only by line-like support of the profile rail 7 in its edge regions 16, 16 'on both sides. The holding sections 9, 9 'for the inner

Sealing element 4 are formed by an acute-angled inclination of the two side edges of the profile rail 7. Due to the acute-angled inclination of the two holding sections 9, 9 ', the inner sealing element 4 is pressed under the acute-angled inclination during assembly - that is to say when the fastening screw 6 is tightened. A stable hold of the inner sealing element 4 is thus ensured. The

Screw groove section 8 of the profiled rail 7 has a groove neck region narrowed with respect to the groove base. Thus, the fastening screw 6 comes into engagement only in the groove neck area, which enables the fastening screw 6 to be screwed in easily and the screw connection to be securely held.

As shown in FIG. 4, the profiled rail is provided with spaced-apart elongated holes 17a-17d along its edge regions 16, 16 'on both sides. The elongated holes 17a-17d serve to fasten the profiled rail 7 to the substructure 1. Here, welding takes place in each case on the side of the elongated hole 17a-17d facing the edge of the profiled rail 7. That kind of Welding allows optimal back ventilation of the profile rail 7 and gives corrosive media a minimal contact surface in the weld area. Furthermore, this type of welding enables a concealed connection, that is to say a connection that is not visible from the outside.

FIG. 5 shows an exemplary embodiment in which at least parts of the substructure 1 are designed as steel pipes filled with water. The water filling can be used in particular for heating or cooling the building. In this application, it is necessary that the substructure 1 of the to avoid thermal bridges in the facade

Fastening elements of the facade system is mounted insulated. For this purpose, a thermal insulation body 18 is provided, which is placed between the profile rail 7 and the inner sealing element 4. The thermal insulation body 18 contains recesses 13 on its side facing the profile rail 7, which have a free space for the two holding sections 9 and 9 'and for the screw groove section

8 form. On its side facing the inner sealing element 4, the thermal insulation body 18 likewise has recesses 14 which receive corresponding peg-shaped projections on the inner sealing element 4. The remaining design features of this embodiment example are identical to the exemplary embodiment described at the outset, so that the facade system can easily be adapted to the special requirements of fluid-carrying substructures.

To support the filling element 2, 2 ', a filling element carrier 21 mounted on the profile rail 7 is provided according to FIG. The filler element carrier 21 takes the occurring weight forces of the resting on it - not shown here -

Filling element 2, 2 'and is indirectly attached to the profile rail 7 via a sleeve-like element 19.

According to FIG. 7, the sleeve-like element 19 interacts with a penetrating, pointed fastening screw 20. The mounting screw 20 is from

Bottom area of the profile rail 7 coming anchored in the groove neck area of the profile rail 7 and pressed through the inner sealing element 4. In order to ensure a reliable sealing effect at the point of penetration of the inner sealing element 4., the fastening screw 20 is provided with a tip, so that the inner sealing element 4 on the fastening screw 20 after piercing - 9 -

comes tight to the system. In addition, the sleeve-like element 19 comes with its end face facing the profile rail 7 sealingly against the inner sealing element 4. A fastening screw (not shown here) which fixes the filler element carrier 21 can be screwed into the part of the sleeve-like element 19 which projects beyond the fastening screw 20.

The embodiment of the invention is not limited to the preferred exemplary embodiments specified above. Rather, a number of variations are conceivable which make use of the solution shown, even in the case of fundamentally different types.

- 10 -

Reference list

1 substructure

2 filling element

3 retaining strips

4 sealing element, inside

5 sealing element, outside

6 fastening screw

7 profile rail

8 screw groove section

9 holding section

10 contact area, flexible

11 flank area

12 guide and pressure spacer system

13 recess

14 recess

15 floor surface, arched

16 edge area

17 slot

18 insulation element

19 element, sleeve-shaped

20 fastening screw 21 filling element carrier

Claims

- 11 patent claims

1. Facade system for the cladding of a building, with a filler support (21) having a substructure (1) made of metal, on the filler elements (2,2 ') - in particular laminated glass elements - are attached, which are at least releasably connected to the substructure (1) outer retaining strips (3) are held, with inner sealing elements (4) and outer sealing elements (5) being provided, characterized in that a separate profiled rail (7) attached to the substructure (1) made of metal is provided for fastening the retaining strips (3) The profile of which has a screw groove section (8) which interacts directly with fastening screws (6) and at least one further holding section (9,9 ') which is located next to the screw groove section (8) and fixes the inner sealing element (4).

2. Facade system according to claim 1, characterized in that the profile rail (7) is mounted on a flat end face of the substructure (1) extending in the facade plane.

3. Facade system according to claim 1 and 2, characterized in that the substructure (1) consists of posts and transversely arranged bars, which form a frame for the filling elements (2, 2 ').

4. Facade system according to claim 3, characterized in that posts (1 a) and bars (1 b) have a T-profile, in which the. Profile rail (7) comes to rest on its transverse web. - 12 -

5. Facade system according to one of claims 1-4, characterized in that the profile rail (7) on its the substructure (1) facing the bottom surface (15) is concave, such that contact to the substructure (1) solely by line-like Rest in the bilateral edge area (16, 16 ') of the bottom surface (15).

6. Facade system according to one of claims 1-5, characterized in that two holding sections (9,9 ') for the inner sealing element (4) are formed by an acute-angled inclination of the two side edges of the profile rail (7).

7. Facade system according to one of claims 1-6, characterized in that the screw groove portion (8) has a narrowed in relation to the groove base groove neck area, such that the fastening screw (6) comes into engagement at the groove neck area.

8. Facade system according to one of claims 1-7, characterized in that the profile rail (7) consists of a steel strip and is profiled by forming.

9. Facade system according to one of claims 1-8, characterized in that the profile rail (7) with the substructure (1) is firmly connected by welding. - 13 -

10. Facade system according to claim 9, characterized in that spaced slots (17a-17d) are provided as welding points along the edge regions (16, 16 ') on both sides, the welding in each case on the side of the edge facing the profile rail (7) each slot (17a-17d).

11. Facade system according to claim 9 and 10, characterized in that the inner sealing element (4) for bridging weld seam heights has a flexible contact area (10).

12. Facade system according to one of the preceding claims, characterized in that for adjusting the clamping distance for the filling element to be held (2,2 ') is provided by the fastening screw (6) coaxially penetrated guide and pressure spacer sleeve system (12).

13. Facade system according to claim 12, characterized in that the guide and pressure spacer system on one end face sealingly on the retaining strip (3) and on the other end face sealingly against the inner sealing element (4).

14. Facade system according to one of the preceding claims, characterized in that the inner sealing element (4) for partially absorbing fastening forces has a rigid flank region (11). - 14 -

15. Facade system according to one of the preceding claims, characterized in that for supporting the filling element (2, 2 ') on the substructure (1) a filling element carrier (21) is provided on the profile rail (7).

16. Facade system according to claim 15, characterized in that the filler element carrier (21) via a through the inner sealing element (4) piercing pointed fastening screw (20) with the profile rail (7) is connected, which is provided with a thread on the inner Sealing element (4) comes into contact with the sleeve-like element (19).

17. Facade system according to one of the preceding claims, characterized in that the mullions and transoms are designed as a hollow profile.

18. Facade system according to one of the preceding claims, characterized in that a thermal insulation body (18) is provided in the configuration of the post and the transom as a fluid-carrying hollow profile between the profile rail (7) and the inner sealing element (4).